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| by Matt Schoonover
| | The content on this page has been moved to the page [[Speed vs Velocity]]. |
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| edited by Hyunsu Jo
| | This page should be deleted. |
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| claimed by Justin Duan (Fall 2016)
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| ==Speed and Velocity==
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| '''Main Idea'''
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| Velocity is a vector quantity, meaning that is has both magnitude and momentum. Speed is the magnitude of a velocity, meaning it's only a scalar without direction.
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| Objects with velocities inherently have a speed and objects with speed don't necessarily have to have a velocity if no direction is specified.
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| ===A Mathematical Model===
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| '''Speed'''
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| Speed = <math>\sqrt{V_x^2 + V_y^2 + V_z^2}</math>
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| Where <math>\boldsymbol{\vec{v}}</math> is the velocity vector.
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| Speed can also be considered as <math>\frac{d}{t}</math> in a one dimensional sense where you are only concerned about the object's speed in one dimension.
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| '''Velocity'''
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| Velocity = <math>\boldsymbol{\vec{v}} = \frac{\Delta\vec{r}}{\Delta{t}}</math>
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| Where <math>{\Delta\vec{r}}</math> is the change in the position of the object and t is the time period over which the change in position occurred.
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| ===A Computational Model===
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| Difference between speed and velocity could be easily explained by the pictures of two computational models.
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| In the first computational model, the speed which is a scalar quantity(one dimension) is only in x-direction.
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| [[File:Velocity.JPG]]
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| However, in the second computational model, the velocity is in both x and y direction which is in 3 Dimensional <x,y,z> plane which differentiates speed and velocity.
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| [[File:Speed.JPG]]
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| =Simple Example=
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| 1) What is the average speed of a person who walked a distance of 15 meters in 3 seconds?
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| This is a problem where we only care about a single dimension, in this case the direction is not specified but is assumed that it's in along the path of the distance. | |
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| Using the formula, speed = <math>\frac{d}{t}</math>, where d is 15 meters and t is 3 seconds, the speed is 15/3 = 5 meters per second.
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| 2) Find the velocity of a person who traveled from <0, 0, 10> to <10, 10, 20> in 5 seconds.
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| Using the formula <math>\boldsymbol{\vec{v}} = \frac{\Delta\vec{r}}{\Delta{t}}</math>, where <math>{\Delta\vec{r}}</math> is <10, 10, 20> - <0, 0, 10> = <10, 10, 10> and where <math>{\Delta{t}}</math> is 5,
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| <10, 10, 10> / 5 = <2, 2, 2>. So the velocity of the person is <2, 2, 2> m/s.
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| =Difficult Example=
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| 1) At time 0.3 seconds after the tennis ball has been hit by a tennis racket, the tennis ball is located at <4,7,3>m, relative to an origin of the tennis court. At time 0.6 seconds after the tennis ball got hit, it was located at <13, 10, 6>m.
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| What is the velocity of the tennis ball?
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| Use the formula: <math>\boldsymbol{\vec{v}} = \frac{\Delta\vec{r}}{\Delta{t}}</math>
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| <math>{\Delta\vec{r}}</math> = <13, 10, 6> - <4, 7, 3> = <9, 3, 3>
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| <math>{\Delta{t}}</math> = .6 - .3 = .3.
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| <9, 3, 3>/ .3 = <30,10,10> m/s
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| What is the speed of the tennis ball?
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| Use the formula: <math>\sqrt{V_x^2 + V_y^2 + V_z^2}</math>
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| speed = <math>\sqrt{30^2+10^2+10^2}</math> = 33.17m/s
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| ==Connectedness==
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| Both speed and velocity represents speed of an object. This is why speed and velocity are often interchangeably used in incorrect ways. Speed represents one dimensional speed of an object while velocity represents three dimensional speed of an object with directions of <x,y,z> plane.
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| == See also ==
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| *[[Vectors]]
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| *[[Velocity]]
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| *[[Newton’s First Law of Motion]]
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| ===External links===
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| * Physics lecture resources by Khan academy [https://www.khanacademy.org/science/physics]
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| * Physics lecture resources by Physics classroom [http://www.physicsclassroom.com/class]
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| ==References==
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| Matter and Interactions, Modern Mechanics, 3rd Edition by Chabay and Sherwood.
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| [[Category:Interactions]]
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| =Simple Examples=
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| 1. If a person walked a distance of 10 meters in 5 seconds, what is their average velocity?
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| Solution: Using the average velocity equation will tell you that the answer is 2 m/s.
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| 2. If someone traveled with a velocity of 13 m/s for 3 minutes, how far would they have traveled?
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| Solution: First convert 3 minutes to seconds(180). Then use the velocity equation to solve for distance. You should get 2,340 m.
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| 3. What is the unit vector for the velocity vector <3,4,0> m/s?
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| Solution: Use the speed equation to get that the speed is 5 and the unit vector equation to get a final answer of <3/5,4/5,0>
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| 4. What is the velocity of an object if the unit vector is <3,2,1> and the speed is 5 m/s?
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| Solution: 5 m/s * <3,2,1> = <15,10,5> m/s
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| == See also ==
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| *[[Kinds of Matter]]
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| *[[Detecting Interactions]]
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| *[[Fundamental Interactions]]
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| *[[System & Surroundings]]
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| *[[Newton's First Law of Motion]]
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| *[[Newton's Second Law of Motion]]
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| *[[Newton's Third Law of Motion]]
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| *[[Gravitational Force]]
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| *[[Terminal Velocity and Friction Due to Air]]
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| *[[Simple Harmonic Motion]]
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| *[[Electric Polarization]]
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| ===External links===
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| ----
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| * A physics resource written by experts for an expert audience [https://en.wikipedia.org/wiki/Portal:Physics Physics Portal]
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| * A wiki book on modern physics [https://en.wikibooks.org/wiki/Modern_Physics Modern Physics Wiki]
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| * The MIT open courseware for intro physics [http://ocw.mit.edu/resources/res-8-002-a-wikitextbook-for-introductory-mechanics-fall-2009/index.htm MITOCW Wiki]
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| * An online concept map of intro physics [http://hyperphysics.phy-astr.gsu.edu/hbase/hph.html HyperPhysics]
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| * Interactive physics simulations [https://phet.colorado.edu/en/simulations/category/physics PhET]
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| * OpenStax algebra based intro physics textbook [https://openstaxcollege.org/textbooks/college-physics College Physics]
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| * The Open Source Physics project is a collection of online physics resources [http://www.opensourcephysics.org/ OSP]
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| * A resource guide compiled by the [http://www.aapt.org/ AAPT] for educators [http://www.compadre.org/ ComPADRE]
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| ==References==
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| Matter and Interactions, Modern Mechanics, Volume One 4th Edition by Chabay and Sherwood.
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| [[Category:Interactions]]
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