Chapter 13 Vibrations and Waves. Periodic motion Periodic (harmonic) motion – self-repeating...
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Transcript of Chapter 13 Vibrations and Waves. Periodic motion Periodic (harmonic) motion – self-repeating...
Chapter 13
Vibrations and Waves
Periodic motion
• Periodic (harmonic) motion – self-repeating motion
• Oscillation – periodic motion in certain direction
• Period (T) – a time duration of one oscillation
• Frequency (f) – the number of oscillations per unit time, SI unit of frequency 1/s = Hz (Hertz)
Tf
1
Heinrich Hertz(1857-1894)
Motion of the spring-mass system
• Hooke’s law:
• The force always acts toward the equilibrium position: restoring force
• The mass is initially pulled to a distance A and released from rest
• As the object moves toward the equilibrium position, F and a decrease, but v increases
kxF
Motion of the spring-mass system
• At x = 0, F and a are zero, but v is a maximum
• The object’s momentum causes it to overshoot the equilibrium position
• The force and acceleration start to increase in the opposite direction and velocity decreases
• The motion momentarily comes to a stop at x = - A
Motion of the spring-mass system
• It then accelerates back toward the equilibrium position
• The motion continues indefinitely
• The motion of a spring mass system is an example of simple harmonic motion
Simple harmonic motion
• Simple harmonic motion – motion that repeats itself and the displacement is a sinusoidal function of time
)cos()( tAtx
Amplitude
• Amplitude – the magnitude of the maximum displacement (in either direction)
)cos()( tAtx
Phase
)cos()( tAtx
Phase constant
)cos()( tAtx
Angular frequency
)cos()( tAtx
)(coscos TtAtA 0
)2cos(cos )(cos)2cos( Ttt
T 2
T
2
f 2
Period
)cos()( tAtx
2
T
Velocity of simple harmonic motion
)cos()( tAtx
)sin()( tAtv
Acceleration of simple harmonic motion
)cos()( tAtx
)cos()( 2 tAta
)()( 2 txta
The force law for simple harmonic motion
• From the Newton’s Second Law:
• For simple harmonic motion, the force is proportional to the displacement
• Hooke’s law:
maF
kxF
xm 2
m
k
k
mT 22mk
Energy in simple harmonic motion
• Potential energy of a spring:
• Kinetic energy of a mass:
2/)( 2kxtU )(cos)2/( 22 tkA
2/)( 2mvtK )(sin)2/( 222 tAm
)(sin)2/( 22 tkA km 2
Energy in simple harmonic motion
)(sin)2/()(cos)2/( 2222 tkAtkA
)()( tKtU
)(sin)(cos)2/( 222 ttkA
)2/( 2kA )2/( 2kAKUE
Energy in simple harmonic motion
)2/( 2kAKUE
2/2/2/ 222 mvkxkA kmvxA /222
22 xAm
kv 22 xA
Chapter 13Problem 11
A simple harmonic oscillator has a total energy E. (a) Determine the kinetic and potential energies when the displacement is one-half the amplitude. (b) For what value of the displacement does the kinetic energy equal the potential energy?
Pendulums
• Simple pendulum:
• Restoring torque:
• From the Newton’s Second Law:
• For small angles
)sin( gFL
I
sin
I
mgL
)sin( gFL
Pendulums
• Simple pendulum:
• On the other hand
L
at
I
mgL
L
s s
I
mgLa
)()( 2 txta
I
mgL
Pendulums
• Simple pendulum:
I
mgL 2mLI
2mL
mgL
L
g
g
LT
22
Pendulums
• Physical pendulum:
I
mgh
mgh
IT
22
Chapter 13Problem 32
An aluminum clock pendulum having a period of 1.00 s keeps perfect time at 20.0°C. (a) When placed in a room at a temperature of –5.0°C, will it gain time or lose time? (b) How much time will it gain or lose every hour?
Simple harmonic motion and uniform circular motion
• Simple harmonic motion is the projection of uniform circular motion on the diameter of the circle in which the circular motion occurs
Simple harmonic motion and uniform circular motion
• Simple harmonic motion is the projection of uniform circular motion on the diameter of the circle in which the circular motion occurs
)cos()( tAtx
)sin()( tAtvx
Simple harmonic motion and uniform circular motion
• Simple harmonic motion is the projection of uniform circular motion on the diameter of the circle in which the circular motion occurs
)sin()( tAtvx
)cos()( tAtx
Simple harmonic motion and uniform circular motion
• Simple harmonic motion is the projection of uniform circular motion on the diameter of the circle in which the circular motion occurs
)cos()( tAtx
)cos()( 2 tAtax
Damped simple harmonic motion
bvFb Dampingconstant
Dampingforce
Forced oscillations and resonance
• Swinging without outside help – free oscillations
• Swinging with outside help – forced oscillations
• If ωd is a frequency of a driving force, then forced
oscillations can be described by:
• Resonance:
)cos(),/()( tbAtx dd
d
Forced oscillations and resonance
• Tacoma Narrows Bridge disaster (1940)
Wave motion
• A wave is the motion of a disturbance
• All waves carry energy and momentum
Types of waves
• Mechanical – governed by Newton’s laws and exist in a material medium (water, air, rock, ect.)
• Electromagnetic – governed by electricity and magnetism equations, may exist without any medium
• Matter – governed by quantum mechanical equations
Types of waves
Depending on the direction of the displacement relative to the direction of propagation, we can define wave motion as:
• Transverse – if the direction of displacement is perpendicular to the direction of propagation
• Longitudinal – if the direction of displacement is parallel to the direction of propagation
Types of waves
Depending on the direction of the displacement relative to the direction of propagation, we can define wave motion as:
• Transverse – if the direction of displacement is perpendicular to the direction of propagation
• Longitudinal – if the direction of displacement is parallel to the direction of propagation
Superposition of waves
• Superposition principle – overlapping waves algebraically add to produce a resultant (net) wave
• Overlapping solutions of the linear wave equation do not in any way alter the travel of each other
Sinusoidal waves
• One of the most characteristic solutions of the linear wave equation is a sinusoidal wave:
• A – amplitude, φ – phase constant
)2/)(cos(
))(sin()(
vtxkA
vtxkAvtxy
Wavelength
• “Freezing” the solution at t = 0 we obtain a
sinusoidal function of x:
• Wavelength λ – smallest distance (parallel to the direction of wave’s travel) between repetitions of the wave shape
))(cos(),( vtxkAtxy
)cos()0,( kxAxy
Wave number
• On the other hand:
• Angular wave number: k = 2π / λ
)cos()0,( kxAxy ))(cos( xkA
)cos( kkxA
)2cos()cos( kxkx /2k
Angular frequency
• Considering motion of the point at x = 0 we observe a simple harmonic motion (oscillation) :
• For simple harmonic motion:
• Angular frequency ω
))(cos(),( vtxkAtxy
)cos(),0( kvtAty )cos( kvtA
)cos()( tAty
/2 vkv
Frequency, period
• Definitions of frequency and period are the same as for the case of rotational motion or simple harmonic motion:
• Therefore, for the wave velocity
2//1 Tf /2T
fTkv //
)cos(),( tkxAtxy
Wave velocity
• v is a constant and is determined by the properties of the medium
• E.g., for a stretched string with linear density μ = m/l under tension T
T
v
Chapter 13Problem 41
A harmonic wave is traveling along a rope. It is observed that the oscillator that generates the wave completes 40.0 vibrations in 30.0 s. Also, a given maximum travels 425 cm along the rope in 10.0 s. What is the wavelength?
Interference of waves
• Interference – a phenomenon of combining waves, which follows from the superposition principle
• Considering two sinusoidal waves of the same amplitude, wavelength, and direction of propagation
• The resultant wave:
)cos(),(2 tkxAtxy)cos(),(1 tkxAtxy
),(),(),( 21 txytxytxy
)cos()cos( tkxAtkxA
2
cos2
cos2coscos
)2/cos()2/cos(2 tkxA
Interference of waves
• If φ = 0 (Fully constructive)
• If φ = π (Fully destructive)
• If φ = 2π/3 (Intermediate)
)2/cos()2/cos(2),( tkxAtxy
)cos(2),( tkxAtxy
0),( txy
)3/cos(
)3/cos(2),(
tkx
Atxy
)3/cos( tkxA
Reflection of waves at boundaries
• Within media with boundaries, solutions to the wave equation should satisfy boundary conditions. As a results, waves may be reflected from boundaries
• Hard reflection – a fixed zero value of deformation at the boundary – a reflected wave is inverted
• Soft reflection – a free value of deformation at the boundary – a reflected wave is not inverted
Questions?
Answers to the even-numbered problems
Chapter 13
Problem 2
(a) 1.1 × 102 N(b) The graph is a straight line passing
through the origin with slope equal to k = 1.0 × 103 N/m.
Answers to the even-numbered problems
Chapter 13
Problem 8
(a) 575 N/m(b) 46.0 J
Answers to the even-numbered problems
Chapter 13
Problem 12
(a) 2.61 m/s(b) 2.38 m/s
Answers to the even-numbered problems
Chapter 13
Problem 16
(a) 0.15 J(b) 0.78 m/s(c) 18 m/s2