chapter 13 vibrations and waves. when x is positive, f is negative ; when at equilibrium (x=0), f =...
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![Page 1: Chapter 13 Vibrations and Waves. When x is positive, F is negative ; When at equilibrium (x=0), F = 0 ; When x is negative, F is positive ; Hooke’s Law](https://reader035.vdocuments.us/reader035/viewer/2022062222/56649d3f5503460f94a18ae9/html5/thumbnails/1.jpg)
Chapter 13Chapter 13
Vibrations and Waves
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• When x is positive ,F is negative ;
• When at equilibrium (x=0), F = 0 ;
• When x is negative ,F is positive ;
Hooke’s Law ReviewedHooke’s Law Reviewed
F =−kx
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Sinusoidal OscillationSinusoidal Oscillation
Pen traces a sine wave
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Graphing x vs. tGraphing x vs. t
A : amplitude (length, m) T : period (time, s)
A
T
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Some VocabularySome Vocabulary
f = Frequency = Angular FrequencyT = PeriodA = Amplitude = phase
x =Acos(t−φ)=Acos(2π ft−φ)
=Acos2πtT
−φ⎛⎝⎜
⎞⎠⎟
f =1T
=2π f =2πT
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PhasesPhases
Phase is related to starting time
90-degrees changes cosine to sine
x =Acos2πtT
−φ⎛⎝⎜
⎞⎠⎟
=Acos2π(t−t0 )
T⎛⎝⎜
⎞⎠⎟
if φ =2πt0T
cos t−π2
⎛⎝⎜
⎞⎠⎟=sin t( )
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a
x
v
• Velocity is 90 “out of phase” with x: When x is at max,v is at min ....
• Acceleration is 180° “out of phase” with x a = F/m = - (k/m) x
Velocity and Velocity and Acceleration vs. Acceleration vs. timetime
T
T
T
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vv and and aa vs. t vs. t
Find vmax with E conservation
Find amax using F=ma
x =Acostv=−vmaxsinta=−amax cost
1
2kA2 =
12
mvmax2
vmax =Akm
−kx = ma−kAcosωt = −mamax cosωt
amax = Ak
m
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What is What is ??Requires calculus. Since
d
dtAcost =−Asint
vmax =A=Akm
=k
m
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Formula SummaryFormula Summary
f =1T
=2π f =2πT
x =Acos(t−φ)v=−Asin(t−φ)
a=− 2A(cost−φ)
=k
m
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Example13.1Example13.1
An block-spring system oscillates with an amplitude of 3.5 cm. If the spring constant is 250 N/m and the block has a mass of 0.50 kg, determine
(a) the mechanical energy of the system
(b) the maximum speed of the block
(c) the maximum acceleration.
a) 0.153 J
b) 0.783 m/s
c) 17.5 m/s2
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Example 13.2Example 13.2
A 36-kg block is attached to a spring of constant k=600 N/m. The block is pulled 3.5 cm away from its equilibrium positions and released from rest at t=0. At t=0.75 seconds,
a) what is the position of the block?
b) what is the velocity of the block?
a) -3.489 cm
b) -1.138 cm/s
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Example 13.3Example 13.3
A 36-kg block is attached to a spring of constant k=600 N/m. The block is pulled 3.5 cm away from its equilibrium position and is pushed so that is has an initial velocity of 5.0 cm/s at t=0.
a) What is the position of the block at t=0.75 seconds?
a) -3.39 cm
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Example 13.4aExample 13.4a
An object undergoing simple harmonic motion follows the expression,
x(t)=4 + 2cos[π (t−3)]
The amplitude of the motion is:a) 1 cmb) 2 cmc) 3 cmd) 4 cme) -4 cm
Where x will be in cm if t is in seconds
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Example 13.4bExample 13.4b
An object undergoing simple harmonic motion follows the expression,
x(t)=4 + 2cos[π (t−3)]
The period of the motion is:a) 1/3 sb) 1/2 sc) 1 sd) 2 se) 2/π s
Here, x will be in cm if t is in seconds
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Example 13.4cExample 13.4c
An object undergoing simple harmonic motion follows the expression,
x(t)=4 + 2cos[π (t−3)]
The frequency of the motion is:a) 1/3 Hzb) 1/2 Hzc) 1 Hzd) 2 Hze) π Hz
Here, x will be in cm if t is in seconds
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Example 13.4dExample 13.4d
An object undergoing simple harmonic motion follows the expression,
x(t)=4 + 2cos[π (t−3)]
The angular frequency of the motion is:a) 1/3 rad/sb) 1/2 rad/sc) 1 rad/sd) 2 rad/se) π rad/s
Here, x will be in cm if t is in seconds
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Example 13.4eExample 13.4e
An object undergoing simple harmonic motion follows the expression,
x(t)=4 + 2cos[π (t−3)]
The object will pass through the equilibrium positionat the times, t = _____ seconds
a) …, -2, -1, 0, 1, 2 … b) …, -1.5, -0.5, 0.5, 1.5, 2.5, …c) …, -1.5, -1, -0.5, 0, 0.5, 1.0, 1.5, …d) …, -4, -2, 0, 2, 4, …e) …, -2.5, -0.5, 1.5, 3.5,
Here, x will be in cm if t is in seconds
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Simple PendulumSimple Pendulum
Looks like Hooke’s law (k mg/L)
F =−mgsinθ
sinθ =x
x2 + L2≈
xL
F ≈−mgL
x
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Simple PendulumSimple PendulumF =−mgsinθ
sinθ =x
x2 + L2≈
xL
F ≈−mgL
x
=g
Lθ = θmax cos(ωt −φ)
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Simple pendulumSimple pendulum
Frequency independent of mass and amplitude!(for small amplitudes)
=g
L
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Pendulum DemoPendulum Demo
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Example 13.5Example 13.5A man enters a tall tower, needing to know its height h. He notes that a long pendulum extends from the roof almost to the ground and that its period is 15.5 s.
(a) How tall is the tower?
(b) If this pendulum is taken to the Moon, where the free-fall acceleration is 1.67 m/s2, what is the period of the pendulum there?
a) 59.7 m
b) 37.6 s
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Damped OscillationsDamped Oscillations
In real systems, friction slows motion
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TRAVELING WAVESTRAVELING WAVES
•Sound•Surface of a liquid•Vibration of strings•Electromagnetic
•Radio waves•Microwaves•Infrared•Visible•Ultraviolet•X-rays•Gamma-rays
•Gravity
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Longitudinal (Compression) WavesLongitudinal (Compression) Waves
Sound waves are longitudinal waves
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Compression and Transverse Waves Compression and Transverse Waves DemoDemo
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Transverse WavesTransverse Waves
Elements move perpendicular to wave motionElements move parallel to wave motion
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Snapshot of a Transverse WaveSnapshot of a Transverse Wave
wavelength
x
y =Acos 2π xλ
−φ⎛⎝⎜
⎞⎠⎟
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Snapshot of Longitudinal Snapshot of Longitudinal Wave Wave
λ
y could refer to pressure or density
y =Acos 2π xλ
−φ⎛⎝⎜
⎞⎠⎟
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Moving WaveMoving Wave
moves to right with velocity v
Fixing x=0,
Replace x with x-vtif wave moves to the right.Replace with x+vt if wave should move to left.y =Acos 2π x−vt
λ−φ⎛
⎝⎜⎞⎠⎟
y =Acos −2π vλ
t−φ⎛⎝⎜
⎞⎠⎟
f =vλ
, v= fλ
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Moving Wave: Formula SummaryMoving Wave: Formula Summary
y =Acos 2π x
λmft⎛
⎝⎜⎞⎠⎟−φ⎡
⎣⎢⎤
⎦⎥
v = fλ
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Example 13.6aExample 13.6a
A wave traveling in the positive x direction has a frequency of f = 25.0 Hz as shown in the figure. The wavelength is:
a) 5 cmb) 9 cmc) 10 cmd) 18 cme) 20 cm
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Example 13.6bExample 13.6b
A wave traveling in the positive x direction has a frequency of f = 25.0 Hz as shown in the figure. The amplitude is:
a) 5 cmb) 9 cmc) 10 cmd) 18 cme) 20 cm
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Example 13.6cExample 13.6c
A wave traveling in the positive x direction has a frequency of f = 25.0 Hz as shown in the figure. The speed of the wave is:
a) 25 cm/sb) 50 cm/sc) 100 cm/sd) 250 cm/se) 500 cm/s
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Example 13.7aExample 13.7a
Consider the following expression for a pressure wave,
where it is assumed that x is in cm,t is in seconds and P will be given in N/m2.
What is the amplitude?a) 1.5 N/m2
b) 3 N/m2
c) 30 N/m2
d) 60 N/m2
e) 120 N/m2
P =60⋅cos 2x−3t( )
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Example 13.7bExample 13.7b
Consider the following expression for a pressure wave,
where it is assumed that x is in cm,t is in seconds and P will be given in N/m2.
What is the wavelength?a) 0.5 cmb) 1 cmc) 1.5 cmd) π cme) 2π cm
P =60⋅cos 2x−3t( )
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Example 13.7cExample 13.7c
Consider the following expression for a pressure wave,
where it is assumed that x is in cm,t is in seconds and P will be given in N/m2.
What is the frequency?a) 1.5 Hzb) 3 Hzc) 3/π Hzd) 3/(2π) Hze) 3π2 Hz
P =60⋅cos 2x−3t( )
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Example 13.7dExample 13.7d
Consider the following expression for a pressure wave,
where it is assumed that x is in cm,t is in seconds and P will be given in N/m2.
What is the speed of the wave?a) 1.5 cm/sb) 6 cm/sc) 2/3 cm/sd) 3π/2 cm/se) 2/π cm/s
P =60⋅cos 2x−3t( )
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Example 13.8Example 13.8Which of these waves move in the positive x direction?
a) 5 and 6b) 1 and 4c) 5,6,7 and 8d) 1,4,5 and 8e) 2,3,6 and 7
1)y =−21.3⋅cos(3.4x+ 2.5t)2)y=−21.3⋅cos(3.4x−2.5t)3)y=−21.3⋅cos(−3.4x+ 2.5t)4)y=−21.3⋅cos(−3.4x−2.5t)5)y=21.3⋅cos(3.4x+ 2.5t)6)y=21.3⋅cos(3.4x−2.5t)7)y=21.3⋅cos(−3.4x+ 2.5t)8)y=21.3⋅cos(−3.4x−2.5t)
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Speed of a Wave in a Vibrating Speed of a Wave in a Vibrating StringString
For different kinds of waves: (e.g. sound)• Always a square root• Numerator related to restoring force• Denominator is some sort of mass density
v =Tμ
where μ =mL
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Example 13.9Example 13.9
A string is tied tightly between points A and B as a communication device. If one wants to double the wave speed, one could:
a) Double the tensionb) Quadruple the tensionc) Use a string with half the massd) Use a string with double the masse) Use a string with quadruple the mass
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Superposition Superposition PrinciplePrinciple
Traveling waves can pass through each other without being altered.
y(x,t)=y1(x,t) + y2 (x,t)
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Reflection – Fixed Reflection – Fixed EndEnd
Reflected wave is inverted
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Reflection – Free Reflection – Free EndEnd
Reflected pulse not inverted