http://www.physicsbook.gatech.edu/api.php?action=feedcontributions&feedformat=atom&user=FatimajamilPhysics Book - User contributions [en]2026-04-19T15:04:57ZUser contributionsMediaWiki 1.42.7http://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=8712Total Angular Momentum2015-12-03T00:32:46Z<p>Fatimajamil: /* Connectedness */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
You can visualize this topic of total angular momentum with this code of the total angular momentum of a binary star. You can see the rotational angular momentum along with the translational angular momentum.<br />
<br />
[[File:Screen_Shot_2015-12-02_at_1.36.42_AM.png]]<br />
<br />
<br />
This screenshot shows the code in action but you can check it out with this link: '''https://trinket.io/glowscript/49129c12fd'''<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
This topic is connected to my major (industrial engineering), because it is important to understand the basics before attempting to solve the bigger picture. In terms of angular momentum, it is important to understand the breakdown of translational and rotational before attempting to solve complex problems involving conservation of angular momentum and more. <br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books and other print media that cover this topic in more depth:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
These are some internet articles that can show more animations and pictures to help understand this concept<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
Matter and Interactions 4th edition. Full Citation: Chabay, Ruth W., and Bruce A. Sherwood. Matter and Interactions. Hoboken, NJ: Wiley, 2011. Print.<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=7934Total Angular Momentum2015-12-02T06:45:23Z<p>Fatimajamil: /* A Computational Model */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
You can visualize this topic of total angular momentum with this code of the total angular momentum of a binary star. You can see the rotational angular momentum along with the translational angular momentum.<br />
<br />
[[File:Screen_Shot_2015-12-02_at_1.36.42_AM.png]]<br />
<br />
<br />
This screenshot shows the code in action but you can check it out with this link: '''https://trinket.io/glowscript/49129c12fd'''<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
This topic is connected to my major, because it is important to understand the basics before attempting to solve the bigger picture. In terms of angular momentum, it is important to understand the breakdown of translational and rotational before attempting to solve complex problems involving conservation of angular momentum and more. <br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books and other print media that cover this topic in more depth:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
These are some internet articles that can show more animations and pictures to help understand this concept<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
Matter and Interactions 4th edition. Full Citation: Chabay, Ruth W., and Bruce A. Sherwood. Matter and Interactions. Hoboken, NJ: Wiley, 2011. Print.<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=7933Total Angular Momentum2015-12-02T06:45:09Z<p>Fatimajamil: /* A Computational Model */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
You can visualize this topic of total angular momentum with this code of the total angular momentum of a binary star. You can see the rotational angular momentum along with the translational angular momentum.<br />
<br />
[[File:Screen_Shot_2015-12-02_at_1.36.42_AM.png]]<br />
<br />
<br />
This screenshot shows the code in action but you can check it out with this link: https://trinket.io/glowscript/49129c12fd<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
This topic is connected to my major, because it is important to understand the basics before attempting to solve the bigger picture. In terms of angular momentum, it is important to understand the breakdown of translational and rotational before attempting to solve complex problems involving conservation of angular momentum and more. <br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books and other print media that cover this topic in more depth:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
These are some internet articles that can show more animations and pictures to help understand this concept<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
Matter and Interactions 4th edition. Full Citation: Chabay, Ruth W., and Bruce A. Sherwood. Matter and Interactions. Hoboken, NJ: Wiley, 2011. Print.<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=7931Total Angular Momentum2015-12-02T06:44:24Z<p>Fatimajamil: </p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
You can visualize this topic of total angular momentum with this code of the total angular momentum of a binary star. <br />
<br />
[[File:Screen_Shot_2015-12-02_at_1.36.42_AM.png]]<br />
<br />
This screenshot shows the code in action but you can check it out with this link: https://trinket.io/glowscript/49129c12fd<br />
<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
This topic is connected to my major, because it is important to understand the basics before attempting to solve the bigger picture. In terms of angular momentum, it is important to understand the breakdown of translational and rotational before attempting to solve complex problems involving conservation of angular momentum and more. <br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books and other print media that cover this topic in more depth:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
These are some internet articles that can show more animations and pictures to help understand this concept<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
Matter and Interactions 4th edition. Full Citation: Chabay, Ruth W., and Bruce A. Sherwood. Matter and Interactions. Hoboken, NJ: Wiley, 2011. Print.<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=7929Total Angular Momentum2015-12-02T06:40:41Z<p>Fatimajamil: /* A Computational Model */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
You can visualize this topic of total angular momentum with this code of the total angular momentum of a binary star. <br />
<br />
[[File:Screen_Shot_2015-12-02_at_1.36.42_AM.png]]<br />
<br />
<iframe src="https://trinket.io/embed/glowscript/49129c12fd" width="100%" height="356" frameborder="0" marginwidth="0" marginheight="0" allowfullscreen></iframe><br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
This topic is connected to my major, because it is important to understand the basics before attempting to solve the bigger picture. In terms of angular momentum, it is important to understand the breakdown of translational and rotational before attempting to solve complex problems involving conservation of angular momentum and more. <br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books and other print media that cover this topic in more depth:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
These are some internet articles that can show more animations and pictures to help understand this concept<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
Matter and Interactions 4th edition. Full Citation: Chabay, Ruth W., and Bruce A. Sherwood. Matter and Interactions. Hoboken, NJ: Wiley, 2011. Print.<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=7927Total Angular Momentum2015-12-02T06:37:25Z<p>Fatimajamil: /* A Computational Model */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
[[File:Screen_Shot_2015-12-02_at_1.36.42_AM.png]]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
This topic is connected to my major, because it is important to understand the basics before attempting to solve the bigger picture. In terms of angular momentum, it is important to understand the breakdown of translational and rotational before attempting to solve complex problems involving conservation of angular momentum and more. <br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books and other print media that cover this topic in more depth:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
These are some internet articles that can show more animations and pictures to help understand this concept<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
Matter and Interactions 4th edition. Full Citation: Chabay, Ruth W., and Bruce A. Sherwood. Matter and Interactions. Hoboken, NJ: Wiley, 2011. Print.<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=File:Screen_Shot_2015-12-02_at_1.36.42_AM.png&diff=7926File:Screen Shot 2015-12-02 at 1.36.42 AM.png2015-12-02T06:37:11Z<p>Fatimajamil: </p>
<hr />
<div></div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4633Total Angular Momentum2015-11-30T19:58:00Z<p>Fatimajamil: /* Connectedness */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
This topic is connected to my major, because it is important to understand the basics before attempting to solve the bigger picture. In terms of angular momentum, it is important to understand the breakdown of translational and rotational before attempting to solve complex problems involving conservation of angular momentum and more. <br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books and other print media that cover this topic in more depth:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
These are some internet articles that can show more animations and pictures to help understand this concept<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
Matter and Interactions 4th edition. Full Citation: Chabay, Ruth W., and Bruce A. Sherwood. Matter and Interactions. Hoboken, NJ: Wiley, 2011. Print.<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4628Total Angular Momentum2015-11-30T19:56:16Z<p>Fatimajamil: /* Further reading */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books and other print media that cover this topic in more depth:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
These are some internet articles that can show more animations and pictures to help understand this concept<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
Matter and Interactions 4th edition. Full Citation: Chabay, Ruth W., and Bruce A. Sherwood. Matter and Interactions. Hoboken, NJ: Wiley, 2011. Print.<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4625Total Angular Momentum2015-11-30T19:55:19Z<p>Fatimajamil: </p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
These are some internet articles that can show more animations and pictures to help understand this concept<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
Matter and Interactions 4th edition. Full Citation: Chabay, Ruth W., and Bruce A. Sherwood. Matter and Interactions. Hoboken, NJ: Wiley, 2011. Print.<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4622Total Angular Momentum2015-11-30T19:53:03Z<p>Fatimajamil: /* Video Content */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
Videos on Total Angular Momentum:<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
https://www.youtube.com/watch?v=iWSu6U0Ujs8<br />
<br />
===External links===<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4618Total Angular Momentum2015-11-30T19:49:53Z<p>Fatimajamil: /* Further reading */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
http://chaos.utexas.edu/wp-uploads/2012/03/Angular_Momentum_21.pdf<br />
<br />
===Video Content===<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
===External links===<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4614Total Angular Momentum2015-11-30T19:48:57Z<p>Fatimajamil: /* External links */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
===Video Content===<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
===External links===<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4613Total Angular Momentum2015-11-30T19:48:46Z<p>Fatimajamil: /* References */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
===Video Content===<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
===External links===<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://hyperphysics.phy-astr.gsu.edu/hbase/amom.html<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4152Total Angular Momentum2015-11-30T03:52:20Z<p>Fatimajamil: /* Connectedness */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
===Video Content===<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
===External links===<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4143Total Angular Momentum2015-11-30T03:46:03Z<p>Fatimajamil: /* Simple */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
A ball falls straight down in the xy plane. Its momentum is shown by the red arrow. What is the direction of the ball's total angular momentum about location A?<br />
<br />
[[File:Simple final.png]]<br />
<br />
When attempting to solve this question, it is important to recognize that there is no rotational angular momentum, because there is no rotation about the center of mass. The only thing that is happening is that the center of mass is translating from some point A. In this case since there is only translational angular momentum, we would simply find the direction of the total angular momentum by using our right hand rule [hint: r points from A to the ball, and the momentum is pointing in the -y direction]<br />
<br />
The direction of the ball's total angular momentum is in the -z direction.<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
===Video Content===<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
===External links===<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=File:Simple_final.png&diff=4127File:Simple final.png2015-11-30T03:34:14Z<p>Fatimajamil: </p>
<hr />
<div></div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=4126Total Angular Momentum2015-11-30T03:33:16Z<p>Fatimajamil: /* Examples */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
<br />
<br />
===Middling===<br />
<br />
This example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Difficult===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
===Video Content===<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
===External links===<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1625Total Angular Momentum2015-11-26T04:29:50Z<p>Fatimajamil: /* External links */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
===Video Content===<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
===External links===<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1624Total Angular Momentum2015-11-26T04:29:37Z<p>Fatimajamil: /* See also */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
===Video Content===<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1621Total Angular Momentum2015-11-26T04:29:19Z<p>Fatimajamil: /* See also */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
===Video Content===<br />
<br />
https://www.youtube.com/watch?v=8SfRmqSQENU&index=34&list=PL9HgJKLOnKxedh-yIp7FDzUTwZeTeoR-Y<br />
<br />
https://www.youtube.com/watch?v=nFSMu3bxXVA<br />
<br />
https://www.youtube.com/watch?v=diZDoY07LG4<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1618Total Angular Momentum2015-11-26T04:26:51Z<p>Fatimajamil: /* History */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1617Total Angular Momentum2015-11-26T04:26:36Z<p>Fatimajamil: /* History */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1616Total Angular Momentum2015-11-26T04:26:18Z<p>Fatimajamil: /* History */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
''"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
''<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.[37]<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
''"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
''<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1614Total Angular Momentum2015-11-26T04:25:46Z<p>Fatimajamil: </p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
Newton, in the Principia, hinted at angular momentum in his examples of the First Law of Motion,<br />
<br />
"A top, whose parts by their cohesion are perpetually drawn aside from rectilinear motions, does not cease its rotation, otherwise than as it is retarded by the air. The greater bodies of the planets and comets, meeting with less resistance in more free spaces, preserve their motions both progressive and circular for a much longer time."<br />
<br />
However, his geometric proof of the Law of Areas is an outstanding example of Newton's genius, and indirectly proves angular momentum conservation in the case of a central force.<br />
<br />
In 1736 Euler, like Newton, touched on some of the equations of angular momentum in his Mechanica without further developing them.<br />
<br />
Bernoulli wrote in a 1744 letter of a "moment of rotational motion", possibly the first conception of angular momentum as we now understand it.[37]<br />
<br />
In 1799, Pierre-Simon Laplace first realized that a fixed plane was associated with rotation — his invariable plane.<br />
<br />
Louis Poinsot in 1803 began representing rotations as a line segment perpendicular to the rotation, and elaborated on the "conservation of moments".<br />
<br />
In 1852 Léon Foucault used a gyroscope in an experiment to display the Earth's rotation.<br />
<br />
William J. M. Rankine's 1858 Manual of Applied Mechanics defined angular momentum in the modern sense for the first time:<br />
<br />
"...a line whose length is proportional to the magnitude of the angular momentum, and whose direction is perpendicular to the plane of motion of the body and of the fixed point, and such, that when the motion of the body is viewed from the extremity of the line, the radius-vector of the body seems to have right-handed rotation."<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
https://en.wikipedia.org/wiki/Angular_momentum<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1602Total Angular Momentum2015-11-26T04:09:40Z<p>Fatimajamil: /* References */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
Professor Gumbart [Georgia Institute of Technology] Lecture Notes<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1569Total Angular Momentum2015-11-26T01:03:15Z<p>Fatimajamil: </p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
These examples will help to solidify the difference between the different components of total angular momentum.<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1563Total Angular Momentum2015-11-26T00:53:09Z<p>Fatimajamil: </p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
http://www.sparknotes.com/testprep/books/sat2/physics/chapter10section6.rhtml<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1561Total Angular Momentum2015-11-26T00:50:57Z<p>Fatimajamil: </p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1554Total Angular Momentum2015-11-26T00:47:23Z<p>Fatimajamil: /* Simple */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Easy.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page.<br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=File:Easy.png&diff=1552File:Easy.png2015-11-26T00:46:11Z<p>Fatimajamil: picture</p>
<hr />
<div>picture</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1447Total Angular Momentum2015-11-25T21:58:10Z<p>Fatimajamil: /* References */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page. <br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
==References==<br />
<br />
https://www.chegg.com/homework-help<br />
http://www.sparknotes.com/physics/rotationalmotion/angularmomentum/section1.rhtml<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1446Total Angular Momentum2015-11-25T21:56:33Z<p>Fatimajamil: /* Middling */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page. <br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle rotational.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Middle translational.png]]<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
''<br />
<br />
The total angular momentum is rotational + translational so it is <0,0,-11.16> kgm^2/s<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=File:Middle_translational.png&diff=1444File:Middle translational.png2015-11-25T21:55:43Z<p>Fatimajamil: picture</p>
<hr />
<div>picture</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=File:Middle_rotational.png&diff=1442File:Middle rotational.png2015-11-25T21:54:10Z<p>Fatimajamil: picture</p>
<hr />
<div>picture</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1440Total Angular Momentum2015-11-25T21:51:31Z<p>Fatimajamil: </p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page. <br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
Matter and Interactions by Ruth W. Chabay and Bruce A. Sherwood<br />
<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1434Total Angular Momentum2015-11-25T21:38:18Z<p>Fatimajamil: /* See also */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page. <br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic:<br />
<br />
Elementary Theory of Angular Momentum (Dover Books on Physics) by M.E. Rose<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1426Total Angular Momentum2015-11-25T21:31:22Z<p>Fatimajamil: /* Middling */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page. <br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1424Total Angular Momentum2015-11-25T21:30:49Z<p>Fatimajamil: /* Examples */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page. <br />
<br />
===Middling===<br />
<br />
This problem shows an example of total angular momentum being based off both translational angular momentum and rotational angular momentum.<br />
<br />
[File:Middle example 1.png]]<br />
<br />
[[File:Middle example 2.png]]<br />
<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=File:Middle_example_1.png&diff=1423File:Middle example 1.png2015-11-25T21:29:58Z<p>Fatimajamil: picture</p>
<hr />
<div>picture</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=File:Middle_example_2.png&diff=1422File:Middle example 2.png2015-11-25T21:29:17Z<p>Fatimajamil: picture</p>
<hr />
<div>picture</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1405Total Angular Momentum2015-11-25T21:05:51Z<p>Fatimajamil: </p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page. <br />
<br />
===Middling===<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic:<br />
<br />
http://www.phy.duke.edu/~lee/P53/sys.pdf<br />
<br />
http://farside.ph.utexas.edu/teaching/301/lectures/node120.html<br />
<br />
https://www.physics.purdue.edu/webapps/index.php/course_document/index/phys172/1332/135/9703<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1395Total Angular Momentum2015-11-25T20:32:51Z<p>Fatimajamil: </p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
'''c) Calculate Ltotal,B (both magnitude and direction)<br />
'''<br />
<br />
Due to the fact that...<br />
<br />
[[File:Total Angular Momentum.png]]<br />
<br />
We calculated that our Lrot is zero, our total angular momentum is just based on translational angular momentum. So in this case, total angular momentum = translational angular momentum. So total angular momentum is 9.72 kgm^2/s, with the same direction, into the page. <br />
<br />
===Middling===<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1394Total Angular Momentum2015-11-25T20:30:53Z<p>Fatimajamil: /* Simple */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
<br />
c) Calculate Ltotal,B (both magnitude and direction)<br />
<br />
===Middling===<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1393Total Angular Momentum2015-11-25T20:22:12Z<p>Fatimajamil: /* Examples */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
===Middling===<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1391Total Angular Momentum2015-11-25T20:20:59Z<p>Fatimajamil: /* Examples */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.19.38 PM.png]]<br />
<br />
<br />
The rotational angular momentum is zero, because even though the apparatus is rotating clockwise with angular speed, the barbell maintains its vertical orientation, so the rotational angular momentum of the the barbell is zero. The angular velocity of the barbell is zero, so the rotational angular momentum of the barbell is also zero.<br />
The magnitude is zero and there is no direction for rotational angular momentum.<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
===Middling===<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=File:Screen_Shot_2015-11-25_at_3.19.38_PM.png&diff=1390File:Screen Shot 2015-11-25 at 3.19.38 PM.png2015-11-25T20:20:44Z<p>Fatimajamil: picture</p>
<hr />
<div>picture</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1388Total Angular Momentum2015-11-25T20:15:02Z<p>Fatimajamil: /* Examples */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
<br />
The rotational angular momentum is zero, because even though the apparatus is rotating clockwise with angular speed, the barbell maintains its vertical orientation, so the rotational angular momentum of the the barbell is zero. The angular velocity of the barbell is zero, so the rotational angular momentum of the barbell is also zero.<br />
The magnitude is zero and there is no direction for rotational angular momentum.<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
===Middling===<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1387Total Angular Momentum2015-11-25T20:14:39Z<p>Fatimajamil: /* Simple */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
This simple example shows the importance of understanding the difference between rotational and translational angular momentum. <br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
'''a) Calculate Lrot (both magnitude and direction)<br />
'''<br />
The rotational angular momentum is zero, because even though the apparatus is rotating clockwise with angular speed, the barbell maintains its vertical orientation, so the rotational angular momentum of the the barbell is zero. The angular velocity of the barbell is zero, so the rotational angular momentum of the barbell is also zero.<br />
The magnitude is zero and there is no direction for rotational angular momentum.<br />
<br />
'''b) Calculate Ltrans,B (both magnitude and direction)<br />
'''<br />
[[File:Simple example 1.png]]<br />
<br />
===Middling===<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamilhttp://www.physicsbook.gatech.edu/index.php?title=Total_Angular_Momentum&diff=1386Total Angular Momentum2015-11-25T20:13:31Z<p>Fatimajamil: /* Simple */</p>
<hr />
<div>Work in Progress by Fatima Jamil<br />
<br />
Total angular momentum can be expressed as [[File:Total Angular Momentum.png]]. This page explains the breakdown of total angular momentum in these 2 components to help understand the difference between rotational angular momentum and translational angular momentum.<br />
<br />
==The Main Idea==<br />
<br />
[[File:Translational and Rotational Angular Momentum.png]]<br />
<br />
It is conveniant to break apart total angular momentum for a multiparticle system into rotational angular momentum and translational angular momentum. The translational angular momentum is associated with a rotation of the center of mass about some point A. This differs for different choices of the location of point A. The rotational angular momentum is associated with a rotation about the center of mass. The rotational angular momentum is independent of the location of the point A and the motion of the center of mass. <br />
<br />
===A Mathematical Model===<br />
<br />
It is often convenient to consider the angular momentum of a collection of particles about their center of mass, because this simplifies the mathematics considerably. The angular momentum of a collection of particles is the sum of the angular momenta of each particle:<br />
<br />
<math>\mathbf{L}=\sum_i \mathbf{R}_i\times m_i \mathbf{V}_i</math><br />
where <math>R_i</math> is the distance of particle i from the reference point, <math>m_i</math> is its mass, and <math>V_i</math> is its velocity. The center of mass is defined by:<br />
<br />
<math>\mathbf{R}=\frac{1}{M}\sum_i m_i \mathbf{R}_i</math><br />
where <math>M</math> is the total mass of all the particles.<br />
<br />
If we define <math>\mathbf{r}_i</math> as the displacement of particle i from the center of mass, and <math>\mathbf{v}_i</math> as the velocity of particle i with respect to the center of mass, then we have<br />
<br />
<math>\mathbf{R}_i=\mathbf{R}+\mathbf{r}_i\,</math> and <math>\mathbf{V}_i=\mathbf{V}+\mathbf{v}_i\,</math><br />
In this case, the total angular momentum is:<br />
<br />
<math>\mathbf{L}=\sum_i (\mathbf{R}+\mathbf{r}_i)\times m_i (\mathbf{V}+\mathbf{v}_i) = \left(\mathbf{R}\times M\mathbf{V}\right) + \left(\sum_i \mathbf{r}_i\times m_i \mathbf{v}_i\right)</math><br />
<br />
===A Computational Model===<br />
<br />
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]<br />
<br />
==Examples==<br />
<br />
Be sure to show all steps in your solution and include diagrams whenever possible<br />
<br />
===Simple===<br />
<br />
[[File:Screen Shot 2015-11-25 at 3.12.38 PM.png]]<br />
<br />
[[File:simple example.png]]<br />
<br />
a) Calculate Lrot (both magnitude and direction)<br />
<br />
The rotational angular momentum is zero, because even though the apparatus is rotating clockwise with angular speed, the barbell maintains its vertical orientation, so the rotational angular momentum of the the barbell is zero. The angular velocity of the barbell is zero, so the rotational angular momentum of the barbell is also zero.<br />
The magnitude is zero and there is no direction for rotational angular momentum.<br />
<br />
b) Calculate Ltrans,B.<br />
<br />
[[File:Simple example 1.png]]<br />
<br />
===Middling===<br />
===Difficult===<br />
<br />
==Connectedness==<br />
#How is this topic connected to something that you are interested in?<br />
#How is it connected to your major?<br />
#Is there an interesting industrial application?<br />
Total angular momentum is very interesting to witness in the orbit of planets and satellites. <br />
[[File:Application of Total Angular Momentum.png]]<br />
<br />
This image shows the translational angular momentum of the Earth (relative to the location of the Sun) and the rotational angular momentum (relative to the center of mass of the Earth). <br />
<br />
It is also important to note that for point particle systems that there is no rotational angular momentum, and only translational angular momentum. This is important, because the total angular momentum for a point particle system is just simply translational angular momentum. <br />
<br />
Understanding the topic of total angular momentum is extremely important in applying the conservation of angular momentum. Due to the fact that angular momentum is conserved, then it is important to note that if there is net force on some body directed towards a fix point, the center, then there is no torque on the body with respect to the center, and the angular momentum of the body about the center is constant. There is a very useful application of constant angular momentum, specifically seen in dealing with the orbits of planets and satellites. This concept is also used for the Bohr model of the atom.<br />
<br />
==History==<br />
<br />
Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.<br />
<br />
== See also ==<br />
<br />
Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?<br />
<br />
===Further reading===<br />
<br />
Books, Articles or other print media on this topic<br />
<br />
===External links===<br />
<br />
Internet resources on this topic<br />
<br />
==References==<br />
<br />
This section contains the the references you used while writing this page<br />
<br />
[[Category:Which Category did you place this in?]]</div>Fatimajamil