●S/2 | sin(t) |dt•(3+27) dedx-(18) The acceleration function in km/sec² is a(t)3t+7 where time t is in seconds, and0 ≤t≤ 10. Let v(t) (in km/sec) and s(t) (in km) be the velocity and position functions= 4 km.= 45 km/sec and the initial position s(0)respectively with the initial velocity, v(0)Find the velocity function and the position functions. Then, find the total distance covered.

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S/2 | sin(t)\ dt • S² ( ² /3 + x²) dx (18) The acceleration function in km/sec² is a(t): 3t+7 where time t is in secon 0 ≤t≤ 10. Let v(t) (in km/sec) and s(t) (in km) be the velocity and position f respectively with the initial velocity, v(0) = 45 km/sec and the initial position s(0) Find the velocity function and the position functions. Then, find the total distance

S/2 | sin(t)\ dt • S² ( ² /3 + x²) dx (18) The acceleration function in km/sec² is a(t): 3t+7 where time t is in secon 0 ≤t≤ 10. Let v(t) (in km/sec) and s(t) (in km) be the velocity and position f respectively with the initial velocity, v(0) = 45 km/sec and the initial position s(0) Find the velocity function and the position functions. Then, find the total distance

Physics for Scientists and Engineers, Technology Update (No access codes included)

9th Edition

ISBN:9781305116399

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter3: Vectors

Section: Chapter Questions

Problem 3.62AP: After a ball rolls off the edge of a horizontal table at time t = 0, its velocity as a function of...

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