The graphs of position and acceleration as function of time for an oscillatingmass-spring apparatus are shown below. The mass of the apparatus is 40.0 kg.Position (cm)2-1- Time (s)-1Acceleration (cm/s?)- Time (s)The graphs of position and acceleration as functions of time for an oscillating simple pendulum are shown.The spring constant k is most nearly:100 N/m300 N/m200 N/m250 N/m150 N/m350 N/m400 N/m50 N/m Which of the following choices is an expression for the velocity v of the mass asa function of time t (in cm/s)? Your answer must be consistent with the position-time and acceleration-time graphs shown.-cos (nt)v = :v =cos2v =cosv =- sin(nt)22-sinV =2

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Description: The graphs of position and acceleration as function of time for an oscillatingmass-spring apparatus are shown below. The mass of the apparatus is 40.0 kg.Position (cm)2-1- Time (s)-1Acceleration (cm/s?)- Time (s)The graphs of position and accelerati

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The graphs of position and acceleration as function of time for an oscillating mass-spring apparatus are shown below. The mass of the apparatus is 40.0 kg. Position (cm) 34 2- + Time (s) -1 -2- -3- Acceleration (cm/s°

The graphs of position and acceleration as function of time for an oscillating mass-spring apparatus are shown below. The mass of the apparatus is 40.0 kg. Position (cm) 34 2- + Time (s) -1 -2- -3- Acceleration (cm/s°

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter12: Oscillatory Motion

Section12.2: Analysis Model: Particle In Simple Harmonic Motion

Problem 12.4QQ: An object of mass m is hung from a spring and set into oscillation. The period of the oscillation is...

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