SHM – Simple Harmonic Motion
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Transcript of SHM – Simple Harmonic Motion
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SHM – Simple Harmonic Motion
Please pick the Learning Outcomes from the front of the room
Take a moment to review the Learning Outcomes
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A Couple Things…
1. This is an EXTREMELY quick and somewhat easy unit (3 classes)
2. We will be done by Spring Break3. 1 Class: Springs4. 2 Classes: Pendulums5. 3 Classes: Unit Quiz
We will be BASICALLY done all Theory by the end of today
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Oscillations and Simple Harmonic Motion:
AP Physics B
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Oscillatory Motion – Can you think of an example of an Oscillator?
Oscillatory Motion is repetitive back and forth motion about an equilibrium position
Oscillatory Motion is periodic.Swinging motion and vibrations are forms of
Oscillatory Motion.
Objects that undergo Oscillatory Motion are called Oscillators.
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Conditions for SHM
All objects that we look at are described the same
mathematically.
Any system with a linear restoring force will undergo simple
harmonic motion around the equilibrium position.
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What is the oscillation period for the broadcast of a 100MHz FM radio station?
Heinrich Hertz produced the first artificial radio waves back
in 1887!
T1f
11108Hz
110 8s10ns
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Simple Harmonic Motion
The most basic of all types of oscillation is depicted on
the bottom sinusoidal graph. Motion that follows
this pattern is called simple harmonic motion or SHM.
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Simple Harmonic Motion
The time to complete one full cycle of
oscillation is a Period.
T1f
f 1T
The amount of oscillations per second is called frequency and is measured in Hertz.
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Simple Harmonic Motion
An objects maximum displacement from its equilibrium position is
called the Amplitude (A) of the motion.
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Damped (NOT DAMPENING) Oscillations – Real Life
A slowly changing line that provides a border to
a rapid oscillation is called the envelope of
the oscillations.
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What would be the opposite of damping?
Resonance… a system that is “pushed” at just the right time
Think a child being pushed on a a swing
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What shape will a velocity-time graph have for SHM? Draw it!
Everywhere the slope (first derivative) of the position graph is zero, the velocity
graph crosses through zero.
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2cos tx t AT
We need a position function to describe the motion above. Hmmm what
could it be?
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Algebra MAXED out
Just a note… you DO NOT need to derive any of the following equations, however you are NOT given them on your equation sheet
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Mathematical Models of SHM
2cos tx t AT
cos 2x t A ft
cosx t A t
1Tf
2T
x(t) to symbolize position as a function of
time
A=xmax=xmin
When t=T, cos(2π)=cos(0)
x(t)=A
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A Little Calculus! (the rate of change!
Find velocity (the rate of change of position) by taking the derivative of the position equation!
cosx t A t
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Mathematical Models of SHM
sinv t A t
cosx t A t
d x tv t
dt
In this context we will call omega Angular
Frequency
What is the physical meaning of the product (Aω)?
maxv AThe maximum speed of an oscillation!
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Makes sense when you look at the curves at a given position
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Example: 1
An airtrack glider is attached to a spring, pulled 20cm to the right, and
released at t=0s. It makes 15 oscillations in 10 seconds.
What is the period of oscillation?15
10sec11.5oscilationsf HzT
1 1 0.671.5
T sf Hz
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Example: 2
An airtrack glider is attached to a spring, pulled 20cm to the right, and
released at t=0s. It makes 15 oscillations in 10 seconds.
What is the object’s maximum speed?
max2Av AT
max
0.2 21.88 /
0.67m
v m ss
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Example: 3
An airtrack glider is attached to a spring, pulled 20cm to the right, and
released at t=0s. It makes 15 oscillations in 10 seconds.
What are the position and velocity at t=0.8s?
sin 0.2 sin 0.8 1.79 /v t A t m s m s
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Example: 4
A mass oscillating in SHM starts at x=A and has period T. At what time, as
a fraction of T, does the object first pass through 0.5A?
2cos
( ) 0.5
tx t AT
x t A
20.5 cos tA AT
1cos 0.52T t
2 3T t
6
Tt
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We have modeled SHM mathematically. Now comes the physics.
Total mechanical energy is conserved for our SHM example of a spring with
constant k, mass m, and on a frictionless surface.
E K U12mv2 1
2kx2
The particle has all potential energy at x=A and x=–A, and the particle has purely kinetic energy at x=0.
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Total Energy Constant
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At turning points:
At x=0:
From conservation:
12kA2
12mvmax
2
Maximum speed as related to amplitude:
vmax kmA
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From energy considerations:
From kinematics:
Combine these:
vmax kmA
vmax A
km
f 12
km
T2 mk
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A toughie… are you ready?
E K U12mv2 1
2kx2
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a 500g block on a spring is pulled a distance of 20cm and released. The subsequent oscillations are measured to
have a period of 0.8s. at what position or positions is the block’s speed 1.0m/s?
The motion is SHM and energy is conserved.
12mv2 1
2kx2
12kA2
kx2 kA2 mv2
x A2 mkv2
x A2 v2
2
2T
20.8s
7.85rad /s
x0.15m
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If you didn’t get the last one… maybe this one…?
Find acceleration (the rate of change of velocity) by taking the derivative of the velocity equation!
sinv t A t
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Dynamics of SHM
Acceleration is at a maximum when the particle is at maximum and minimum displacement from x=0.
ax dvx (t)dt
d Asin t
dt 2Acos t
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Dynamics of SHM
Acceleration is proportional to the
negative of the displacement.
ax 2Acos t
ax 2x
xAcos t