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Video Clips
RealVideo®
7:15 minutes (29:07 - 36:22)
Calculation of x(t) for pendulum; differential equation and independence of mass.
Prof. Walter Lewin
Sinusoidal Motion (10:09 of V10)
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RealVideo®
4:27 minutes (36:22 - 40:49)
Dependence of T on L, g for pendulum; m, k for spring explained qualitatively.
Prof. Walter Lewin
Pendulum Equation (29:07 of V10)
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RealVideo®
8:09 minutes (40:49 - 48:58)
Demonstration that period is independent of both mass and angle θ.
Prof. Walter Lewin
Pendulum Equation (29:07 of V10)
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RealVideo®
7:26 minutes (19:13 - 26:39)
Calculation of θmax by work-energy; phase angle and oscillation equation obtained.
Prof. Walter Lewin
Pendulum Oscillation I (12:09 of V18)
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RealVideo®
8:29 minutes (25:40 - 34:09)
Angular velocity and θ calculated for uniform rod swinging on a pin; proof of simple harmonic oscillation using torque.
Prof. Walter Lewin
Motion of Rod After Impulse (14:10 of V21)
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RealVideo®
2:20 minutes (34:09 - 36:29)
Explicit calculation of T for rod on a pin; demonstration to verify.
Prof. Walter Lewin
Rod Swinging on a Pin (25:40 of V21)
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RealVideo®
7:50 minutes (36:29 - 44:19)
Calculation of simple harmonic oscillation and period for swinging hoop; proof that it is the same as pendulum; demonstration of period.
Prof. Walter Lewin
Rod on a Pin Demonstration (34:09 of V21)
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RealVideo®
4:11 minutes (0:00 - 4:11)
Period of physical pendulum calculated for arbitrary geometry.
Prof. Walter Lewin
Torque, Simple Harmonic Motion
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RealVideo®
11:45 minutes (4:11 - 15:56)
Period of a physical pendulum, for rod, hoop, disc, and bob; experiment to verify T for rod.
Prof. Walter Lewin
General Physical Pendulum (beginning of V30)
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RealVideo®
4:52 minutes (15:56 - 20:48)
To obtain the same period, dimensions of physical pendula are compared and tested.
Prof. Walter Lewin
Specific Physical Pendula (4:11 of V30)
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Lecture Notes
PDF - 1.1 MB
#Page 1 to page 5
Simple pendulum; physical pendulum, with example; center of oscillation; torsional pendulum; percussion; damped oscillations; and critical damping.
Prof. Stanley Kowalski
Oscillatory Motion
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PDF
#Page 1 to page 14
Simple pendulum; physical pendulum, with example; center of oscillation; torsional pendulum; percussion; damped oscillations; and critical damping.
Prof. Stanley Kowalski
Oscillatory Motion
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PDF
Page 1
Simple and physical pendulums defined, with equations for period; parallel axis theorem defined; kinetic energy of rotational motion; summary of linear and rotational dynamics.
Dr. George Stephans
Torque
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PDF
Page 18 to page 33
Dr. Peter Dourmashkin, Prof. J. David Litster, Prof. David Pritchard, Prof. Bernd Surrow
Rotational Dynamics, Simple Harmonic Motion
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PDF
#Page 1 to page 7
Physical pendulum experiment setup and procedure.
Dr. Peter Dourmashkin, Prof. J. David Litster, Prof. David Pritchard, Prof. Bernd Surrow
Simple Pendulum
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Practice Problems
PDF
Problem 29
Elastic and inelastic collisions between a pendulum bob and an object.
Dr. Peter Dourmashkin, Prof. J. David Litster, Prof. David Pritchard, Prof. Bernd Surrow
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PDF
Problem 31
Motion of a simple pendulum.
Dr. Peter Dourmashkin, Prof. J. David Litster, Prof. David Pritchard, Prof. Bernd Surrow
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PDF
Problem 4
Measuring the speed of a bullet by shooting a block suspended by two cables.
Dr. Peter Dourmashkin, Prof. J. David Litster, Prof. David Pritchard, Prof. Bernd Surrow
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PDF
Problem 5
Oscillation of a ruler suspended from one end.
Dr. Peter Dourmashkin, Prof. J. David Litster, Prof. David Pritchard, Prof. Bernd Surrow
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PDF
Problem 2
Analysis of data collected in Experiment 8.
Dr. Peter Dourmashkin, Prof. J. David Litster, Prof. David Pritchard, Prof. Bernd Surrow
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PDF
#Problem 8
3-part pendulum problem; speed and kinetic energy at bottom, for two different masses.
Prof. Walter Lewin
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Exam Questions
PDF
#Problem 4
Motion of a baseball thrown on a small moon of Saturn.
Dr. George Stephans
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PDF
#Problem 6
For inelastic collision, finding initial and final velocities and pendulum attributes.
Dr. Peter Dourmashkin, Prof. Kate Scholberg
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PDF
Problem 5
Motion of an oscillating physical pendulum.
Dr. Peter Dourmashkin, Prof. J. David Litster, Prof. David Pritchard, Prof. Bernd Surrow
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PDF
Problem 1a
Period of a physical pendulum.
Dr. Peter Dourmashkin, Prof. J. David Litster, Prof. David Pritchard, Prof. Bernd Surrow
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PDF
#Problem 2b
Finding the period of a pendulum in a moving elevator.
Prof. Walter Lewin
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PDF
Problem 2c to problem 2d
Calculating θmax for pendulum after an inelastic collision between a bullet and a pendulum.
Prof. Walter Lewin
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PDF
Problem 3
5-part rotational dynamics problem; finding τ, I, equation of motion, T, and force at pin.
Prof. Walter Lewin
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