Analyzing Simple Harmonic Motion in a Bifilar Pendulum Experiment

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SUMMARY

The discussion focuses on analyzing simple harmonic motion (SHM) in a bifilar pendulum experiment. Participants emphasize the importance of measuring the time for multiple oscillations and the distance of the rod to establish SHM. They recommend plotting the inverse of distance (d^-1) against time (t) and calculating the gradient (td) to derive equations linking acceleration, velocity, or displacement. Additionally, the potential energy as a function of angular displacement is highlighted as a crucial factor in confirming harmonic motion.

PREREQUISITES
  • Understanding of simple harmonic motion principles
  • Familiarity with bifilar pendulum setup and mechanics
  • Basic knowledge of trigonometry for calculating center of mass
  • Experience with graphing and interpreting mathematical relationships
NEXT STEPS
  • Learn how to derive equations of motion for simple harmonic oscillators
  • Explore the relationship between potential energy and angular displacement in pendulums
  • Study the mathematical methods for analyzing oscillatory motion
  • Investigate the effects of damping on simple harmonic motion
USEFUL FOR

Physics students, educators, and researchers interested in experimental mechanics and the analysis of oscillatory systems.

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Could someone please give me an overview of how I get from measuring the time taken for x oscillations and the distance of the rod, to proving it moves with simple harmonic motion? I know i have to plot t--d^-1 on a graph, then using the gradient (td) i need to do some maths magic to get either an equation linking acceleration to velocity or displacement (to prove the motion is simple harmonic).

the setup is like this http://www.egglescliffe.org.uk/physics/gravitation/bifilar/Image7.gif but i don't understand the rest of the experiment he has done...

thanks :)
 
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I think you could try to compute the potential energy as a function of the angular displacement. You simply (...well, I didn't try it, I don't know how simple it is) have to find the height of the center of mass with a bit of trigonometry.

If the energy is quadratic in phi (or nearly quadratic for small phi), the motion is harmonic (anyone correct me if I'm wrong).
 

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