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HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE PDF Download

Exercise

Q.1. A particle executes simple harmonic motion with an amplitude of 10 cm and time period 6 s. At t = 0 it is at position x = 5 cm going towards positive x-direction. Write the equation for the displacement x at time t. Find the magnitude of the acceleration of the particle at t = 4 s.

It is given,
Amplitude of the simple harmonic motion, A =10 cm
At t = 0 and  x = 5 cm,
Time period of the simple harmonic motion, T  = 6 s
Angular frequency (ω) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Consider the equation of motion of S.H.M,
 Y = Asin(ωt + ∅) ...(1)
where Y is displacement of the particle, and ∅ is phase of the particle.
On substituting the values of A, t and ω in equation (1), we get:
5 = 10sin(ω × 0 + ϕ)
⇒ 5 = 10sin ϕ
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
∴ Equation of displacement can be written as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(ii) At t = 4 s,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Acceleration is given by,
a = −ω2x
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.2. The position, velocity and acceleration of a particle executing simple harmonic motion are found to have magnitude 2 cm, 1 m s−1 and 10 m s−2 at a certain instant. Find the amplitude and the time period of the motion.

It is given that:
Position of the particle, x = 2 cm = 0.02 m
Velocity of the particle, v = 1 ms−1.
Acceleration of the particle, a = 10 ms−2.
Let
ω be the angular frequency of the particle.
The acceleration of the particle is given by,
 a = ω2x
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time period of the motion is given as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Now, the amplitude A is calculated as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.3. A particle executes simple harmonic motion with an amplitude of 10 cm. At what distance from the mean position are the kinetic and potential energies equal?

It is given that:
Amplitude of the particle executing simple harmonic motion, A = 10 cm
To determine the distance from the mean position, where the kinetic energy of the particle is equal to its potential energy:
Let y be displacement of the particle,
ω be the angular speed of the particle, and
A be the amplitude of the simple harmonic motion.
Equating the mathematical expressions for K.E. and P.E. of the particle, we get :
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
The kinetic energy and potential energy of the particle are equal at a distance of 5√2 cm from the mean position.


Q.4. The maximum speed and acceleration of a particle executing simple harmonic motion are 10 cm/s and 50 cm/s2. Find the position(s) of the particle when the speed is 8 cm/s.

It is given that:
Maximum speed of the particle, HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Maximum acceleration of the particle,
amax = 50 cms−2
The maximum velocity of a particle executing simple harmonic motion is given by,
vMax = Aω
where  omega is angular frequency, and  omega is angular frequency, and A is amplitude of the particle.
Substituting the value of vMax in the above expression,
we get :
Aω = 10 ...(1)
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
aMax = ω2A = 50 cms−1
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
From the equations (1) and (2), we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
To determine the positions where the speed of the particle is 8 ms-1, we may use the following formula:
v2 = ω2 (A2 − y2)
where y is distance of particle from the mean position, and v is velocity of the particle.
On substituting the given values in the above equation, we get:
64 = 25 (4 − y2)
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
⇒ 4 − y2 = 2.56
⇒ y2 = 1.44
⇒  y  = √1.44
⇒y = ± 1.2 cm   (from the mean position)


Q.5. A particle having mass 10 g oscillates according to the equation x = (2.0 cm) sin [(100 s−1)t + π/6]. Find (a) the amplitude, the time period and the spring constant. (c) the position, the velocity and the acceleration at t = 0.

Given:
Equation of motion of the particle executing S.H.M ,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
 Mass of the particle, m = 10g ...(1)
General equation of the particle is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On comparing the equations (1) and (2) we get:
(a) Amplitude, A is 2 cm.
Angular frequency, ω is 100 s−1.
Time period is calculated as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Also, we know -
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where k is the spring constant.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) At t = 0 and x = 2 cm
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE from the mean position,
We know:
x = A sin (ωt + ϕ)
Using
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(c) Acceleration of the particle is given by,
a = -ω2x
= 1002×1 = 10000 cm/s2


Q.6. The equation of motion of a particle started at t = 0 is given by x = 5 sin (20t + π/3), where x is in centimetre and t in second. When does the particle
(a) first come to rest
(b) first have zero acceleration
(c) first have maximum speed?

Given:
The equation of motion of a particle executing S.H.M. is,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
The general equation of S..H.M. is give by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(a) Maximum displacement from the mean position is equal to the amplitude of the particle.
As the velocity of the particle is zero at extreme position, it is at rest.
∴ Displacement   x = 5, which is also the amplitude of the particle.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Now,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
The particle will come to rest at HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b)  Acceleration is given as,
a = ω2x
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 
(c) The maximum speed (v) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
For maximum velocity:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE  


Q.7. Consider a particle moving in simple harmonic motion according to the equation x = 2.0 cos (50 πt + tan−1 0.75) where x is in centimetre and t in second. The motion is started at t = 0. (a) When does the particle come to rest for the first time? (b) When does he acceleration have its maximum magnitude for the first time? (c) When does the particle come to rest for the second time?

It is given that a particle executes S.H.M.
Equation of S.H.M. of the particle:
x = 2.0 cos (50 π t + tan−10.75)
= 2.0 cos (50 π t + 0.643)
(a) Velocity of the particle is given by,
v = dx/dt v = −100 πsin (50 πt + 0.643)
As the particle comes to rest, its velocity becomes be zero.
⇒ v = −100 πsin (50 πt + 0.643) = 0
⇒ sin (50πt + 0.643) =0 = sinπ
When the particle initially comes to rest,
50πt + 0.643 =π
⇒  t = 1.6 × 10−2 s
(b) Acceleration is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
For maximum acceleration:
cos (50πt + 0.643) = −1 = cosπ(max) (so that a is max)
⇒ t = 1.6 ×  10−2 s
(c) When the particle comes to rest for the second time, the time is given as,
50πt + 0.643 = 2π
⇒ t = 3.6 × 10−2 s


Q.8. Consider a simple harmonic motion of time period T. Calculate the time taken for the displacement to change value from half the amplitude to the amplitude.

As per the conditions given in the question,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(for the given two positions)
Let y1 and y2 be the displacements at the two positions and A be the amplitude.
Equation of motion for the displacement at the first position is given by, y1 = Asinωt1
As displacement is equal to the half of the amplitude,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
The displacement at second position is given by,
y2 = A sin ωt2
As displacement is equal to the amplitude at this position,
⇒ A = A sin ωt2
⇒ sinωt2 = 1
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.9. The pendulum of a clock is replaced by a spring-mass system with the spring having spring constant 0.1 N/m. What mass should be attached to the spring?

Given:
Spring constant, k =0.1 N/m
Time period of the pendulum of clock, T = 2 s
Mass attached to the string, m, is to be found.
The relation between time period and spring constant is given as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On substituting the respective values, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.10. A block suspended from a vertical spring is in equilibrium. Show that the extension of the spring equals the length of an equivalent simple pendulum, i.e., a pendulum having frequency same as that of the block.

An equivalent simple pendulum has same time period as that of the spring mass system.
The time period of a simple pendulum is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where l is the length of the pendulum, and g is acceleration due to gravity.
Time period of the spring is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where m is the mass, and k is the spring constant.
Let x be the extension of the spring.
For small frequency, TP can be taken as equal to TS.    
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.11. A block of mass 0.5 kg hanging from a vertical spring executes simple harmonic motion of amplitude 0.1 m and time period 0.314 s. Find the maximum force exerted by the spring on the block.

It is given that:
Amplitude of simple harmonic motion, x = 0.1 m
Time period of simple harmonic motion, T  = 0.314 s
Mass of the block, m = 0.5 kg
Weight of the block, W = mg = 0.5 x 10 = 5 kg HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Total force exerted on the block = Weight of the block + spring force
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Periodic time of spring is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
∴ The force exerted by the spring on the block (F) is,
F = kx = 200.0 × 0.1 = 20 N
Maximum force = F + weight of the block
= 20 + 5 = 25 N


Q.12. A body of mass 2 kg suspended through a vertical spring executes simple harmonic motion of period 4 s. If the oscillations are stopped and the body hangs in equilibrium find the potential energy stored in the spring.

It is given that:
Mass of the body, m = 2 kg
Time period of the spring mass system, T = 4 s
The time period for spring-mass system is given as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where k is the spring constant.
On substituting the respective values, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As the restoring force is balanced by the weight, we can write:
F = mg = kx
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
∴ Potential Energy (U) of the spring is,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.13. A spring stores 5 J of energy when stretched by 25 cm. It is kept vertical with the lower end fixed. A block fastened to its other end is made to undergo small oscillations. If the block makes 5 oscillations each second what is the mass of the block?

It is given that:
Energy stored in the spring, E = 5 J
Frequency of the mass-spring system, f = 5
Extension in the length of the spring, x = 25 cm = 0.25 m
Time  period, T = (1/5)s
Potential  energy (U) is  given  by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time period  of  spring  mass  system  is  given  by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE where  m  is  the  mass  of the body hanged, and k is  the spring constant .
On  substituting  the  respective  values  in the above expression, we  get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.14. A small block of mass m is kept on a bigger block of mass M which is attached to a vertical spring of spring constant k as shown in the figure. The system oscillates vertically. (a) Find the resultant force on the smaller block when it is displaced through a distance x above its equilibrium position. (b) Find the normal force on the smaller block at this position. When is this force smallest in magnitude? (c) What can be the maximum amplitude with which the two blocks may oscillate together?
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(a) Consider the free body diagram.
Weight of the body, W = mg
Force, F = ma = mω2x
x is the small displacement of mass m.
As normal reaction R is acting vertically in the upward direction, we can write:
R + mω2x − mg = 0  ....(1)
Resultant force = mω2x = mg − R
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) R = mg − mω2x
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
It can be seen from the above equations that, for R to be smallest, the value of mω2xshould be maximum which is only possible when the particle is at the highest point.
(c) R = mg − mω2x
As the two blocks oscillate together R becomes greater than zero.
When limiting condition follows,
i.e. R = 0
mg = mω2x
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Required maximum amplitude
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.15. The block of mass m1 shown in figure is fastened to the spring and the block of mass m2 is placed against it. (a) Find the compression of the spring in the equilibrium position. (b) The blocks are pushed a further distance (2/k) (m1 + m2)g sin θ against the spring and released. Find the position where the two blocks separate. (c) What is the common speed of blocks at the time of separation?
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

(a) As it can be seen from the figure,
Restoring force = kx
Component of total weight of the two bodies acting vertically downwards = (m1 + m2) g sin θ
At equilibrium,  
kx = (m1 + m2) g sin θ
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) It is given that:
Distance at which the spring is pushed,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As the system is released, it executes S.H.M.
where HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
When the blocks lose contact, P becomes zero. (P is the force exerted by mass m1 on mass m2)
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Therefore, the blocks lose contact with each other when the spring attains its natural length.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(c) Let v be the common speed attained by both the blocks.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 


Q.16. In following figure k = 100 N/m M = 1 kg and F = 10 N. (a) Find the compression of the spring in the equilibrium position. (b) A sharp blow by some external agent imparts a speed of 2 m/s to the block towards left. Find the sum of the potential energy of the spring and the kinetic energy of the block at this instant. (c) Find the time period of the resulting simple harmonic motion. (d) Find the amplitude. (e) Write the potential energy of the spring when the block is at the left extreme. (f) Write the potential energy of the spring when the block is at the right extreme.
The answer of (b), (e) and (f) are different. Explain why this does not violate the principle of conservation of energy.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

It is given that :
Spring constant, k = 100 N/m,
Mass of the block, M = 1 kg
Force, F = 10 N
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(a) In the equilibrium position,
F = kx
where x is the compression of the spring, and k is the spring constant.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) The blow imparts a speed of 2 ms-1 to the block, towards left.
Potential energy of spring, U = 1/2 kx2
Kinetic energy,
K = 1/2 Mv2
(c) Time period (T)  is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(d) Let A be the amplitude.
Amplitude is the distance between the mean and the extreme position.
At the extreme position, compression of the spring will be (A + x).
As the total energy in S.H.M.  remains constant, we can write:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
∴ 50(A + 0.1)2 = 2.5 + 10x
⇒ 50A2 + 0.5 + 10A = 2.5 + 10A
⇒ 50A2 = 2
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(e) Potential Energy at the left extreme will be,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(f) Potential Energy at the right extreme is calculated as:
Distance between the two extremes = 2A
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As the work is done by the external force of 10 N, different values of options (b), (e) and (f) do not violate the law of conservation of energy.


Q.17. Find the time period of the oscillation of mass m in figures  a, b, c. What is the equivalent spring constant of the pair of springs in each case?]
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

(a) Spring constant of a parallel combination of springs is given as,
K = k1 + k2  (parallel)
Using the relation of time period for S.H.M. for the given spring-mass system, we have :
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) Let x be the displacement of the block of mass m, towards left.
Resultant force is calculated as,
F = F1 + F2 = (k1 + k2)x
Acceleration (a) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time period (T) is given by ,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On  substituting  the  values  of  displacement  and  acceleration,   we  get: HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Required spring constant, K = k1 + k2
(c) Let K be the equivalent spring constant of the series combination.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time  period  is  given  by
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On  substituting  the respective values, we  get: HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.18. The spring shown in figure is unstretched when a man starts pulling on the cord. The mass of the block is M. If the man exerts a constant force F, find (a) the amplitude and the time period of the motion of the block, (b) the energy stored in the spring when the block passes through the equilibrium position and (c) the kinetic energy of the block at this position.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(a) We know-
f = kx
⇒ x = F/k
Acceleration = F/m
Using the relation of time period of S.H.M.,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Amplitude = Maximum displacement = F/k
When the block passes through the equilibrium position, the energy contained by the spring is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) At the mean position, potential energy is zero.
Kinetic energy is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.19. A particle of mass m is attatched to three springs A, B and C of equal force constants kas shown in figure . If the particle is pushed slightly against the spring C and released, find the time period of oscillation.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

(a) Let us push the particle lightly against the spring C through displacement x.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As a result of this movement, the resultant force on the particle is kx.
The force on the particle due to springs A and B is HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Total Resultant force HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
= kx + kx = 2kx
Acceleration is given by = HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time  period  HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.20. Repeat the previous exercise if the angle between each pair of springs is 120° initially.

As the particle is pushed against the spring C by the distance x, it experiences a force of magnitude kx.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
If the angle between each pair of the springs is 120˚ then the net force applied by the springs A and B is given as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Total resultant force (F) acting on mass m will be,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
∴ Time  period, HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.21. The springs shown in the figure are all unstretched in the beginning when a man starts pulling the block. The man exerts a constant force F on the block. Find the amplitude and the frequency of the motion of the block.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As the block of mass M is pulled, a net resultant force is exerted by the three springs opposing the motion of the block.
Now, springs k2 and k3 are in connected as a series combination.
Let kbe the equivalent spring constant.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
kand k1 form a parallel combination of springs. Hence, equivalent spring constant k = k1 + k4.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) Frequency (v) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(c) Amplitude (x) is given by
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.22. Find the elastic potential energy stored in each spring shown in figure when the block is in equilibrium. Also find the time period of vertical oscillation of the block.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
All three spring attached to the mass M are in series.
k1, k2, k3 are the spring constants.
Let k be the resultant spring constant.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time  period (T) is  given  by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As force is equal to the weight of the body,
 F = weight = Mg
Let x1, x2, and xbe the displacements of the springs having spring constants k1, k2 and krespectively.
For spring k1,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 


Q.23. The string the spring and the pulley shown in figure are light. Find the time period of the mass m.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

Let l be the extension in the spring when mass m is hung.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let T1 be the tension in the string; its value is given by,
T1 = kl = mg
Let x be the extension in the string on applying a force F.
Then, the new value of tension T2 is given by,
T2 = k(x + l)
Driving force is the difference between tensions T1 and T2.
∴ Driving force = T2 − T1 = k(x + l) − kl
= kx
Acceleration, a =kx/m
Time  period (T) is  given  by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.24. Solve the previous problem if the pulley has a moment of inertia I about its axis and the string does not slip over it.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

Let us try to solve the problem using energy method.
If δ is the displacement from the mean position then, the initial extension of the spring from the mean position is given by, δ = mg/k
Let x be any position below the equilibrium during oscillation.
Let v be the velocity of mass m and ω be the angular velocity of the pulley.
If r is the radius of the pulley then
v = rω
As total energy remains constant for simple harmonic motion, we can write:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
By taking derivatives with respect to t, on both sides, we have:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.25. Consider the situation shown in figure . Show that if the blocks are displaced slightly in opposite direction and released, they will execute simple harmonic motion. Calculate the time period.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
The centre of mass of the system should not change during simple harmonic motion.
Therefore, if the block m on the left hand side moves towards right by distance x, the block on the right hand side should also move towards left by distance x. The total compression of the spring is 2x.
If v is the velocity of the block. Then
Using energy method, we can write:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
By taking the derivative of both sides with respect to t, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.26. A rectangle plate of sides a and b is suspended from a ceiling by two parallel string of length L each in Figure . The separation between the string is d. The plate is displaced slightly in its plane keeping the strings tight. Show that it will execute simple harmonic motion. Find the time period.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

Let m is the mass of rectangular plate and x is the displacement of the rectangular plate.

During the oscillation, the centre of mass does not change.
Driving force (F) is given as,
F = mgsin θ
Comparing the above equation with F = ma, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
For small values of θ, sinθ can be taken as equal to θ.
Thus, the above equation reduces to:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE  [Where  g  and  L  are  constant.]
It can be seen from the above equation that, a α x.
Hence, the motion is simple harmonic.
Time period of simple harmonic motion (T) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.27. A 1 kg block is executing simple harmonic motion of amplitude 0.1 m on a smooth horizontal surface under the restoring force of a spring of spring constant 100 N/m. A block of mass 3 kg is gently placed on it at the instant it passes through the mean position. Assuming that the two blocks move together, find the frequency and the amplitude of the motion.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
It is given that:
Amplitude of simple harmonic motion, x  = 0.1 m
Total mass of the system, M = 3 + 1 = 4 kg (when both the blocks move together)
Spring constant, k = 100 N/m
Time period of SHM (T) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
\[\text { On  substituting  the  values  of  M  and  k  in  the  bove  equation,   we  have:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Frequency  of  the  motion  is  given  by, HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let v be the velocity of the 1 kg block, at mean position.
As  kinetic  energy  is  equal  to  the  potential  energy,   we  can  write:  HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where x = amplitude = 0.1 m
Substituting  the  value  of  x  in  above  equation  and  solving  for  v,   we  get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
When the 3 kg block is gently placed on the 1 kg block, the 4 kg mass and the spring become one system. As a spring-mass system experiences external force, momentum should be conserved.
Let V be the velocity of 4 kg block.
Now,
Initial momentum = Final momentum
∴ 1 × v = 4 × V
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Thus, at the mean position, two blocks have a velocity of HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Mean  value  of  kinetic  energy  is  given  as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
At the extreme position, the spring-mass system has only potential energy.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where δ is the new amplitude.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.28. The left block in figure moves at a speed v towards the right block placed in equilibrium. All collisions to take place are elastic and the surfaces are frictionless. Show that the motions of the two blocks are periodic. Find the time period of these periodic motions. Neglect the widths of the blocks.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
According to the question, the collision is elastic and the surface is frictionless, therefore, when the left block A moves with speed v and collides with the right block B, it transfers all the energy to the right block B.
The left block A moves a distance x against the spring; the right block returns to the original position and completes half of the oscillation.
Therefore, the period of right block B will be, HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Right block B collides with left block A and comes to rest.
Let L be the distance moved by the block to return to its original position.
The time taken is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Hence, time period of the periodic motion is,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 


Q.29. Find the time period of the motion of the particle shown in figure. Neglect the small effect of the bend near the bottom.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let t1 and t2  be the time taken by the particle to travel distances AB and BC respectively.
Acceleration for part AB, a1 = g sin 45°
The distance travelled along AB is s1.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let v be the velocity at point B, and u be the initial velocity.
Using the third equation of motion, we have:
v2 − u2 = 2a1s1
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
For the distance BC,
Acceleration, a2 = −gsin 60°
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
v = 0
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Thus, the total time period, t = 2(t1 + t2) = 2 (0.2 + 0.163) = 0.73 s


Q.30. All the surfaces shown in figure are frictionless. The mass of the care is M, that of the block is m and the spring has spring constant k. Initially the car and the block are at rest and the spring is stretched through a length x0 when the system is released. (a) Find the amplitudes of the simple harmonic motion of the block and of the care as seen from the road. (b) Find the time period(s) of the two simple harmonic motions.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

Let x1 and x2 be the amplitudes of oscillation of masses m and M respectively.
(a) As the centre of mass should not change during the motion, we can write:
mx1 = Mx2 ...(1)
Let k be the spring constant. By conservation of energy, we have:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where x0 is the length to which spring is stretched.
From equation (2) we have,
x0 = x1 + x2
On substituting the value of xfrom equation (1) in equation (2), we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On substituting the value of x1 from above equation, we get:    
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Thus, the amplitude of the simple harmonic motion of a car, as seen from the road is
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) At any position,
Let vand v2 be the velocities.
Using law of conservation of energy we have,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Here, (v1 − v2) is the absolute velocity of mass m as seen from the road.
Now, from the principle of conservation of momentum, we have:
Mx2 = mx1
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Putting the above values in equation (3), we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Taking derivative of both the sides, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 


Q.31. A uniform plate of mass M stays horizontally and symmetrically on two wheels rotating in opposite direction in Figure . The separation between the wheels is L. The friction coefficient between each wheel and the plate is μ. Find the time period of oscillation of the plate if it is slightly displaced along its length and released.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

Let x be the displacement of the uniform plate towards left.
Therefore, the centre of gravity will also be displaced through displacement x.
At the displaced position,
R1 + R2 = mg
Taking moment about g, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Similarly,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time  period (T) is  given  by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.32. A pendulum having time period equal to two seconds is called a seconds pendulum. Those used in pendulum clocks are of this type. Find the length of a second pendulum at a place where g = π2 m/s2.

It is given that:
Time period of the second pendulum, T = 2 s
Acceleration due to gravity of a given place, g = π2ms-2
The relation between time period and acceleration due to gravity is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where l is the length of the second pendulum.
Substituting the values of T and g, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Hence, the length of the pendulum is 1 m.


Q.33. The angle made by the string of a simple pendulum with the vertical depends on time as HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE.  Find the length of the pendulum if g = π2 m2.

It  is  given  that:
Angle  made  by  the  simple  pendulum  with  the  vertical, HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE On  comparing  the  above  equation  with  the  equation  of  S . H . M . , we  get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time  period  is  given  by  the  relation,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Hence, length  of  the  pendulum  is  1  m.


Q.34. The pendulum of a certain clock has time period 2.04 s. How fast or slow does the clock run during 24 hours?

Given,
Time period of the clock pendulum = 2.04 s
The number of oscillations made by the pendulum in one day is calculated as
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
In each oscillation, the clock gets slower by (2.04 − 2.00) s, i.e., 0.04 s.
In one day, it is slowed by = 43200 × (0.04)
= 28.8 min
Thus, the clock runs 28.8 minutes slow during 24 hours.


Q.35. A pendulum clock giving correct time at a place where g = 9.800 m/s2 is taken to another place where it loses 24 seconds during 24 hours. Find the value of g at this new place.

Let Tbe the time period of pendulum clock at a place where acceleration due to gravity (g1) is 9.8 ms−2.
Let T1 = 2 s
g1 =9.8ms-2
Let T2 be the time period at the place where the pendulum clock loses 24 seconds during 24 hours.
Acceleration due to gravity at this place is (g2)
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
= 9.795m/s2


Q.36. A simple pendulum is constructed by hanging a heavy ball by a 5.0 m long string. It undergoes small oscillations. (a) How many oscillations does it make per second? (b) What will be the frequency if the system is taken on the moon where acceleration due to gravitation of the moon is 1.67 m/s2?

It is given that:
Length of the pendulum, l = 5 m
Acceleration due to gravity, g = 9.8 ms-2
Acceleration due to gravity at the moon, g' = 1.67 ms-2
(a) Time period (T)  is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
i.e. the body will take  2 π(0.7) seconds to complete an oscillation.
Now, frequency (f) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) Let g' be the value of acceleration due to gravity at moon. Time period of simple pendulum at moon (T′), is given as:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On substituting the respective values in the above formula, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Therefore, frequency (f′) will be,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.37. A small block oscillates back and forth on a smooth concave surface of radius R ib Figure . Find the time period of small oscillation.

The maximum tension in the string of an oscillating pendulum is double of the minimum tension. Find the angular amplitude.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let the speed of bob of the pendulum at an angle θ be v.
Using the principle of conservation of energy between the mean and extreme positions, we get:
(1/2)mv2 − 0 = mgl(1 − cos θ)
v2 = 2gl(1 − cos θ) ...(1)
In a moving pendulum, the tension is maximum at the mean position, whereas it is minimum at the extreme position.
Maximum tension at the mean position is given by
Tmax = mg + 2mg(1 − cos θ)
Minimum tension at the extreme position is given by
Tmin = m g cosθ
According to the question,
Tmax = 2Tmin
⇒ mg + 2mg − 2m g cosθ = 2m g cosθ
⇒ 3mg = 4 mg cosθ
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.38. A small block oscillates back and forth on a smooth concave surface of radius R in Figure. Find the time period of small oscillation.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
It is given that R is the radius of the concave surface.
Let N be the normal reaction force.
Driving force, F = mg sin θ
Comparing the expression for driving force with the expression, F = ma, we get:
Acceleration, a = g sin θ
Since the value of θ is very small,
∴ sin θ → θ
∴ Acceleration, a = gθ
Let x be the displacement of the body from mean position.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As acceleration is directly proportional to the displacement. Hence, the body will execute S.H.M.
Time period (T) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.39. A spherical ball of mass m and radius r rolls without slipping on a rough concave surface of large radius R. It makes small oscillations about the lowest point. Find the time period.

Let ω be the angular velocity of the system about the point of suspension at any time.
Velocity of the ball rolling on a rough concave surface (vC)  is given by,
 vc = (R − r)ω
Also, vc = rω1
where ω1 is the rotational velocity of the sphere.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As total energy of a particle in S.H.M. remains constant,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Taking derivative on both sides, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Therefore, the motion is S.H.M.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time  period  is  given  by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.40. A simple pendulum of length 40 cm is taken inside a deep mine. Assume for the time being that the mine is 1600 km deep. Calculate the time period of the pendulum there. Radius of the earth = 6400 km.

It is given that:
Length of the pendulum, l = 40 cm = 0.4 m
Radius of the earth, R = 6400 km
Acceleration due to gravity on the earth's surface, g = 9.8 ms-2
Let
g' be the acceleration due to gravity at a depth of 1600 km from the surface of the earth.
Its value is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE  where  d  is  the  depth  from  the  earth  surface, R  is  the  radius  of  earth,  and  g  is  acceleration  due  to  gravity .
On  substituting  the  respective  values,   we  get: HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time period is given as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 


Q.41. Assume that a tunnel is dug across the earth (radius = R) passing through its centre. Find the time a particle takes to cover the length of the tunnel if (a) it is projected into the tunnel with a speed of HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE (b) it is released from a height R above the tunnel (c) it is thrown vertically upward along the length of tunnel with a speed of HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Given:
Radius of the earth is R.
Let M be the total mass of the earth and ρ be the density.
Let mass of the part of earth having radius x be M.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Force on the particle is calculated as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Now, acceleration (ax) of mass M' at that position is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
So, Time  period  of  oscillation, T = HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(a) Velocity-displacement equation in S.H.M is written as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where, A  is  the  amplitude; and y  is  the  displacement .
When the particle is at y = R,
The velocity of the particle is HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On substituting these values in the velocity-displacement equation, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let t1 and t2 be the time taken by the particle to reach the positions X and Y.
Now, phase of the particle at point X will be greater than π/2 but less than π
Also, the phase of the particle on reaching Y will be greater than π but less than 3π/2
Displacement-time relation is given by,
y = A sin ωt
Substituting y = R and A = HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE in the above relation , we get :
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time taken by the particle to travel from X to Y:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) When the body is dropped from a height R
Using the principle of conservation of energy, we get:
Change in P.E. = Gain in K.E.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As the velocity is same as that at X, the body will take the same time to travel XY.
(c) The body is projected vertically upwards from the point X with a velocity HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE Its velocity becomes zero as it reaches the highest point.
The velocity of the body as it reaches X again will be,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Hence, the body will take same time i.e.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE to travel XY.


Q.42. Assume that a tunnel is dug along a chord of the earth, at a perpendicular distance R/2 from the earth's centre where R is the radius of the earth. The wall of the tunnel is frictionless. (a) Find the gravitational force exerted by the earth on a particle of mass mplaced in the tunnel at a distance x from the centre of the tunnel. (b) Find the component of this force along the tunnel and perpendicular to the tunnel. (c) Find the normal force exerted by the wall on the particle. (d) Find the resultant force on the particle. (e) Show that the motion of the particle in the tunnel is simple harmonic and find the time period.

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
If ρ  is the density of the earth, then mass of the earth (M) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Similarly, mass (M') of  the  part  of  earth  having  radius (x) is  given  by, HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(a) Let F be the gravitational force exerted by the earth on the particle of mass m. Then, its value is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Substituting the value of M' in the above equation, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
 (c)
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
∵ Normal force exerted by the wall N = Fx
(d)The resultant force is HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(e) Acceleration = Driving force/mass
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.43. A simple pendulum of length l is suspended through the ceiling of an elevator. Find the time period of small oscillations if the elevator (a) is going up with and acceleration a0(b) is going down with an acceleration a0 and (c) is moving with a uniform velocity.

The length of the simple pendulum is l.
Let x be the displacement of the simple pendulum.
(a)
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

From the diagram, the driving forces f is given by,
f = m(g + a0)sinθ ...(1)
Acceleration (a) of the elevator is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
[ when θ is very small, sin θ → θ = x/l]
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As the acceleration is directly proportional to displacement, the pendulum executes S.H.M.
Comparing equation (2) with the expression a = ω2x, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Thus, time period of small oscillations when elevator is going upward(T) will be:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
When the elevator moves downwards with acceleration a0,
Driving force (F) is given by,
 F = m(g − a0)sinθ
On comparing the above equation with the expression, F = ma, Acceleration, HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time  period  of  elevator  when  it  is  moving  downward (T') is  given  by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(c) When the elevator moves with uniform velocity, i.e. a0 = 0,
For a simple pendulum, the driving force (F) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Comparing  the  above  equation  with  the  expression, F = ma, we  get: HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.44. A simple pendulum of length 1 feet suspended from the ceiling of an elevator takes π/3 seconds to complete one oscillation. Find the acceleration of the elevator.

It is given that:
Length of the simple pendulum, l = 1  feet
Time period of simple pendulum, T = (π/3)s Acceleration due to gravity, g = 32 ft/s2
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let a be the acceleration of the elevator while moving upwards.
Driving force (f) is given by,
f = m(g + a)sinθ
Comparing the above equation with the expression, f = ma, we get:
Acceleration, a  =  (g + a)sinθ = (g +a)θ (For small angle θ, sin θ → θ)
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On substituting the respective values in the above formula, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.45. A simple pendulum fixed in a car has a time period of 4 seconds when the car is moving uniformly on a horizontal road. When the accelerator is pressed, the time period changes to 3.99 seconds. Making an approximate analysis, find the acceleration of the car.

It is given that:
When the car is moving uniformly, time period of simple pendulum, T = 4.0 s
As the accelerator is pressed, new time period of the pendulum, T' = 3.99 s
Time period of simple pendulum, when the car is moving uniformly on a horizontal road is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let the acceleration of the car be a.
The time period of pendulum, when the car is accelerated, is given by:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Taking  the  ratio  of  T  to  T',   we  get: HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On solving the above equation for a, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.46. A simple pendulum of length l is suspended from the ceiling of a car moving with a speed v on a circular horizontal road of radius r. (a) Find the tension in the string when it is at rest with respect to the car. (b) Find the time period of small oscillation.

It is given that a car is moving with speed v on a circular horizontal road of radius r.
(a) Let T be the tension in the string.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
According to the free body diagram, the value of T is given as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where acceleration, HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
The time period (T) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 
On substituting  the respective values, we  have:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.47. The ear-ring of a lady shown in figure has a 3 cm long light suspension wire. (a) Find the time period of small oscillations if the lady is standing on the ground. (b) The lady now sits in a merry-go-round moving at 4 m/s1 in a circle of radius 2 m. Find the time period of small oscillations of the ear-ring.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

Given,
Length of the long, light suspension wire, l = 3 cm = 0.03 m
Acceleration due to gravity, g = 9.8 ms-2
(a)Time Period (T) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) Velocity of merry-go-round, v = 4 ms-1
Radius of circle, r = 2 m
As the lady sits on the merry-go-round, her earring experiences centripetal acceleration.
Centripetal acceleration (a) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Resultant acceleration (A) is given by ,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time Period,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.48. Find the time period of small oscillations of the following systems. (a) A metre stick suspended through the 20 cm mark. (b) A ring of mass m and radius r suspended through a point on its periphery. (c) A uniform square plate of edge a suspended through a corner. (d) A uniform disc of mass m and radius r suspended through a point r/2 away from the centre.

(a) Moment Of inertia (I) about the point X is given by ,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
I = IC.G + mh2
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
The time Period (T) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE where I = the  moment  of  inertia,   and  
l = distance  between  the  centre  of  gravity  and  the  point  of  suspension.
On  substituting  the  respective  values  in  the  above  formula, we  get: HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE = 1.52s
(b) Moment Of inertia (I) about A is given as,
I = IC.G. + mr= mr+ mr= 2mr2
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
The time period (T) will be,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On  substituting  the  respective  values  in  the  above  equation, we  have:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(c) Let I be the moment of inertia of a uniform square plate suspended through a corner.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
In the
△ ABC, l2 + l2 = a2
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(d) We  know
h = r/2
Distance  between  the  C . G .   and  suspension  point, l = r/2
Moment of inertia about A will be:
l = IC.G. + mh2
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time period (T) will be,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.49. A uniform rod of length l is suspended by an end and is made to undergo small oscillations. Find the length of the simple pendulum having the time period equal to that of the road.

It is given that the length of the rod is l.
Let point A be the suspension point and point B be the centre of gravity.
Separation between the point of suspension and the centre of mass, l' = l/2
Also, h = l/2
Using parallel axis theorem, the moment of inertia about A is given as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let T' be the time period of simple pendulum of length x.
Time Period (T') is given by HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
As  the  time  period  of  the  simple  pendulum  is  equal  to  the  time  period  of  the  rod, T' = T
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.50. A uniform disc of radius r is to be suspended through a small hole made in the disc. Find the minimum possible time period of the disc for small oscillations. What should be the distance of the hole from the centre for it to have minimum time period?

Let m be the mass of the disc and r be its radius.
Consider a point at a distance x from the centre of gravity.
Thus, l = x
Moment of intertia (I) about the point x will be,
I = IC.G +mx2
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Time period(T) is given as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On  substituting  the  respective  values  in  the  above  equation,   we  get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
To determine the minimum value of T,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On  substituting  the  respective  values  in  the  above  equation,   we  get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
To determine the minimum value of T,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Substituting this value of x in equation (1), we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 


Q.51. A hollow sphere of radius 2 cm is attached to an 18 cm long thread to make a pendulum. Find the time period of oscillation of this pendulum. How does it differ from the time period calculated using the formula for a simple pendulum?

HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Let I be the moment of inertia and ω be the angular speed.
Using the energy equation, we can write:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Moment  of  inertia  about  the  point  of  suspension  A  is  given  by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Substituting  the  value  of  l  in  the  above  equation,   we  get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On substituting the value of I in equation (1) and differentiating it, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Thus,   time  period (T) will  be:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
For a simple pendulum, time period (T) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
%   change  in  the  value  of  time  period = HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
∴ It is about 0.3% greater than the calculated value.


Q.52. A closed circular wire hung on a nail in a wall undergoes small oscillations of amplitude 2° and time period 2 s. Find (a) the radius of the circular wire, (b) the speed of the particle farthest away from the point of suspension as it goes through its mean position, (c) the acceleration of this particle as it goes through its mean position and (d) the acceleration of this particle when it is at an extreme position. Take g = π2 m/s2.

It is given that:
Time period of oscillation, T = 2 s
Acceleration due to gravity, g = π2 ms-2
Let I be the moment of inertia of the circular wire having mass m and radius r.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(a) Time period of compound pendulum (T) is given by ,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Moment of inertia about the point of suspension  is calculated as,
I = mr2 + mr2 = 2mr2
On substituting the value of moment of inertia I in equation (1), we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) From the energy equation, we have:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On  substituing  the  value  of  g  and  r  in  the  above  equation,   we  get: ω = 0.11 rad/s
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(c) The acceleration is found to be centripetal at the extreme position.
Centripetal acceleration at the extreme position (an)is given by,
a= ω2(2r) = (0.11) × 100 = 12 cm/s2
The direction of an is towards the point of suspension.
(d) The particle has zero centripetal acceleration at the extreme position. However, the particle will still have acceleration due to the S.H.M.
Angular frequency (ω) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
∴ Angular Accelaration (a) at the extrame position is given as,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Thus , tangential acceleration
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
= 34 cm/s2


Q.53. A uniform disc of mass m and radius r is suspended through a wire attached to its centre. If the time period of the torsional oscillations be T, what is the torsional constant of the wire?

It is given that:
Mass of disc = m
Radius of disc = r
The time period of torsional oscillations is T.
 Moment of inertia of the disc at the centre, I = mr2/2
Time period of torsional pendulum (T) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
where I is the moment of inertia, and k is the torsional constant.
On substituting the value of moment of inertia in the expression for time period T, we have:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On  squaring  both  the  sides,   we  get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 


Q.54. Two small balls, each of mass m are connected by a light rigid rod of length L. The system is suspended from its centre by a thin wire of torsional constant k. The rod is rotated about the wire through an angle θ0 and released. Find the force exerted by the rod on one of the balls as the system passes through the mean position.
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE

It is given that the mass of both the balls is m and they are connected to each other with the help of a light rod of length L.
Moment of inertia of the two-ball system (I) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Torque (τ), produced at any given position θ is given as: τ = kθ
⇒ Work done during the displacement of system from 0 to θ0 will be,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
On applying work-energy theorem, we get:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
From the free body diagram of the rod, we can write:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.55. A particle is subjected to two simple harmonic motions of same time period in the same direction. The amplitude of the first motion is 3.0 cm and that of the second is 4.0 cm. Find the resultant amplitude if the phase difference between the motions is (a) 0°, (b) 60°, (c) 90°.

It is given that a particle is subjected to two S.H.M.s of same time period in the same direction.
Amplitude of first motion, A1 = 3 cm
Amplitude of second motion, A2 = 4 cm
Let ϕ be the phase difference.
The resultant amplitude (R) is given by,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.56. Three simple harmonic motions of equal amplitude A and equal time periods in the same direction combine. The phase of the second motion is 60° ahead of the first and the phase of the third motion is 60° ahead of the second. Find the amplitude of the resultant motion.

It is given that three S.H.M.s of equal amplitudes A and equal time periods are combined in the same direction.
Let Y1, Y2 and Y3 be the three vectors representing the motions, as shown in the figure given below.
According to the question:
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
By using the vector method, we can find the resultant vector.
Resultant amplitude = Vector sum of the three vectors
= A + A cos 60° + A cos 60°
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.57. A particle is subjected to two simple harmonic motions given by x1 = 2.0 sin (100π t) and x2 = 2.0 sin (120 π t + π/3), where x is in centimeter and t in second. Find the displacement of the particle at (a) t = 0.0125, (b) t = 0.025.

Given are the equations of motion of a particle:
 x1 = 2.0sin100 πt
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
The Resultant displacement (x) will be
x = x+ x2
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(a) At t = 0.0125 s
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
(b) At t = 0.025 s
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE


Q.58. A particle is subjected to two simple harmonic motions, one along the X-axis and the other on a line making an angle of 45° with the X-axis. The two motions are given by x = x0 sin ωt and s = s0 sin ωt. Find the amplitude of the resultant motion.

Given:
Equation of motion along X axis, x = x0 sinωt
Equation of motion along Y axis, s = s0 sinωt
Angle between the two motions, θ 45°
Resultant motion (R) will be,
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE
Hence, the resultant amplitude is
HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE 

The document HC Verma Questions and Solutions: Chapter 12: Simple Harmonics Motion- 2 | HC Verma Solutions - JEE is a part of the JEE Course HC Verma Solutions.
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