Recall that in simple harmonic oscillation, the oscillator's positionconforms to the the equationx (t) = A cos(@t + 4)Also recall that the instantaneous velocity the oscillator isv (t) = -wA sin(@t + o)%3DConsider an oscillation of amplitude 0.70 cm. At time t = 0, theocillator's position is x = 0.48 cm and its velocity is positive.Determine the phase constant o.-47°-81°133-43°31°

Name: Recall that in simple harmonic oscillation, the oscillator's position
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Description: Recall that in simple harmonic oscillation, the oscillator's positionconforms to the the equationx (t) = A cos(@t + 4)Also recall that the instantaneous velocity the oscillator isv (t) = -wA sin(@t + o)%3DConsider an oscillation of amplitude 0.70 cm

Given A = 0.7cm At, t=0, x= 0.48 cm. As given the velocity of mass is positive so the value of…

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Recall that in simple harmonic oscillation, the oscillator's position conforms to the the equation x (t) = A cos(@t + 4) %3D Also recall that the instantaneous velocity the oscillator is v (t) = -wA sin(@t + 4) Consider an oscillation of amplitude 0.70 cm. At time t 0, the oscillator's position is x = 0.48 cm and its velocity is positive. Determine the phase constant o.

Recall that in simple harmonic oscillation, the oscillator's position conforms to the the equation x (t) = A cos(@t + 4) %3D Also recall that the instantaneous velocity the oscillator is v (t) = -wA sin(@t + 4) Consider an oscillation of amplitude 0.70 cm. At time t 0, the oscillator's position is x = 0.48 cm and its velocity is positive. Determine the phase constant o.

Classical Dynamics of Particles and Systems

5th Edition

ISBN:9780534408961

Author:Stephen T. Thornton, Jerry B. Marion

Publisher:Stephen T. Thornton, Jerry B. Marion

Chapter12: Coupled Oscillations

Section: Chapter Questions

Problem 12.3P

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