A mass weighing 4 N is attached to a spring whose constant is 2 N/m. The medium offers a damping force that is numerically equal to the instantaneous velocity. The mass is initially released from a point i m above the equilibrium position with a downward velocity of 8 m/s. Determine the time at which the mass passes through the equilibrium position, (Use g - 9.8 m/s? for the acceleration due to gravity.) 0.678 Find the time after the mass passes through the equilibrium position at which the mass attains its extreme displacement from the equilibrium position. 0.678 What is the position of the mass at this instant? 1.383

A mass weighing 4 N is attached to a spring whose constant is 2 N/m. The medium offers a damping force that is numerically equal to the instantaneous velocity. The mass is initially released from a point i m above the equilibrium position with a downward velocity of 8 m/s. Determine the time at which the mass passes through the equilibrium position, (Use g - 9.8 m/s? for the acceleration due to gravity.) 0.678 Find the time after the mass passes through the equilibrium position at which the mass attains its extreme displacement from the equilibrium position. 0.678 What is the position of the mass at this instant? 1.383

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Description: A mass weighing 4 N is attached to a spring whose constant is 2 N/m, The medium offers a damping force that is numericallyequal to the instantaneous velocity. The mass is initially released from a point 1 m above the equilibrium position with adownw

Classical Dynamics of Particles and Systems

5th Edition

ISBN:9780534408961

Author:Stephen T. Thornton, Jerry B. Marion

Publisher:Stephen T. Thornton, Jerry B. Marion

Chapter3: Oscillations

Section: Chapter Questions

Problem 3.31P

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