Simple Harmonic Motion

Simple harmonic motion (SHM) is motion in which a restoring force is directly proportional to the displacement of an object
Nature's response to a perturbation or disturbance is often SHM

Circular Motion vs. SHM

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Frequency
- Frequency is the number of revolutions or cycles which occur each second
- Symbol is f
- Units are 1/s, or Hertz (Hz)
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Period
- Period is the time it takes for one complete revolution, or cycle.
- Symbol is T
- Unites are seconds (s)
- T = time for 1 cycle = time for 1 revolution
Relationship
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Angular frequency is the number of radians per second, and it corresponds to the angular velocity for an object traveling in uniform circular motion
Relationship
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An oscillating system is created by a releasing an object from a maximum displacement of 0.2 meters. The object makes 60 complete oscillations in one minute
Determine the object's angular frequency

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What is the object's position at time t=10s?

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At what time is the object at x=0.1m?

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A 5-kg block is attached to a 2000 N/m spring as shown and displaced a distance of 8 cm from its equilibrium position before being released.
Determine the period of oscillation, the frequency, and the angular frequency for the block

When an object undergoes SHM, kinetic and potential energy both vary with time, although total energy (E=K+U) remains constant

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A mass m is attached to a light string that swings without friction about the vertical equilibrium position

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A 2-kg block is attacked to a spring. A force of 20 N stretches the spring to a displacement of 0.5 meter
The spring constant

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The total energy
The speed at the equilibrium position

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The speed at x=0.30 meters
The speed at x=-0.4 meters

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The acceleration at the equilibrium position

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The magnitude of the acceleration at x=0.5 meters.
The net force at equilibrium position

$C:\25225E85\B09A51C6-0574-4A0C-A2C1-496768C10C63_files\image307.png$
The net force at x=0.25 meter
Where does kinetic energy = potential energy

A 2-kg block attached to an un-stretched spring of spring constant k=200 N/m as shown in the diagram below is released from rest. Determine the period of the block's oscillation and the maximum displacement of the block from its equilibrium while undergoing simple harmonic motion.