In this exercise you will analyze two video clips. The clips show a cart being pulled by a constant force F for some time interval ∆t. The velocity of the cart at t = 0 is zero. After the time interval the force is zero and the cart moves with approximately constant velocity. You will determine the magnitude of the impulse I = F∆t received by the cart, and its velocity and momentum after the force has dropped to zero.
Procedure:
Choose the impulse_1.mp4 and the impulse_2.mp4 video clips. In the video clip impulse_1. mp4 the cart is pulled by a constant force for some time ∆t . If you bring up the clip and use the step up button, you will see that the force sensor reading varies between 0.76 and 0.72 N until you get to approximately 1.4 seconds. (The time box displays the time for each frame.) At ∆t ~ 1.4 s the force sensor reading drops to ~0.
During the first 1.4 s, when the force is not zero, the
cart is accelerating. Its velocity and therefore its momentum are changing.
The impulse F*∆t is equal to the change in momentum ∆p = p_{final}
– p_{initial} = p_{final}, since p_{initial} = 0.
After 1.4 s the force is zero, there is no acceleration, the cart is moving with
constant speed. Use the step up button to
step to t ~ 1.4s. Then calibrate and start taking data. Find
the position of the cart as a function of time. Import your data into Excel.
To play a video clip or to step through it framebyframe click the "Begin" button. The "Video Analysis" web page will open.
To find the magnitude of the impulse received by the cart, step through the video clip framebyframe and note the time interval ∆t through which the force acts. Multiply the force sensor reading by ∆t to find the magnitude of the impulse I. Estimate the uncertainty in F, ∆t, and I.  
To find the final velocity of the cart step through the video clip and start taking data after the force has dropped to zero. Determine the position of the cart as a function of time by stepping through the video clip framebyframe and by reading the time and the position coordinates of the cart off each frame. Construct a spreadsheet with columns for time and position. The slope of a position versus time graph yields the velocity of the cart.  
To find the magnitude of the final momentum p of the cart multiply its
speed by its mass. Estimate the uncertainty in the magnitude of the
final momentum p. To estimate your uncertainties you must think about the uncertainties in the experiment. How well did you estimate the average force? (The reading in the impulse_1. mp4 clip varies between 0.77 N and 0.70 N. If you estimate the average force to be 0.73 N, the uncertainty is probably on the order of 0.02 N to 0.03 N.) How well did you estimate ∆t? (At what time exactly did the force drop to near zero? There is probably a one frame or 0.07s uncertainty.) What is the uncertainty in the slope and therefore in v? Which quantities have the largest percentage errors? Some estimates are quite subjective, but others, such as the uncertainty in the slope, are computed by Excel using a welldefined algorithm. In every measurement there are uncertainties. It important to make reasonable assumptions about the magnitudes of these uncertainties. Then one can check how the uncertainties affect the results. For example, if you estimated an error of 5% in the force, you would have an error of 5% in p_{final}.  
Compare I and p. Comment on your results. 
To earn extra credit add your name and email address to your spreadsheet. In full sentences answer the following question.
What values did you obtain for I and p (numbers and units) for the video
clip impulse_1. mp4?
 
What values did you obtain for I and p (numbers and units) for the video
clip impulse_2. mp4?

Save your Excel document (your name_exm7.xlsx). Go to Blackboard, Assignments, Extra Credit 7, and attach your document.