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This topic covers Right Hand Rule.  
This topic covers Right Hand Rule.  
Claimed by: Layla Darian
Claimed by: Thomas Chiu fall 2024
<!-- Whoever edits this: please make sure the reader knows that right hand rule refers to cross products in general, not just angular momentum-->


==The Main Idea==
==The Main Idea==
The magnitude of the translational angular momentum doesn't tell us everything about the motion of an object. For example, to describe the motion of Earth's orbit if you are standing on the positive z axis looking toward the origin, the Earth is moving counterclockwise in the xy plane. However, this statement cannot be used mathematically. You can't add "counterclockwise in the xy plane" to "clockwise in the yz plane." Instead, we can use the right hand rule to describe the direction of angular momentum as a vector. The direction can be specified like this:
The right hand rule is used to find the direction of the cross product between two vectors in 3 dimensions. This has uses in many field of physics, including angular momentum and electromagnetism. For example, to describe the motion of Earth's orbit if you are standing on the positive z axis looking toward the origin, the Earth is moving counterclockwise in the xy plane. However, this statement cannot be used mathematically. You can't add "counterclockwise in the xy plane" to "clockwise in the yz plane." Instead, we can use the right hand rule to describe the direction of angular momentum as a vector. The direction can be specified like this:
* The plane in which both the position vector from the two objects and the momentum vector for the object of interest lie can be indicated by a unit vector perpendicular to that plane.  
* The plane in which both the position vector from the two objects and the momentum vector for the object of interest lie can be indicated by a unit vector perpendicular to that plane.  
* The direction of motion within the plane (clockwise or counterclockwise) can be indicated by establishing a right hand rule (RHR) for this unit vector.
* The direction of motion within the plane (clockwise or counterclockwise) can be indicated by establishing a right hand rule (RHR) for this unit vector.
* Right Hand Rule: Using your right arm, point your arm to represent the "r" vector. Now turn your palm in the direction of the momentum vector. Curl your fingers in that direction of the momentum, and extend your thumb outward. The unit vector representing the direction of the angular momentum is defined to point in the direction of your thumb.
* The cross product, or the result of the right hand rule will be a vector normal to the plane
*Hint: If the rotational motion is counterclockwise, your right thumb, therefore the unit vector, will point out of the plane. If the rotational motion is clockwise, the unit vector will point into the plane.


===A Mathematical Model===
===A Mathematical Model===
The direction of the angular momentum can also be solved through calculating the cross product of the '''r/B''' and '''p/V''' vectors.
The cross product looks like this. As shown, the magnitude of the cross product is computed by |a||b|sinθ. We use the right hand rule to determine direction if this method is used.
[[File:crossproduct-vis.png]]
To calculate the cross product from a matrix, multiply each component by its corresponding determinant. Use this visual representation to help you.
[[File:crossproduct-visual.png]]
For more on the explanation of how to calculate cross product, visit this website: https://www.mathsisfun.com/algebra/vectors-cross-product.html
Here is an example problem. Solve first using the right hand rule, and then solve mathematically with the cross product.
[[File:problem1.jpg]]
Answer:
The cross product should be <-12, 0, 0>
So the vector is in the -x direction, which the right hand rule also tells us.
===Visualization===
You can use your right hand to visualize the intuition of the Right Hand Rule. Consider the x-y-z space drawn with these axes from the origin:
[[File:xyzog500.png]]
Now, take your right hand and point your index finger forward (the direction your arm faces), point your thumb up, and point your middle finger perpendicular to your index finger.
Your thumb is the z-axis and points in the positive z-direction. Your index and middle fingers represent the x-y plane.
Your hand should look something like this:
[[File:right-hand250.png]]
Then you can visualize the x-y-z axes over your hand like this:
[[File:right-hand-directions250.png]]
Realize that you can rotate the x-y plane along the z-axis.
For example, if you were to rotate the original x-y plane in 90 degree increments clockwise, you would see this:
[[File:xyzog250f.png]]
[[File:xyz1rot250h.png]]
[[File:xyz2rot250h.png]]


The direction of the angular momentum can also be solved through calculating the cross product of the '''r''' and '''p''' vectors.  
Now, as you can see, your right hand indeed represents the entire x-y-z space.
[[File:right-hand-axis500.png]]


The cross product of two vectors can be solved as so:
==Performing the Right Hand Rule==


* Right Hand Rule: Using your right arm, point your arm to represent the '''r''' vector. Now turn your palm in the direction of the momentum or '''p''' vector. Curl your fingers in that direction of the momentum, and extend your thumb outward. The unit vector representing the direction of the angular momentum is defined to point in the direction of your thumb.
*Hint: If the rotational motion is counterclockwise, your right thumb, therefore the unit vector, will point out of the plane. If the rotational motion is clockwise, the unit vector will point into the plane.


[[File:crossproduct2.jpg]]
To find the magnetic field induced by a wire, you can do the same thing, point your thumb in the direction of current and your fingers show the magnetic field.  


[[File:Cross product.jpg]]
Counterclockwise example:
Notice your thumb points up in the +z direction when the direction from '''r''' to '''p''' is counterclockwise.


The first row is the standard basis vectors and must appear in the order given here.  The second row is the components of '''r''' and the third row is the components of '''p'''. First, the terms alternate in sign and notice that the 2x2 is missing the column below the standard basis vector that multiplies it as well as the row of standard basis vectors. To solve for the "i" component, you use the expression: bf - ce. Do the same for the "j" and "k" components, and this will give you your vector.
[[File:counterclockwise-example500.png]]


For more on the explanation of how to calculate cross product, visit this website: [https://www.mathsisfun.com/algebra/vectors-cross-product.html]
If the '''p''' vector is in the other direction relative to '''r''', you would need to turn your hand upside down to curl your fingers towards it.
In this case, your thumb points down in the -z direction!


Here are some example problems. Try solving the cross product:
[[File:clockwise-ex1.png]]


[[File:problem1.jpg]]
Click [[File:problem1ans.jpg]] for the answer


===A Computational Model===
This situation would also make your thumb point in the -z direction (Notice it is just the first image rotated 180 degrees).


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]
[[File:clockwise-ex2.png]]


==Examples==
==Examples==


Be sure to show all steps in your solution and include diagrams whenever possible
[[File:ex2.jpg]]
 
Ans: 4
 
[[File:ex3.jpg]]
 
Ans: 3
 
[[File:EX4.jpg]]
 
Ans: 3
 
[[File:EX5.jpg]]


===Simple===
Ans:
===Middling===
L(A)=L(B)=L(H) = <0, 0, -30>
===Difficult===
L(G)=L(C) = <0, 0, 0>
L(D)=L(E)=L(F) = <0, 0, +50>


==Connectedness==
==Connectedness==
#How is this topic connected to something that you are interested in?
The Right Hand Rule is a very essential component of solving cross products, such as in angular momentum problems. The concept is usually very tricky to understand, so I wanted to give my best insight on what helped me understand exactly how and why it works.
#How is it connected to your major?
 
#Is there an interesting industrial application?
 
Here are some interesting videos about the conservation of angular momentum:
 
 
https://www.youtube.com/watch?v=Aw5i994n2bw&feature=youtu.be
 
https://www.youtube.com/watch?v=OKbawIq3w7U


==History==
==History==


Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.
I wasn't able to find who was the first to apply the Right Hand Rule to angular momentum and torque. However, it seems that the right hand rule is applied to other aspects of physics
as well. For example, André-Marie Ampère, a French physicist and mathematician, created a right hand rule for circuits and electric currents. This is used when a vector must be defined
to represent the rotation of a body, a magnetic field, or a fluid. It reveals a connection between the current and the magnetic field lines in the magnetic field that the current created.
This right hand rule works exactly the same way as the one I have described above.


== See also ==
== See also ==


Are there related topics or categories in this wiki resource for the curious reader to explore?  How does this topic fit into that context?
The Right Hand Rule is a crucial part in solving [http://www.physicsbook.gatech.edu/The_Angular_Momentum_Principle Angular Momentum] and [http://www.physicsbook.gatech.edu/Torque Torque] problems.
 
===Further reading===
 
Books, Articles or other print media on this topic


===External links===
===External links===
[https://www.khanacademy.org/test-prep/mcat/physical-processes/magnetism-mcat/a/using-the-right-hand-rule Khan Academy]


Internet resources on this topic
[http://mathworld.wolfram.com/Right-HandRule.html Wolfram MathWorld]


==References==
==References==


This section contains the the references you used while writing this page
The following pictures were created in Adobe Photoshop using pictures taken by me:
*Cross product visualization
*All Right Hand Rule visualization pictures


[[Category:Which Category did you place this in?]]
All other pictures and videos were taken from Professor Flavio Fenton's Physics 2211 lecture notes.
https://en.wikipedia.org/wiki/Right-hand_rule

Latest revision as of 13:30, 24 November 2024

This topic covers Right Hand Rule. Claimed by: Thomas Chiu fall 2024

The Main Idea

The right hand rule is used to find the direction of the cross product between two vectors in 3 dimensions. This has uses in many field of physics, including angular momentum and electromagnetism. For example, to describe the motion of Earth's orbit if you are standing on the positive z axis looking toward the origin, the Earth is moving counterclockwise in the xy plane. However, this statement cannot be used mathematically. You can't add "counterclockwise in the xy plane" to "clockwise in the yz plane." Instead, we can use the right hand rule to describe the direction of angular momentum as a vector. The direction can be specified like this:

  • The plane in which both the position vector from the two objects and the momentum vector for the object of interest lie can be indicated by a unit vector perpendicular to that plane.
  • The direction of motion within the plane (clockwise or counterclockwise) can be indicated by establishing a right hand rule (RHR) for this unit vector.
  • The cross product, or the result of the right hand rule will be a vector normal to the plane

A Mathematical Model

The direction of the angular momentum can also be solved through calculating the cross product of the r/B and p/V vectors. The cross product looks like this. As shown, the magnitude of the cross product is computed by |a||b|sinθ. We use the right hand rule to determine direction if this method is used.

To calculate the cross product from a matrix, multiply each component by its corresponding determinant. Use this visual representation to help you.


For more on the explanation of how to calculate cross product, visit this website: https://www.mathsisfun.com/algebra/vectors-cross-product.html

Here is an example problem. Solve first using the right hand rule, and then solve mathematically with the cross product.

Answer: The cross product should be <-12, 0, 0> So the vector is in the -x direction, which the right hand rule also tells us.

Visualization

You can use your right hand to visualize the intuition of the Right Hand Rule. Consider the x-y-z space drawn with these axes from the origin:

Now, take your right hand and point your index finger forward (the direction your arm faces), point your thumb up, and point your middle finger perpendicular to your index finger. Your thumb is the z-axis and points in the positive z-direction. Your index and middle fingers represent the x-y plane.

Your hand should look something like this:

Then you can visualize the x-y-z axes over your hand like this:

Realize that you can rotate the x-y plane along the z-axis. For example, if you were to rotate the original x-y plane in 90 degree increments clockwise, you would see this:

Now, as you can see, your right hand indeed represents the entire x-y-z space.

Performing the Right Hand Rule

  • Right Hand Rule: Using your right arm, point your arm to represent the r vector. Now turn your palm in the direction of the momentum or p vector. Curl your fingers in that direction of the momentum, and extend your thumb outward. The unit vector representing the direction of the angular momentum is defined to point in the direction of your thumb.
  • Hint: If the rotational motion is counterclockwise, your right thumb, therefore the unit vector, will point out of the plane. If the rotational motion is clockwise, the unit vector will point into the plane.

To find the magnetic field induced by a wire, you can do the same thing, point your thumb in the direction of current and your fingers show the magnetic field.

Counterclockwise example: Notice your thumb points up in the +z direction when the direction from r to p is counterclockwise.

If the p vector is in the other direction relative to r, you would need to turn your hand upside down to curl your fingers towards it. In this case, your thumb points down in the -z direction!


This situation would also make your thumb point in the -z direction (Notice it is just the first image rotated 180 degrees).

Examples

Ans: 4

Ans: 3

Ans: 3

Ans: L(A)=L(B)=L(H) = <0, 0, -30> L(G)=L(C) = <0, 0, 0> L(D)=L(E)=L(F) = <0, 0, +50>

Connectedness

The Right Hand Rule is a very essential component of solving cross products, such as in angular momentum problems. The concept is usually very tricky to understand, so I wanted to give my best insight on what helped me understand exactly how and why it works.


Here are some interesting videos about the conservation of angular momentum:


https://www.youtube.com/watch?v=Aw5i994n2bw&feature=youtu.be

https://www.youtube.com/watch?v=OKbawIq3w7U

History

I wasn't able to find who was the first to apply the Right Hand Rule to angular momentum and torque. However, it seems that the right hand rule is applied to other aspects of physics as well. For example, André-Marie Ampère, a French physicist and mathematician, created a right hand rule for circuits and electric currents. This is used when a vector must be defined to represent the rotation of a body, a magnetic field, or a fluid. It reveals a connection between the current and the magnetic field lines in the magnetic field that the current created. This right hand rule works exactly the same way as the one I have described above.

See also

The Right Hand Rule is a crucial part in solving Angular Momentum and Torque problems.

External links

Khan Academy

Wolfram MathWorld

References

The following pictures were created in Adobe Photoshop using pictures taken by me:

  • Cross product visualization
  • All Right Hand Rule visualization pictures

All other pictures and videos were taken from Professor Flavio Fenton's Physics 2211 lecture notes. https://en.wikipedia.org/wiki/Right-hand_rule