Creating an exact duplicate of a graph.

Describe, in" rel="nofollow">in detail, how you would move in" rel="nofollow">in order to create an exact duplicate of this graph. 1. Start very close and stay in" rel="nofollow">in same position for four seconds. 2. Move halfway back in" rel="nofollow">in one second, and main" rel="nofollow">intain" rel="nofollow">in position for some time 3. Move back at a moderate pace. 4. Stay in" rel="nofollow">in place. Describe, in" rel="nofollow">in detail, how you would move in" rel="nofollow">in order to create an exact duplicate of this graph. 1. Steady 2. Increase velocity 3. Steady 4. Decrease velocity 5. Steady 6. Decrease velocity 7. Steady 8. Increase velocity 9. Steady How does the resultin" rel="nofollow">ing velocity time graph compare with the velocity time graph you predicted in" rel="nofollow">in procedure 11? Our position graph was similar, but opposite of the actual graph. Our velocity graph was not similar to actual graph. We had to adjust the time for the model in" rel="nofollow">in order to capture the whole graph. Describe any major differences. Our V shaped position graph was the opposite shape (^) based on the experience of usin" rel="nofollow">ing the cardboard startin" rel="nofollow">ing close to the computerized motion detector to generate a V usin" rel="nofollow">ing the motion detector cardboard. Our carrat shaped velocity graph predicted a rise as velocity in" rel="nofollow">increased until it reached the end. Then a decrease in" rel="nofollow">in velocity on the way down. Our velocity graph was not similar. The actual graph quickly gain" rel="nofollow">ined negative velocity goin" rel="nofollow">ing toward the motion detector, and then steadily gain" rel="nofollow">ined velocity until      

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