Waves& Oscillations.pdf

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Types of Motion: We very often come across the following types of motions
1. Rectilinear motion: Motion of a particle in a straight line

Examples: Motion of ball in straight line, a body that falls freely in vertical direction under the
influence of gravity etc.

Periodic Motion

A motion that repeats itself at regular intervals of time is called periodic motion.

Swinging Pendulum and clock

In both the cases, the motions repeat after certain interval of time. Such a motion that repeats after
certain interval of time is known as periodic motion. The body is displaced from a fixed point and
it is given a small displacement, a force comes into action that tries to bring it to its equilibrium
point, giving rise to oscillation or vibration.

Every oscillatory motion is a periodic, but every periodic motion need not be oscillatory.
Oscillations

Oscillatory motion is a to and fro motion about a mean position and periodic motion repeats
at regular intervals of time.

All oscillatory motions are periodic but all periodic motions are not oscillatory.

Oscillations or Vibrations

There is no significant difference between oscillations and vibrations.

Low frequency periodic motions are called as oscillation (like the oscillation of a branch of
a tree),

High frequency Periodic motions are called as vibration (like the vibration of a string of a
musical instrument).

Periodic Motions which can be represented by Sinusoidal waveform (Sine or Cosine wave) are
known as harmonic motion

Simple Harmonic Motion

Simple Harmonic Motion (SHM) is a specialized form of periodic motion

Periodic vibration around an equilibrium position

Restoring force must be

proportional to displacement from equilibrium

in the direction of equilibrium

There are two types of SHM that will be discussed.

Mass-Spring System

Pendulum

Simple harmonic motion (SHM) is a special kind of periodic motion occurs in mechanical
system where net force acting on an object is proportional to the displacement of the object
from its equilibrium position and the force is always directed towards the equilibrium
position.

In order for mechanical oscillation to occur, a system must posses two
quantities: elasticity and inertia.
 When the system is displaced from its equilibrium position, the elasticity provides
a restoring force such that the system tries to return to equilibrium.

The inertia property causes the system to overshoot equilibrium. This constant play
between the elastic and inertia properties is what allows oscillatory motion to occur.

The natural frequency of the oscillation is related to the elastic and inertia properties

An oscillating system is a mass connected to a rigid
foundation with a spring.

Example: Spring mass system

An oscillating system is a mass connected to a rigid foundation with a spring.

The spring constant k provides the elastic restoring force, and the inertia of the
mass m provides the overshoot.

By applying Newton's second law F=ma to the mass, one can obtain the equation of motion for the
system:

d 2x d 2x k d 2x
F   kx  m   kx   x  0   o2 x  0
dt 2
dt 2
m dt 2

k
o  is the natural frequency
m
The solution of the wave equation
x(t )  xm cos(ot   )

where xm is the amplitude of the oscillation, and φ is the phase
constant of the oscillation.
Displacement

x(t)  Acos(t   )
dx
Velocity : v(t)   ωAsin(ωt   )
dt
d2x
Acceleration : a(t)  2  ω 2 Acos(t   )
dt

Circular Motion

Uniform Circular motion projected in one dimension is SHM

The ball mounted on the turntable moves in uniform
circular motion, and its shadow, projected on a moving
strip of film, executes simple harmonic motion.

Simple Pendulum

A pendulum consists of an object hanging from the end of a string or rigid rod pivoted about the
point. The object is displaced (a small displacement; about 5-10⁰) to one side and allowed to
oscillate. If the object has negligible size and the string or rod is massless, then the pendulum is
called a simple pendulum.
Waves with different amplitudes Waves with different phase

Waves with different time period

The period of the oscillatory motion is defined as the time
required for the system to start one position, complete a
cycle of motion and return to the starting position.

2 m
T  2
o k
v(t )  o xm sin(ot   )
a(t )  o2 xm cos(ot   )

Energy in Simple Harmonic Motion

Kinetic energy (K) of the particle executing SHM

1
K mv 2
2
1
K  mω 2 A 2sin 2 ( ωt  φ)
2
1
K  kA 2sin 2 ( ωt  φ)
2
associated potential energy
1
U  kx 2
2
1
U  kA2 cos 2 ( ωt  φ)
2

Total energy, E, of the system is,

1 2
E U  K  kA
2
Throughout oscillation, KE continually being transformed into PE and vice versa, but TOTAL
ENERGY remains constant

As the system oscillates, the total mechanical energy in the system trades back and forth between
potential and kinetic energies.

1 2 1 2 1 2
PE  kx  kxm cos 2 (o t   ) PE  KE  kxm
2 2 2
1 1 1 1
KE  mv 2  mo2 xm2 cos 2 (o t   )  mo2 xm2  mvm2
2 2
2 2

The total energy in the system, however, remains constant, and depends only on the spring constant
and the maximum displacement (or mass and maximum velocity vm=ωxm)
 Simple Harmonic Motion and Uniform Circular Motion

Displacement of oscillating object = projection on x-axis
of object undergoing circular motion

x(t) = Acos 
For rotational motion with angular frequency ,
displacement at time t:
x(t) = Acos (t + )
= angular displacement at t=0 (phase constant)
A = amplitude of oscillation (= radius of circle)

Velocity and Acceleration in Simple Harmonic Motion

Simple harmonic motion is the projection of uniform circular motion on a diameter of the circle in
which the latter motion takes place.
Restoring force

F   mg sin 
x
F   mg   mg for small angles
L
F  x SHM motion

Damped Harmonic motion: Real oscillatory system

Have you ever thought why a simple pendulum or spring mass system comes to rest when they are
kept in oscillatory motion. Ideally, the oscillatory motion should continue forever.

It is because of the resistance created by air, i.e. air works as damping medium which always
apposes the motion or in other words we can say that the damping force is always in opposite
direction to the restoring force.

In general, it is found that the damping force is proportional to the velocity of the oscillatory body.

Damped Oscillations

For damped oscillations, simplest case is when the
damping force is proportional to the velocity of the
oscillating object

Equation of motion:

d 2x dx
m 2   kx  b
dt dt

Forced or Driven oscillation

The natural frequency is the frequency at which it
will oscillate if there is no driving and damping
forces.
What is a wave?

A disturbance or variation that transfers energy progressively from point to point in a medium and
that may take the form of an elastic deformation or of a variation of pressure, electric potential,
temperature or more.

The Human Wave
The human wave is the disturbance (people jumping up
and sitting back down), and it travels around the stadium.
However, none of the individual people in the stadium
are carried around with the wave as it travels - they all
remain at their seats.

Waves in Everyday Life: Examples

Disturbance produced in pond by throwing a stone creates ripples which move outward.
Sound: Type of wave that moves through matter and then vibrates our eardrums so we can
hear.
Visible Light: Kind of wave that is made up of photons.
Radio and TV Signals etc.

TYPES OF WAVES
(a) Mechanical waves
Requires medium for propagation
Governed by Newton’s laws
Example: Water waves, sound waves, seismic waves, etc.
(b) Electromagnetic waves
Do not require any medium for their propagation
Example: Visible and ultraviolet light, Radio waves, Microwaves, X-rays etc.
(c) Matter waves
 wave associated with the motion of a particle of atomic or subatomic size (electrons,
protons, neutrons, other fundamental particles, and even atoms and molecules)

Waves differ from one another in the manner the particles of medium oscillate (or vibrate) with
reference to the direction of propagation.
Transverse Wave

A wave in which the particles of the medium vibrate at right angles to the direction of propagation
of wave, is called a transverse wave.

Longitudinal waves

A wave in which the particles of the medium vibrate in the same direction in which wave is
propagating, is called a longitudinal wave.

Wave Parameters

The amplitude A, is half the height difference between a peak and a trough.
The wavelength λ, is the distance between successive peaks (or troughs).
The period T, is the time between successive peaks (or troughs).
The wave speed c, is the speed at which peaks (or troughs) move.
The frequency ν, (Greek letter "nu") measures the number of peaks (or troughs) that pass
per second.

A wave is a disturbance that travels from one location to another, and is described by a wave
function that is a function of both space and time. If the wave function was sine function then the
wave would be expressed by

y  A sin(t  kx )

The negative sign is used for a wave traveling in the positive x direction and the positive sign is
used for a wave traveling in the negative x direction.
 2
k

  2

Wave Speed

The speed of a wave depends on the medium through which the wave moves.
The speed, wavelength, and frequency are related.

 
v   λν
k T

 Speed of a Transverse Wave on Stretched String

T
v

Where μ is linear mass density of a string, is the mass m of the string divided by its length l.

 Speed of a Longitudinal Wave Speed of Sound
B
v

where B is bulk modulus and ρ is density of the medium.

 Speed of a longitudinal wave in an ideal gas

Y
v

where Y is the Young’s modulus of the material of the bar.

 Speed of a longitudinal wave in an ideal gas

P
v

where P is the Pressure of the ideal gas. Above eqn. is known as Newton relation.
Laplace correction

For adiabatic processes the ideal gas satisfies the relation,

PV   constant
where γ is the ratio of two specific heats, γ =C p/Cv
P
v

This modification of Newton’s formula is referred to as the Laplace correction.

Waves meet matter
Waves do not travel through the same medium.
Waves can be reflected, refracted or absorbed.
Sound wave traveling though a long corridor is reflected back as echo.
The speed of waves depend on the elastic properties of the medium through which it
travels.
When a wave encounters different medium where the wave speed is different, the wave
will change directions.
Sound wave travelling through different medium undergoes change in speed.
Refraction enables sound to travel faster along the ground at night than during the say.
When waves approach a shore with a gradual depth profile, e.g. a beach, most of the wave
energy is absorbed by the breaking of waves.
When waves approach a hard vertical surface, e.g. a concrete wall or a dock, most of the
energy is converted into waves moving in the opposite direction, a reflection. Of course
the reflected waves are superimposed onto the original waves,

Superposition of Waves

The principle of superposition may be applied to waves whenever two (or more) waves travelling
through the same medium at the same time. The waves pass through each other without being
disturbed. The net displacement of the medium at any point in space or time, is simply the sum of
the individual wave displacements
y (x, t) = y1(x, t) + y2(x, t)

Reflection of Waves
When a wave encounters a boundary, it will reflect back.
The way in which it reflects will vary depending on whether it encounters a fixed or free
boundary.

Fixed Boundary

A fixed boundary is when a wave encounters a fixed surface. This would occur for a rope
attached to a wall.

Free Boundary

A free boundary occurs when, for example, a rope is attached to a post and is free to move up and
down at the end.

Reflection and Refraction

Reflection
Waves bounce back off of a surface that they encounter.
A travelling wave, at a rigid boundary or a
closed end, is reflected with a phase reversal
but the reflection at an open boundary takes
place without any phase change.
Refraction
Waves bend and pass through a surface that they encounter.
Standing Waves and Normal Modes

Standing wave oscillates with time but appears to be fixed in its location
wave pattern that results when two waves of the same frequency, wavelength, and amplitude travel
in opposite directions and interfere

Node
A point in a standing wave that always undergoes
complete destructive interference and therefore is
stationary

Antinode
A point in a standing wave, halfway between two nodes,
at which the largest amplitude occurs

For Nodes
kx=nπ where n= 0,1,2,3,…
distance of λ/2 or half a wavelength separates two consecutive nodes.
For Antinodes
kx=(n+1/2) π where n= 0,1,2,3,…
distance of λ/2 or half a wavelength separates two consecutive antinodes.
For a stretched string of length L, fixed at both ends, the two ends of the string have to
be nodes
λ = 2L/n, for n = 1, 2, 3, … etc
The corresponding frequencies can be represented as
ν = n v/2L, for n = 1, 2, 3, … etc.
For a system closed at one end, with the other end being free the closed end will be node
while open end will be antinode
λ = 2L/(n+1/2), for n = 1, 2, 3, … etc
The corresponding frequencies can be represented as
ν = (n+1/2) v/2L, for n = 1, 2, 3, … etc.

The oscillation mode with that lowest frequency is called the fundamental mode or the first
harmonic The second harmonic is the oscillation mode with n = 2. The third harmonic corresponds
to n = 3 and so on. The collection of all possible modes is called the harmonic series and n is called
the harmonic number.
Beats

The phenomenon of regular rise and fall in the intensity of sound, when two waves of nearly equal
frequencies travelling along the same line and in the same direction superimpose each other is
called beats.

One rise and one fall in the intensity of sound
constitutes one beat and the number of beats per
second is called beat frequency. It is given as:
νb = (ν1 – ν2)
where ν1 and ν2 are the frequencies of the two
interfering waves; ν1 being greater than ν2

Resonance

Resonance occurs in an oscillating system when the driving frequency happens to equal the natural
frequency. For this special case the amplitude of the motion becomes a maximum.

An example is trying to push someone on a swing so that the swing gets higher and higher. If the
frequency of the push equals the natural frequency of the swing, the motion gets bigger and bigger.

Doppler's Effect

The phenomena of apparent change in frequency of source due to a relative motion between the
source and observer is called Doppler's effect.

When the source and observer are moving toward each other, the frequency heard by the
observer is higher than the frequency of the source.
When the source and observer are moving away from each other, the frequency heard by
the observer is lower than the frequency of the source.