A well thrown ball is caught in a well-padded mitt. m The deceleration of the ball is 2.10 x 104 and 1.85 ms (milli seconds) s² elapses from the time the ball touches the mitt and stops. (a) • Using the notation Ax for displacement, v for velocity at time t, v for the initial velocity, and a acceleration, determine what quantities are known and what are unknown. • Enter the values of some known quantities below. • Make sure you account for the signs of the vectors using the coordinate system used in Part 1. Enter to 3 significant figures V= a = t = m/s ✔m/s² S (b) Is the acceleration constant during the time the ball comes to a stop? (c) Which equation of motion can you use to calculate the initial velocity of the ball? 1.v=v₁ + at 2. Ax=vot+at² 3. ✓²=v²+2a(Ax)

A well thrown ball is caught in a well-padded mitt. m The deceleration of the ball is 2.10 x 104 and 1.85 ms (milli seconds) s² elapses from the time the ball touches the mitt and stops. (a) • Using the notation Ax for displacement, v for velocity at time t, v for the initial velocity, and a acceleration, determine what quantities are known and what are unknown. • Enter the values of some known quantities below. • Make sure you account for the signs of the vectors using the coordinate system used in Part 1. Enter to 3 significant figures V= a = t = m/s ✔m/s² S (b) Is the acceleration constant during the time the ball comes to a stop? (c) Which equation of motion can you use to calculate the initial velocity of the ball? 1.v=v₁ + at 2. Ax=vot+at² 3. ✓²=v²+2a(Ax)

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Description: PLEASE ANSWER QUICKLY AND I WILL RATE HIGHLY *10 A well thrown ball is caught in a well-padded mitt.mThe deceleration of the ball is 2.10 x 104 and 1.85 ms (milli seconds)s²elapses from the time the ball touches the mitt and stops.(a)Using the notati

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter3: Motion In Two Dimensions

Section: Chapter Questions

Problem 3CQ

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