Chapter 13
Vibrations and Waves
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Vibrations and Waves - General Physics I - Lecture Slides, Slides of Physics
Following points are the summary of these Lecture Slides : Vibrations and Waves, Harmonic Motion, Equations, Motion, Wave Motion, Wave Properties, Standing Waves, Resonance, Simple Harmonic Motion, Periodic Motion
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Chapter 13
Vibrations and Waves
Units of Chapter 13
Simple Harmonic Motion Equations of Motion Wave Motion Wave Properties Standing Waves and Resonance
13.1 Simple Harmonic Motion
Displacement (
x ) is the
directed distance of the objectfrom equilibrium. Amplitude (
A ) is the maximum
displacement. Period (
T ) is the time for one full cycle. Frequency (
f ) is the number of
full cycles per second.
13.1 Simple Harmonic Motion
SI unit of frequency: hertz, Hz 1 Hz = 1 cycle/second^ ANIMATION:
Simple Harmonic Motion
13.1 Simple Harmonic Motion
The total energy of an object in simple harmonicmotion is directly proportional to the square of theamplitude of the object’s displacement.
13.1 Simple Harmonic Motion
This allows us to calculate the velocity as afunction of position:^ and the maximum velocity (at
x^ = 0):
13.2 Equations of Motion
An equation of motion gives the position of anobject as a function of time. Simple harmonic motion can be representedas a component of uniform circular motion:
ANIMATION:
Uniform Circular Motion
13.2 Equations of Motion
The equation of motion for the oscillatingobject is given by: Here, the only possibility is that
y^ = 0 at
t^ = 0.
More likely, we would want
y^ =
A^ at
t^ = 0; that
is, at
t^ = 0 the object would have its maximum displacement. In that case,
13.2 Equations of Motion
This figure shows the displacement as afunction of time.
13.2 Equations of Motion
These graphs showthe form of theequation of motionfor different initialconditions.
13.2 Equations of Motion
In the real world, friction will cause anoscillating object to slow down and eventuallystop. This is called damped harmonic motion.
ANIMATION:
Damped Harmonic Motion
13.3 Wave Motion
A wave pulse is adisturbance thatpropagates througha medium. Ittransfers energywithout transferringmatter; the energyis a combination ofkinetic and potentialenergy.
13.3 Wave Motion
Such a wave will have a sinusoidal form inboth time and space. Amplitude: maximum displacement Wavelength: distance between points havingthe same phase Frequency: number of waves passing persecond Period: time for one complete wave to pass
13.3 Wave Motion
Relationship between wave speed,wavelength, period, and frequency: