A simple pendulum has a length of 0.532 m. The pendulum bob of mass 40.0 x 10³ kg is displaced 2.50 x 102 m from equilibrium and released. It then moves with simple harmonic motion (S.H.M.). a) i. Determine the time period of the pendulum. ÏÏ. iii. iv. Determine the maximum acceleration of the pendulum bob. Sketch a graph to show how the acceleration varies with displacement for the pendulum. The graph should show both axes with labels and unit, appropriate values indicated on each axis and a line of best fit. Determine the total kinetic and potential energy of the pendulum bob.

A simple pendulum has a length of 0.532 m. The pendulum bob of mass 40.0 x 10³ kg is displaced 2.50 x 102 m from equilibrium and released. It then moves with simple harmonic motion (S.H.M.). a) i. Determine the time period of the pendulum. ÏÏ. iii. iv. Determine the maximum acceleration of the pendulum bob. Sketch a graph to show how the acceleration varies with displacement for the pendulum. The graph should show both axes with labels and unit, appropriate values indicated on each axis and a line of best fit. Determine the total kinetic and potential energy of the pendulum bob.

Name: Q3, last part only A simple pendulum has a length of 0.532 m. The pend
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Description: Q3, last part only A simple pendulum has a length of 0.532 m. The pendulum bob of mass40.0 x 10³ kg is displaced 2.50 x 102 m from equilibrium and released. Itthen moves with simple harmonic motion (S.H.M.).a) i. Determine the time period of the pend

Physics for Scientists and Engineers with Modern Physics

10th Edition

ISBN:9781337553292

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter15: Oscillatory Motion

Section: Chapter Questions

Problem 21P

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