A certain mass is supported by a spring such that it is at rest 1m above the ground. The mass is pulled up 0.5 m and released at t= 0, creating a periodic up and down motion called simple harmonic motion. It takes 1.8 seconds for the mass to return to its original position each time. O Draw a graph to show the height of the mass above the ground as a function of time for the first 5.4 seconds. -4)+c for b) Write an equation as a cosine function in the form h = ascos your graph in part (a). c) Use your equation to determine all the time(s) in the first 5 seconds where the height of the mass above the ground is 0.5 m. Full algebraic solution.

A certain mass is supported by a spring such that it is at rest 1m above the ground. The mass is pulled up 0.5 m and released at t= 0, creating a periodic up and down motion called simple harmonic motion. It takes 1.8 seconds for the mass to return to its original position each time. O Draw a graph to show the height of the mass above the ground as a function of time for the first 5.4 seconds. -4)+c for b) Write an equation as a cosine function in the form h = ascos your graph in part (a). c) Use your equation to determine all the time(s) in the first 5 seconds where the height of the mass above the ground is 0.5 m. Full algebraic solution.

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Description: 3. A certain mass is supported by a spring such that it is at rest 1 m above the ground.The mass is pulled up 0.5 m and released at t= 0, creating a periodic up and downmotion called simple harmonic motion. It takes 1.8 seconds for the mass to retur

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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