

Study with the several resources on Docsity
Earn points by helping other students or get them with a premium plan
Prepare for your exams
Study with the several resources on Docsity
Earn points to download
Earn points by helping other students or get them with a premium plan
The concepts of displacement and velocity, providing formulas and examples to calculate these physical quantities. It also introduces the idea of instantaneous velocity as a derivative. A time-elapsed image of a hockey puck's motion and asks the reader to determine its displacement and velocity between specific time intervals.
Typology: Study notes
1 / 3
This page cannot be seen from the preview
Don't miss anything!


Velocity
Objective: Understand the definition of displacement and velocity; know how to calculate displacement and velocity, understand the idea of instantaneous velocity as a derivative.
The displacement of an object is the change in its position.
displacement ∆~r = ~r 2 − ~r 1 (1)
velocity ~v =
~r 2 − ~r 1 (t 2 − t 1 )
(The magnitude of velocity, |~v| is called the speed.)
Suppose that a hockey puck travels as shown in the time-elapsed image below. It starts at the lower left- hand corner at t=0 s. Each subsequent image is at t=1 s, t=2 s, etc. Use the image to answer the following questions. You will need to define a coordinate system and an origin. Let’s define the origin at the first image (t=0) with +x to the right and +y upward.
Figure 1: Each gridline represents 0.05 m.
What is the displacement of the puck between t = 1 s and t = 4 s? First, sketch the initial position vector ~r 1. Then sketch the second position vector ~r 2. Now, sketch the vector (~r 2 - ~r 1. Note that this is the vector that when added to ~r 1 gives you ~r 2. That’s because ~r 2 = ~r 1 + (~r 2 − ~r − 1). Now, calculate it algebraically.
displacement of puck = ~r 2 − ~r 1 = (3) Do you get the same thing? The numerical result should be consistent with your graphical result. The velocity of the puck is the displacement divided by the time interval. Remember that dividing a vector by a scalar gives results in a vector. Therefore, what is the velocity vector?
velocity of puck ~v = ~r 2 − ~r 1 t 2 − t 1
Note that is points in the direction of the motion as if it traveled along a straight line from point 1 to point 2. What is the speed of the puck?
speed of puck |~v| = (5) What is the direction of the puck’s motion expressed as a unit vector?
direction of velocity of puck ˆv =
~v |~v|
Put the pieces back together to check your work:
|~v|ˆv = (7)
The definition of velocity can be rewritten as
~r 2 − ~r 1 = ~v(t 2 − t 1 ) (8) which can be used to calculate
~r 2 = ~r 1 + ~v(t 2 − t 1 ) (9) This says that if we know the starting position of an object and we know the velocity of the object, we can predict the new position of the object. In component form, this equation looks like
< x 2 , y 2 , z 2 >=< x 1 , y 1 , z 1 > + < vx, vy , vz > (t 2 − t 1 ) (10) Since the x-component of the vector on the left of the equal sign must equal the x-component of the vector on the right of the equal sign (and likewise for the other components), then we can write
x 2 = x 1 + vx(t 2 − t 1 ) (11) y 2 = y 1 + vy (t 2 − t 1 ) (12) y 2 = y 1 + vy (t 2 − t 1 ) (13) For example, at time t 1 = 12. 18 s, a ball’s position vector is ~r 1 =< 20 , 8 , − 12 > m. The ball’s velocity is ~v =< 9 , − 4 , 6 > m/s. At time t 2 = 12. 21 s, where is the ball, assuming that its velocity hardly changes during this short time interval?
~r 2 = ~r 1 + ~v(t 2 − t 1 ) = (14) Note that if the velocity changes significantly during the time interval, in either magnitude or direction, our prediction for the new position may not be very accurate.
We use the symbol ∆ to mean “change of” or “take the final value of something – the initial value of something”. For example,
displacement of puck, or change of position, ∆~r = ~r 2 − ~r 1 (15)
change of time interval ∆t = t 2 − t 1 (16)
change of time interval ∆t = t 2 − t 1 (17)
velocity of puck ~v = ∆~r ∆t