In this lab, we videos us throwing a ball in a parabolic shape. We used the video and the PASCO keystone program to make graphs and learn more about the acceleration, velocity, and motion of the ball. Here is a video of our throw:
Once we plotted data points, PASCO gave us a position vs time for both horizontal and vertical movement. The green line shows the vertical position vs time while the purple line shows the horizontal movement. The green line's slope is constantly changing, and it shows us that the object has acceleration. Also, the line switches directions, showing a shift in direction of the ball. The purple line has a constant slope, indicating constant velocity. The ball had no forces acting on it in the horizontal direction and because of this it had a constant velocity.
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Our second graph shows us the velocity vs time of the object in the vertical and horizontal directions. The yellow line is the vertical direction and the red line is the horizontal line.
The yellow line shows that the velocity begins at a very high rate and then begins to slow down. The line then hits the origin, showing a change in direction. The ball then begins to pick up speed in the negative direction. The line also has a slope, which is constant, which shows acceleration. The slope of our line is close to -11 (acceleration) whereas the actual acceleration of the ball should have been -9.8 m/s^2 (the true acceleration of gravity. Although the numbers weren't totally correct, they were pretty close. The red line shows no slope. This means that the velocity of the ball in the horizontal direction was constant, which is the case because of its lack of forces in the horizontal direction.
Analysis:
a) The only force acting on the ball after it left my hand was gravity. This means that the acceleration of the ball was -9.8m/s^2 (the acceleration of only gravity acting on anything)
b)There are no forces acting on the ball in the horizontal direction. This means that the ball's forces are balanced in the horizontal direction, giving it no acceleration.
c) By using our graph, we can tell that the initial horizontal velocity is very close to .6 m/s.
d) The initial velocity in the vertical direction was 2.6 m/s according to our graph.
e) The velocity in the horizontal direction was constant the whole time. This means that at the top of the path, the ball was still going .6 m/s.
f) At the top of the path in the vertical direction, the ball is switching direction and momentarily has a velocity of 0 m/s.
g) At the end of our test, the ball stops on the ground (eventually) and has a velocity of 0 m/s in the horizontal direction.
h) At the end of our test, the ball stops on the ground (eventually) and has a velocity of 0 m/s in the vertical direction.
i) Using the equation Change in x = 1/2(a)t^2 +vit, we can calculate the height the ball got. The ball reached its highest point after .9 seconds (according to graph)
Conclusions: What occlusions can you make about projectile motion?
a) The vertical acceleration on our graph shows -11 m/s^2. In reality, this should be closer to -9.8 m/s^2 because of the acceleration of gravity. The only force on the ball is gravity, giving it this acceleration. The slightly larger acceleration is probably due to minor errors while plotting points on our graph. There are no forces acting on the ball in the horizontal direction. This means that the horizontal axis is balanced, and the ball has no horizontal acceleration.
b) The equation for horizontal velocity is (change in horizontal position)/time. this velocity should stay constant throughout t ball's motion. The equation for vertical velocity is (change in vertical position)/time. This velocity will change throughout the motion of the ball.
c) Vertical formula for displacement: Displacement = 1/2(at)(t^2) + (Vi)(t)
Horizontal formula for displacement: displacement = (.6)t
d) Displacement = 1/2(a)(t^2) + Vi(t)
e) The ball has a vertical velocity of 0 m/s at the very peak of its path, but the horizontal velocity stays constant throughout the whole motion.
