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Oscillations & Waves Class 11 Notes Physics Chapter 13
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Page 1
Oscillation s and Waves
If a particle in periodic motion moves back and forth (or to and
fro) over the same path, then its motion is called oscillatory or
vibratory.
Characteristics of a Harmonic Motion
The basic quantities characterizing a periodic motion are
the amplitude, period and frequency of vibrations.
Amplitude (A)
The amplitude of oscillations is the maximum displacement
of a vibrating body from the position of equilibrium.
Time Period (T)
The time period of oscillations is defined as the time
between two successive identical positions passed by the
body in the same direction.
Frequency (f)
The frequency of oscillations is the number of cycles of
vibrations of a body completed in one second. The
frequency is related to the time period as
Page 2
Oscillation s and Waves
If a particle in periodic motion moves back and forth (or to and
fro) over the same path, then its motion is called oscillatory or
vibratory.
Characteristics of a Harmonic Motion
The basic quantities characterizing a periodic motion are
the amplitude, period and frequency of vibrations.
Amplitude (A)
The amplitude of oscillations is the maximum displacement
of a vibrating body from the position of equilibrium.
Time Period (T)
The time period of oscillations is defined as the time
between two successive identical positions passed by the
body in the same direction.
Frequency (f)
The frequency of oscillations is the number of cycles of
vibrations of a body completed in one second. The
frequency is related to the time period as
f =
T
1
The SI unit of frequency is s
-1
or Hz (hertz)
Simple Harmonic Motion
Let us consider an oscillatory particle along a straight line
whose potential energy function varies as
U(x) =
2
2
1
kx
where k is a constant
Simple Harmonic Motion.
x = A sin ( ?t + ?) is the general equation of SHM.
Above equation is the standard differential equation of
SHM.
The Spring-Mass System
O r
Page 3
Oscillation s and Waves
If a particle in periodic motion moves back and forth (or to and
fro) over the same path, then its motion is called oscillatory or
vibratory.
Characteristics of a Harmonic Motion
The basic quantities characterizing a periodic motion are
the amplitude, period and frequency of vibrations.
Amplitude (A)
The amplitude of oscillations is the maximum displacement
of a vibrating body from the position of equilibrium.
Time Period (T)
The time period of oscillations is defined as the time
between two successive identical positions passed by the
body in the same direction.
Frequency (f)
The frequency of oscillations is the number of cycles of
vibrations of a body completed in one second. The
frequency is related to the time period as
f =
T
1
The SI unit of frequency is s
-1
or Hz (hertz)
Simple Harmonic Motion
Let us consider an oscillatory particle along a straight line
whose potential energy function varies as
U(x) =
2
2
1
kx
where k is a constant
Simple Harmonic Motion.
x = A sin ( ?t + ?) is the general equation of SHM.
Above equation is the standard differential equation of
SHM.
The Spring-Mass System
O r
Time period of a spring-mass is given by
T = 2 ?
k
m
Series and Parallel Combinations of springs
For Series Combinations of springs , the equivalent
stiffness of the combination is given by
12
1 2 1 2
1 1 1 k k
k
kk
? ? ? ?
? k k k
For parallel Combinations of springs, the equivalent stiffness
of the combination is given by
k = k
1
+ k
2
ENERGY CONSERVATION IN SHM
In a spring-mass system, the instantaneous potential energy
and kinetic energy are expressed as
U = ? ? ? ? ? ? t kA kx
2 2 2
sin
2
1
2
1
and K = ? ? ? ? ? ? ? t A m mv
2 2 2 2
cos
2
1
2
1
Since ?
2
=
m
k
, therefore,
Page 4
Oscillation s and Waves
If a particle in periodic motion moves back and forth (or to and
fro) over the same path, then its motion is called oscillatory or
vibratory.
Characteristics of a Harmonic Motion
The basic quantities characterizing a periodic motion are
the amplitude, period and frequency of vibrations.
Amplitude (A)
The amplitude of oscillations is the maximum displacement
of a vibrating body from the position of equilibrium.
Time Period (T)
The time period of oscillations is defined as the time
between two successive identical positions passed by the
body in the same direction.
Frequency (f)
The frequency of oscillations is the number of cycles of
vibrations of a body completed in one second. The
frequency is related to the time period as
f =
T
1
The SI unit of frequency is s
-1
or Hz (hertz)
Simple Harmonic Motion
Let us consider an oscillatory particle along a straight line
whose potential energy function varies as
U(x) =
2
2
1
kx
where k is a constant
Simple Harmonic Motion.
x = A sin ( ?t + ?) is the general equation of SHM.
Above equation is the standard differential equation of
SHM.
The Spring-Mass System
O r
Time period of a spring-mass is given by
T = 2 ?
k
m
Series and Parallel Combinations of springs
For Series Combinations of springs , the equivalent
stiffness of the combination is given by
12
1 2 1 2
1 1 1 k k
k
kk
? ? ? ?
? k k k
For parallel Combinations of springs, the equivalent stiffness
of the combination is given by
k = k
1
+ k
2
ENERGY CONSERVATION IN SHM
In a spring-mass system, the instantaneous potential energy
and kinetic energy are expressed as
U = ? ? ? ? ? ? t kA kx
2 2 2
sin
2
1
2
1
and K = ? ? ? ? ? ? ? t A m mv
2 2 2 2
cos
2
1
2
1
Since ?
2
=
m
k
, therefore,
K = ? ? ? ? ? t kA
2 2
cos
2
1
The total mechanical energy is given by
E = K + U or E = ? ? ? ? ? ? ? ? ? ? ? ? ? t t kA
2 2 2
cos sin
2
1
or E =
2
2
1
kA = constant
Thus, the total energy of
SHM is constant and
proportional to the
square of the amplitude.
The variation of K and
U as function of x is
shown in figure. When
x = ?A, the kinetic
energy is zero and the
total energy is equal to
the maximum potential
energy.
E = U
max
=
2
2
1
kA
Energy
E
U(x)
K(x) x
+A -A
The variation of the kinetic energy , potential
energy, and total energy as a function of
position.
There are extreme points or turning points of the SHM.
At x = 0, U = 0 and the energy is purely kinetic,
i.e. E =K
max
= ? ?
2
2
1
A m ?
Page 5
Oscillation s and Waves
If a particle in periodic motion moves back and forth (or to and
fro) over the same path, then its motion is called oscillatory or
vibratory.
Characteristics of a Harmonic Motion
The basic quantities characterizing a periodic motion are
the amplitude, period and frequency of vibrations.
Amplitude (A)
The amplitude of oscillations is the maximum displacement
of a vibrating body from the position of equilibrium.
Time Period (T)
The time period of oscillations is defined as the time
between two successive identical positions passed by the
body in the same direction.
Frequency (f)
The frequency of oscillations is the number of cycles of
vibrations of a body completed in one second. The
frequency is related to the time period as
f =
T
1
The SI unit of frequency is s
-1
or Hz (hertz)
Simple Harmonic Motion
Let us consider an oscillatory particle along a straight line
whose potential energy function varies as
U(x) =
2
2
1
kx
where k is a constant
Simple Harmonic Motion.
x = A sin ( ?t + ?) is the general equation of SHM.
Above equation is the standard differential equation of
SHM.
The Spring-Mass System
O r
Time period of a spring-mass is given by
T = 2 ?
k
m
Series and Parallel Combinations of springs
For Series Combinations of springs , the equivalent
stiffness of the combination is given by
12
1 2 1 2
1 1 1 k k
k
kk
? ? ? ?
? k k k
For parallel Combinations of springs, the equivalent stiffness
of the combination is given by
k = k
1
+ k
2
ENERGY CONSERVATION IN SHM
In a spring-mass system, the instantaneous potential energy
and kinetic energy are expressed as
U = ? ? ? ? ? ? t kA kx
2 2 2
sin
2
1
2
1
and K = ? ? ? ? ? ? ? t A m mv
2 2 2 2
cos
2
1
2
1
Since ?
2
=
m
k
, therefore,
K = ? ? ? ? ? t kA
2 2
cos
2
1
The total mechanical energy is given by
E = K + U or E = ? ? ? ? ? ? ? ? ? ? ? ? ? t t kA
2 2 2
cos sin
2
1
or E =
2
2
1
kA = constant
Thus, the total energy of
SHM is constant and
proportional to the
square of the amplitude.
The variation of K and
U as function of x is
shown in figure. When
x = ?A, the kinetic
energy is zero and the
total energy is equal to
the maximum potential
energy.
E = U
max
=
2
2
1
kA
Energy
E
U(x)
K(x) x
+A -A
The variation of the kinetic energy , potential
energy, and total energy as a function of
position.
There are extreme points or turning points of the SHM.
At x = 0, U = 0 and the energy is purely kinetic,
i.e. E =K
max
= ? ?
2
2
1
A m ?
WAVE
The wave function
y = A sin [k(x ?vt)]
y = A sin (kx ? t)
The negative sign is used when the wave travels along the
positive x – axis, and vice-versa.
Some Important Points
k =
?
? 2
where is called the angular frequency (measured in
rad/s)and T is the time period and f is the frequency.
Time Period (T)
T =
1
f
Frequency ( f )
The number of complete vibrations of a point on the string
that occur in one second or, the number of wavelengths that
pass a given point in one second.
k is called the wave number, and ? is called the wavelength.
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FAQs on Oscillations & Waves Class 11 Notes Physics Chapter 13
| 1. What are oscillations and waves? |  |
| 2. How do oscillations and waves differ? | |
Ans. Although oscillations and waves share similarities, they differ in their nature and behavior. Oscillations involve the repetitive back-and-forth motion of a system, while waves involve the transfer of energy without the physical movement of particles.
| 3. What are some examples of oscillations in everyday life? | |
Ans. There are numerous examples of oscillations in everyday life, such as the swinging of a pendulum, the vibrations of guitar strings, the back-and-forth motion of a rocking chair, or the oscillation of a tuning fork.
| 4. How are waves classified? | |
Ans. Waves can be classified into two main types: mechanical waves and electromagnetic waves. Mechanical waves require a medium to propagate, such as sound waves or water waves. Electromagnetic waves can propagate through a vacuum, including light waves and radio waves.
| 5. What are the properties of waves? | |
Ans. Waves have several important properties, including amplitude (the maximum displacement of particles or energy), wavelength (the distance between two corresponding points on a wave), frequency (the number of complete cycles of a wave per unit of time), and speed (the rate at which a wave propagates through a medium).
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