A simple harmonic oscillator consists of a 100-g mass attached to a spring whose force constant is 10 dyne/cm. The mass is displaced 3 cm and released from rest. The oscillator of Problem 3-1 is set into motion by giving it an initial velocity of 1 cm/s at its equilibrium position. Calculate (a) the maximum displacement and (b) the maximum potential energy.

A simple harmonic oscillator consists of a 100-g mass attached to a spring whose force constant is 10 dyne/cm. The mass is displaced 3 cm and released from rest. The oscillator of Problem 3-1 is set into motion by giving it an initial velocity of 1 cm/s at its equilibrium position. Calculate (a) the maximum displacement and (b) the maximum potential energy.

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Question

A simple harmonic oscillator consists of a 100-g mass attached to a spring whose force constant is 10 dyne/cm. The mass is displaced 3 cm and released from rest.
The oscillator of Problem 3-1 is set into motion by giving it an initial velocity of 1 cm/s at its equilibrium position. Calculate (a) the maximum displacement and (b) the maximum potential energy.

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