Transcript kx 2

Harmonic Motion and Waves
Simple Harmonic Motion(SHM)
• Vibration (oscillation)
• Equilibrium position – position of the natural
length of a spring
• Amplitude – maximum displacement
Period and Frequency
• Period (T) – Time for one complete cycle (back
to starting point)
• Frequency (Hz) – Cycles per second
F=1
T
T=1
f
Period and Frequency
A radio station has a frequency of 103.1 M Hz.
What is the period of the wave?
103.1 M Hz
1X106 Hz = 1.031 X 108 Hz
1M Hz
T = 1/f = 1/(1.031 X 108 Hz) = 9.700 X 10-9 s
Hooke’s Law
F = -kx
F = weight of an object
k = spring constant (N/m)
x = displacement when the object is placed on the
spring
Hooke’s Law: Example 1
What is the spring constant
if a 0.100 kg mass causes
the spring to stretch 6.0
cm?
(ANS: 16 N/m)
Special Note:
If a spring has a mass on it,
and then is stretched
further, equilibrium
position is the starting
length (with the mass on
it)
Hooke’s Law: Example 2
A family of four has a combined mass of 200 kg.
When they step in their 1200 kg car, the shocks
compress 3.0 cm. What is the spring constant of
the shocks?
F = -kx
k = -F/x
k = -(200 kg)(9.8 m/s2)/(-0.03 m)
k = 6.5 X 104 N/m
(note that we did not include the mass of the car)
Hooke’s Law: Example 2a
How far will the car lower if a 300 kg family
borrows the car?
F = -kx
x = -F/k
x = -(300 kg)(9.8 m/s2)/ 6.5 X 104 N/m
x = 4.5 X 10-2 m = 4.5 cm
Forces on a Spring
• Extreme Position (Amplitude)
– Force at maximum
– Velocity = 0
• Equilibrium position
– Force = 0
– Velocity at maximum
Energy and Springs
• KE = ½ mv2
• PE = ½ kx2
• Maximum PE = ½ kA2
Law of conservation of Energy
½ kA2 = ½ mv2+ ½ kx2
All PE
All KE
All PE
Some KE and Some PE
Spring Energy: Example 1
A 0.50 kg mass is connected to a light spring with a
spring constant of 20 N/m. Calculate the total
energy if the amplitude is 3.0 cm.
Maximum PE = ½ kA2
Maximum PE = ½ (20 N/m)(0.030 m2)
Maximum PE = 9 X 10-3 Nm (J)
Spring Energy: Example 1a
What is the maximum speed of the mass?
½ kA2 = ½ mv2+ ½ kx2
½ kA2 = ½ mv2
(x=0 at the origin)
9 X 10-3 J = ½ (0.50 kg)v2
v = 0.19 m/s
Spring Energy: Example 1b
What is the potential energy and kinetic energy at x
= 2.0 cm?
PE = ½ kx2
PE = ½ (20 N/m)(0.020 m2) = 4 X 10-3 J
½ kA2 = ½ mv2 + ½ kx2
½ mv2 = ½ kA2 - ½ kx2
KE = 9 X 10-3 J - 4 X 10-3 J = 5 X 10-3 J
Spring Energy: Example 1c
At what position is the speed 0.10 m/s?
(Ans: + 2.6 cm)
Spring Energy: Example 2a
A spring stretches 0.150 m when a 0.300 kg mass is
suspended from it (diagrams a and b). Find the
spring constant.
(Ans: 19.6 N/m)
Spring Energy: Example 2b
The spring is now stretched an additional 0.100 m
and allowed to oscillate (diagram c). What is the
maximum velocity?
The maximum velocity occurs through the origin:
½ kA2 = ½ mv2+ ½ kx2
½ kA2 = ½ mv2
(x=0 at the origin)
kA2 = mv2
v2 = kA2/m
v = \/kA2/m = \/(19.6 N/m)(0.100m)2/0.300kg
v = 0.808 m/s
Spring Energy: Example 2c
What is the velocity at x = 0.0500 m?
½ kA2 = ½ mv2+ ½ kx2
kA2 = mv2+ kx2
mv2 = kA2 - kx2
v2 = kA2 - kx2
m
v2 = 19.6 N/m(0.100m2 – 0.0500m2) = 0.49 m2/s2
0.300 kg
v = 0.700 m/s
Spring Energy: Example 2d
What is the maximum acceleration?
The force is a maximum at the amplitude
F = ma
and F = kx
ma = kx
a = kx/m = (19.6 N/m)(0.100 m)/(0.300 kg)
a = 6.53 m/s2
Trigonometry and SHM
• Ball rotates on a table
• Looks like a spring from the side
• One rev(diameter) = 2pA
T = 2p m
k
f= 1
T
• Period depends only on mass and spring constant
• Amplitude does not affect period
vo = 2pAf or
vo = 2pA
T
vo is the initial (and maximum) velocity
Period: Example 1
What is the period and frequency of a 1400 kg car
whose shocks have a k of 6.5 X 104 N/m after it
hits a bump?
T = 2p m =
2p (1400 kg/6.5 X 104 N/m)1/2
k
T = 0.92 s
f = 1/T = 1/0.92 s = 1.09 Hz
Period: Example 2a
An insect (m=0.30 g) is caught in a spiderweb that
vibrates at 15 Hz. What is the spring constant of
the web?
T = 1/f = 1/15 Hz = 0.0667 s
T = 2p m
k
T2 = (2p)2m
k
k = (2p)2m = (2p)2(3.0 X 10-4 kg) = 2.7 N/m
T2
(0.0667)2
Period: Example 2b
What would be the frequency for a lighter insect,
0.10 g? Would it be higher or lower?
T = 2p m
k
T = 2p (m/k)1/2
T = 2p (1.0 X 10-4 kg/2.7 N/m)1/2 = 0.038 s
f = 1/T = 1/0.038 s = 26 Hz
Cosines and Sines
• Imagine placing a
pen on a vibrating
mass
• Draws a cosine
wave
x = A cos2pt
T
A = Amplitude
t = time
T = period
f = frequency
or
x = A cos2pft
x = A cos2pft
Velocity is the
derivative of
position
v = -vosin2pft
Acceleration is
the derivative of
velocity
a = -aocos2pft
Cos: Example 1a
A loudspeaker vibrates at 262 Hz (middle C). The
amplitude of the cone of the speaker is 1.5 X 10-4
m. What is the equation to describe the position
of the cone over time?
x = A cos2pft
x = (1.5 X 10-4 m) cos2p(262 s-1)t
x = (1.5 X 10-4 m) cos(1650 s-1)t
Cos: Example 1b
What is the position at t = 1.00 ms (1 X 10-3 s)
x = A cos2pft
x = (1.5 X 10-4 m) cos2p(262 s-1) (1 X 10-3 s)
x = (1.5 X 10-4 m) cos(1.65 rad) = -1.2 X 10-5 m
Cos: Example 1c
What is the maximum velocity and acceleration?
vo = 2pAf
vo = 2p(1.5 X 10-4 m)(262 s-1) = 0.25 m/s
F = ma
kx = ma
a = kx/m
a=kx
m
T = 2p m
k
T2 = (2p)2m
k
k = (2p)2 =
m T2
But we don’t know k or m
Solve for k/m
(2p)2f2
a=kx
m
a = (2pf)2x = (2pf)2A
a = [(2p)(262 Hz)]2(1.5 X 10-4 m) = 410 m/s2
Cos: Example 2a
Find the amplitude, frequency and period of motion
for an object vibrating at the end of a spring that
follows the equation:
x = (0.25 m)cos p t
8.0
x = A cos2pft
x = (0.25 m)cos p t
8.0
Therefore A = 0.25 m
2pft = p t
8.0
2f = 1
8.0
f = 1/16 Hz
T = 1/f = 16 s
Cos: Example 2b
Find the position of the object after 2.0 seconds.
x = (0.25 m)cos p t
8.0
x = (0.25 m)cos p
4.0
x = 0.18 m
The Pendulum
• Pendulums follow SHM only
for small angles (<15o)
• The restoring force is at a
maximum at the top of the
swing.
q
Fr = restoring Force
Remember the circle (360o = 2p rad)
q
L
q=x
L
x
Fr = mgsinq
at small angles sinq = q
Fr = mgq
q
mg
Fr
Fr = mgq
Fr = mgx
L
k = mg
L
T = 2p m
k
T = 2p mL
mg
(Look’s like Hook’s Law F = -kx)
T = 2p L
g
f=1 = 1 g
T 2p L
The Period and Frequency of a pendulum depends
only on its length
Swings and the Pendulum
• To go fast, you need a high frequency
• Short length (tucking and extending your legs)
f= 1 g
2p L
decrease the denominator
Example 1: Pendulum
What would be the period of a grandfather clock
with a 1.0 m long pendulum?
T = 2p L
g
Ans: 2.0 s
Example 2: Pendulum
Estimate the length of the pendulum of a
grandfather clock that ticks once per second (T =
1.0 s).
T = 2p L
g
Ans: 0.25 m
Damped Harmonic Motion
•Most SHM systems slowly stop
•For car shocks, a fluid “dampens” the motion
Resonance: Forced Vibrations
• Can manually move a spring (sitting on a car and
bouncing it)
• Natural or Resonant frequency (fo)
• When the driving frequency f = fo, maximum
amplitude results
– Tacoma Narrows Bridge
– 1989 freeway collapse
– Shattering a glass by singing
Wave Medium
• Mechanical Waves
–
–
–
–
Require a medium
Water waves
Sound waves
Medium moves up and down but wave moves
sideways
• Electromagnetic Waves
– Do not require a medium
– EM waves can travel through the vacuum of space
Parts of a wave
•
•
•
•
•
•
Crest
Trough
Amplitude
Wavelength
Frequency (cycles/s or Hertz (Hz))
Velocity
v = lf
Velocity of Waves in a String
• Depends on:
• Tension (FT) [tighter string, faster wave]
• Mass per unit length (m/L) [heavier string, more
inertia]
v = FT
m/L
Example 1: Strings
A wave of wavelength 0.30 m is travelling down a
300 m long wire whose total mass is 15 kg. If the
wire has a tension of 1000 N, what is the velocity
and frequency?
v=
1000 N
15 kg/300 m
v = lf
= 140 m/s
f = v/l = 140 m/s/0.30 m = 470 Hz
Transverse and Longitudinal Waves
• Transverse Wave – Medium vibrates
perpendicular to the direction of wave
– EM waves
– Water waves
– Guitar String
• Longitudinal Wave – Medium vibrates in the
same direction as the wave
– Sound
Longitudinal Waves: Velocity
• Wave moving along a long solid rod
– Wire
– Train track
vlong=
E
Elastic modulus
r
• Wave moving through a liquid or gas
vlong = B
Bulk modulus
r
Ex. 1: Longitudinal Waves: Velocity
How fast would the sound of a train travel down a
steel track? How long would it take the sound to
travel 1.0 km?
vlong=
E = (2.0 X 1011/7800 kg/m3)1/2
r
vlong = 5100 m/s (much fast than in air)
v = x/t
t = x/v = 1000m/5100m/s = 0.20 s
Earthquakes
• Both Transverse and Longitudinal waves are
produced
• S(Shear) –Transverse
• P(Pressure) – Longitudinal
• In a fluid, only p waves pass
• Center of earth is liquid iron
Energy Transported by Waves
Intensity = Power transported across a unit area
perpendicular to the wave’s direction
I = Power =
Area
P
4pr2
Comparing two distances:
I1r12 = I2r22
Intensity: Example 1
The intensity of an earthquake wave is 1.0 X 106
W/m2 at a distance of 100 km from the source.
What is the intensity 400 km from the source?
I1r12 = I2r22
I2 = I1r12/r22
I2 = (1.0 X 106 W/m2)(100 km)2/(400 km)2
I2 = 6.2 X 104 W/m2
Reflection of a Wave
•Hard boundary inverts the
wave
•Exerts an equal and
opposite force
•Loose rope returns in same
direction
•Continue in same direction if
using another rope boundary
Constructive and Destructive
Interference
Destructive
Constructive
Interference
Interference
Constructive and Destructive
Interference : Phases
Waves “in phase”
“out of phase”
in between
Resonance
Standing Wave – a wave that doesn’t
appear to move
Node – Point of destructive interference
Antinode – Point of constructive
interference (think “Antinode,Amplitude)
“Standing waves are produced only at the
natural (resonant) frequencies.”
Resonance: Harmonics
Fundamental
•Lowest possible frequency
•“first harmonic”
•L = ½ l
First overtone (Second Harmonic)
Second overtone (Third Harmonic)
Resonance: Equations
L = nln
2
f = nv = nf1
2L
v = lf
v=
FT
m/L
n = 1, 2, 3…..
Example 1: Resonance
A piano string is 1.10 m long and has a mass of
9.00 g. How much tension must the string be
under to vibrate at 131 Hz (fund. freq.)?
L = nln
2
l1 = 2L = 2.20 m
1
v = lf = (2.20 m)(131 Hz) = 288 m/s
v = FT
m/L
v2 = FT
m/L
FT = v2m = (288 m/s)2(0.009 kg) = 676 N
L
(1.10 m)
What are the frequencies of the first four harmonics
of this string?
f1 = 131 Hz
f2 = 262 Hz
f3 = 393 Hz
f4 = 524 Hz
1st Harmonic
2nd Harmonic
3rd Harmonic
4th Harmonic
1st Overtone
2nd Overtone
3rd Overtone
Hitting a Boundary
• Both reflection and refraction occur
• Angle of incidence = angle of reflection
q1
q2
q1 = q2
Reflected
wave
air
water
Refracted
wave
Refraction
•Velocity of a wave changes when crossing between substances
•Soldiers slow down marching into mud
sin q1 = v1
sin q2 = v2
Example 1: Refraction
An earthquake p-wave crosses a rock boundary
where its speed changes from 6.5 km/s to 8.0
km/s. If it strikes the boundary at 30o, what is the
angle of refraction?
sin q1 = v1
sin q2 = v2
q2 = 38o
sin 30o = 6.5 km/s
sin q2
8.0 km/s
Example 2: Refraction
A sound wave travels through air at 343 m/s and
strikes water at an angle of 50. If the refracted
angle is 21.4o, what is the speed of sound in
water?
(Ans: 1440 m/s)
Diffraction
Note bending of wave into “shadow region”
Diffraction
• Bending of waves around an object
• Only waves diffract, not particles
• The smaller the obstacle, the more diffraction in
the shadow region