All Courses
Get the App Signup / Login
Sign in Open App
NEET Exam  >  NEET Notes  >  Physics Class 11  >  HC Verma Solutions: Chapter 12 - Simple Harmonics Motion

HC Verma Solutions: Chapter 12 - Simple Harmonics Motion | Physics Class 11 - NEET PDF Download

Download, print and study this document offline
Please wait while the PDF view is loading
 Page 1


12.1
SOLUTIONS TO CONCEPTS 
CHAPTER 12
1. Given, r = 10cm.
At t = 0, x = 5 cm.
T = 6 sec.
So, w = 
T
2 ?
= 
6
2 ?
= 
3
?
sec
–1
At, t = 0, x = 5 cm.
So, 5 = 10 sin (w × 0 + ?) = 10 sin ? [y = r sin wt]
Sin ? = 1/2 ? ? = 
6
?
? Equation of displacement x = (10cm) sin ?
?
?
?
?
? ?
3
(ii) At t = 4 second
x = 10 sin 
?
?
?
?
?
? ?
? ?
?
6
4
3
= 10 sin 
?
?
?
?
?
? ? ? ?
6
8
= 10 sin ?
?
?
?
?
? ?
2
3
= 10 sin ?
?
?
?
?
? ?
? ?
2
= - 10 sin ?
?
?
?
?
? ?
2
= -10
Acceleration a = – w
2
x = –
?
?
?
?
?
?
?
?
?
9
2
× (–10) = 10.9 ? 0.11 cm/sec. ?
2. Given that, at a particular instant,
X = 2cm = 0.02m
V = 1 m/sec
A = 10 msec
–2
We know that a = ?
2
x 
? ? = 
x
a
= 
02 . 0
10
= 500 = 10 5
T = 
?
? 2
= 
5 10
2 ?
= 
236 . 2 10
14 . 3 2
?
?
= 0.28 seconds.
Again, amplitude r is given by v = ?
?
?
?
?
?
?
?
2 2
x r ?
? v
2
= ?
2
(r
2
– x
2
)
1 = 500 (r
2
– 0.0004)
? r = 0.0489 ? 0.049 m
? r = 4.9 cm. ?
3. r = 10cm
Because, K.E. = P.E.
So (1/2) m ?
2
(r
2
– y
2
) = (1/2) m ?
2
y
2
r
2
– y
2
= y
2
? 2y
2 
= r
2
? y = 
2
r
= 
2
10
= 5 2 cm form the mean position. ?
4. v
max
= 10 cm/sec.
? r ? = 10
? ?
2
= 
2
r
100
…(1)
A
max
= ?
2
r = 50 cm/sec
? ?
2
= 
y
50
= 
r
50
…(2)
Page 2


12.1
SOLUTIONS TO CONCEPTS 
CHAPTER 12
1. Given, r = 10cm.
At t = 0, x = 5 cm.
T = 6 sec.
So, w = 
T
2 ?
= 
6
2 ?
= 
3
?
sec
–1
At, t = 0, x = 5 cm.
So, 5 = 10 sin (w × 0 + ?) = 10 sin ? [y = r sin wt]
Sin ? = 1/2 ? ? = 
6
?
? Equation of displacement x = (10cm) sin ?
?
?
?
?
? ?
3
(ii) At t = 4 second
x = 10 sin 
?
?
?
?
?
? ?
? ?
?
6
4
3
= 10 sin 
?
?
?
?
?
? ? ? ?
6
8
= 10 sin ?
?
?
?
?
? ?
2
3
= 10 sin ?
?
?
?
?
? ?
? ?
2
= - 10 sin ?
?
?
?
?
? ?
2
= -10
Acceleration a = – w
2
x = –
?
?
?
?
?
?
?
?
?
9
2
× (–10) = 10.9 ? 0.11 cm/sec. ?
2. Given that, at a particular instant,
X = 2cm = 0.02m
V = 1 m/sec
A = 10 msec
–2
We know that a = ?
2
x 
? ? = 
x
a
= 
02 . 0
10
= 500 = 10 5
T = 
?
? 2
= 
5 10
2 ?
= 
236 . 2 10
14 . 3 2
?
?
= 0.28 seconds.
Again, amplitude r is given by v = ?
?
?
?
?
?
?
?
2 2
x r ?
? v
2
= ?
2
(r
2
– x
2
)
1 = 500 (r
2
– 0.0004)
? r = 0.0489 ? 0.049 m
? r = 4.9 cm. ?
3. r = 10cm
Because, K.E. = P.E.
So (1/2) m ?
2
(r
2
– y
2
) = (1/2) m ?
2
y
2
r
2
– y
2
= y
2
? 2y
2 
= r
2
? y = 
2
r
= 
2
10
= 5 2 cm form the mean position. ?
4. v
max
= 10 cm/sec.
? r ? = 10
? ?
2
= 
2
r
100
…(1)
A
max
= ?
2
r = 50 cm/sec
? ?
2
= 
y
50
= 
r
50
…(2)
Chapter 12
12.2
?
2
r
100
= 
r
50
? r = 2 cm.
? ? = 
2
r
100
= 5 sec
2
Again, to find out the positions where the speed is 8m/sec,
v
2
= ?
2
(r
2
– y
2
)
? 64 = 25 ( 4 – y
2
)
? 4 – y
2
= 
25
64
? y
2
= 1.44 ? y = 44 . 1 ? y = ?1.2 cm from mean position.
5. x = (2.0cm)sin [(100s
–1
) t + ( ?/6)]
m = 10g.
a) Amplitude = 2cm.
? = 100 sec
–1
? T = 
100
2 ?
= 
50
?
sec = 0.063 sec.
We know that T = 2 ?
k
m
? T
2
= 4 ?
2
×
k
m
? k = m
T
4
2
2
?
= 10
5
dyne/cm = 100 N/m. [because ? = 
T
2 ?
= 100 sec
–1
]
b) At t = 0
x = 2cm sin ?
?
?
?
?
? ?
6
= 2 × (1/2) = 1 cm. from the mean position.
We know that x = A sin ( ?t + ?)
v = A cos ( ?t + ?)
= 2 × 100 cos (0 + ?/6) = 200 × 
2
3
= 100 3 sec
–1
= 1.73m/s
c) a = – ?
2
x = 100
2
× 1 = 100 m/s
2
?
6. x = 5 sin (20t + ?/3)
a) Max. displacement from the mean position = Amplitude of the particle.
At the extreme position, the velocity becomes ‘0’.
? x = 5 = Amplitude.
? 5 = 5 sin (20t + ?/3)
sin (20t + ?/3) = 1 = sin ( ?/2)
? 20t + ?/3 = ?/2
? t = ?/120 sec., So at ?/120 sec it first comes to rest.
b) a = ?
2
x = ?
2
[5 sin (20t + ?/3)]
For a = 0, 5 sin (20t + ?/3) = 0 ? sin (20t + ?/3) = sin ( ?) ?
? 20 t = ? – ?/3 = 2 ?/3 
? t = ?/30 sec.
c) v = A ? cos ( ?t + ?/3) = 20 × 5 cos (20t + ?/3)
when, v is maximum i.e. cos (20t + ?/3) = –1 = cos ?
? 20t = ? – ?/3 = 2 ?/3
? t = ?/30 sec. ?
7. a) x = 2.0 cos (50 ?t + tan
–1
0.75) = 2.0 cos (50 ?t + 0.643)
v = 
dt
dx
= – 100 sin (50 ?t + 0.643)
? sin (50 ?t + 0.643) = 0
As the particle comes to rest for the 1
st
time
? 50 ?t + 0.643 = ?
? t = 1.6 × 10
–2
sec.
Page 3


12.1
SOLUTIONS TO CONCEPTS 
CHAPTER 12
1. Given, r = 10cm.
At t = 0, x = 5 cm.
T = 6 sec.
So, w = 
T
2 ?
= 
6
2 ?
= 
3
?
sec
–1
At, t = 0, x = 5 cm.
So, 5 = 10 sin (w × 0 + ?) = 10 sin ? [y = r sin wt]
Sin ? = 1/2 ? ? = 
6
?
? Equation of displacement x = (10cm) sin ?
?
?
?
?
? ?
3
(ii) At t = 4 second
x = 10 sin 
?
?
?
?
?
? ?
? ?
?
6
4
3
= 10 sin 
?
?
?
?
?
? ? ? ?
6
8
= 10 sin ?
?
?
?
?
? ?
2
3
= 10 sin ?
?
?
?
?
? ?
? ?
2
= - 10 sin ?
?
?
?
?
? ?
2
= -10
Acceleration a = – w
2
x = –
?
?
?
?
?
?
?
?
?
9
2
× (–10) = 10.9 ? 0.11 cm/sec. ?
2. Given that, at a particular instant,
X = 2cm = 0.02m
V = 1 m/sec
A = 10 msec
–2
We know that a = ?
2
x 
? ? = 
x
a
= 
02 . 0
10
= 500 = 10 5
T = 
?
? 2
= 
5 10
2 ?
= 
236 . 2 10
14 . 3 2
?
?
= 0.28 seconds.
Again, amplitude r is given by v = ?
?
?
?
?
?
?
?
2 2
x r ?
? v
2
= ?
2
(r
2
– x
2
)
1 = 500 (r
2
– 0.0004)
? r = 0.0489 ? 0.049 m
? r = 4.9 cm. ?
3. r = 10cm
Because, K.E. = P.E.
So (1/2) m ?
2
(r
2
– y
2
) = (1/2) m ?
2
y
2
r
2
– y
2
= y
2
? 2y
2 
= r
2
? y = 
2
r
= 
2
10
= 5 2 cm form the mean position. ?
4. v
max
= 10 cm/sec.
? r ? = 10
? ?
2
= 
2
r
100
…(1)
A
max
= ?
2
r = 50 cm/sec
? ?
2
= 
y
50
= 
r
50
…(2)
Chapter 12
12.2
?
2
r
100
= 
r
50
? r = 2 cm.
? ? = 
2
r
100
= 5 sec
2
Again, to find out the positions where the speed is 8m/sec,
v
2
= ?
2
(r
2
– y
2
)
? 64 = 25 ( 4 – y
2
)
? 4 – y
2
= 
25
64
? y
2
= 1.44 ? y = 44 . 1 ? y = ?1.2 cm from mean position.
5. x = (2.0cm)sin [(100s
–1
) t + ( ?/6)]
m = 10g.
a) Amplitude = 2cm.
? = 100 sec
–1
? T = 
100
2 ?
= 
50
?
sec = 0.063 sec.
We know that T = 2 ?
k
m
? T
2
= 4 ?
2
×
k
m
? k = m
T
4
2
2
?
= 10
5
dyne/cm = 100 N/m. [because ? = 
T
2 ?
= 100 sec
–1
]
b) At t = 0
x = 2cm sin ?
?
?
?
?
? ?
6
= 2 × (1/2) = 1 cm. from the mean position.
We know that x = A sin ( ?t + ?)
v = A cos ( ?t + ?)
= 2 × 100 cos (0 + ?/6) = 200 × 
2
3
= 100 3 sec
–1
= 1.73m/s
c) a = – ?
2
x = 100
2
× 1 = 100 m/s
2
?
6. x = 5 sin (20t + ?/3)
a) Max. displacement from the mean position = Amplitude of the particle.
At the extreme position, the velocity becomes ‘0’.
? x = 5 = Amplitude.
? 5 = 5 sin (20t + ?/3)
sin (20t + ?/3) = 1 = sin ( ?/2)
? 20t + ?/3 = ?/2
? t = ?/120 sec., So at ?/120 sec it first comes to rest.
b) a = ?
2
x = ?
2
[5 sin (20t + ?/3)]
For a = 0, 5 sin (20t + ?/3) = 0 ? sin (20t + ?/3) = sin ( ?) ?
? 20 t = ? – ?/3 = 2 ?/3 
? t = ?/30 sec.
c) v = A ? cos ( ?t + ?/3) = 20 × 5 cos (20t + ?/3)
when, v is maximum i.e. cos (20t + ?/3) = –1 = cos ?
? 20t = ? – ?/3 = 2 ?/3
? t = ?/30 sec. ?
7. a) x = 2.0 cos (50 ?t + tan
–1
0.75) = 2.0 cos (50 ?t + 0.643)
v = 
dt
dx
= – 100 sin (50 ?t + 0.643)
? sin (50 ?t + 0.643) = 0
As the particle comes to rest for the 1
st
time
? 50 ?t + 0.643 = ?
? t = 1.6 × 10
–2
sec.
Chapter 12
12.3
b) Acceleration a = 
dt
dv
= – 100 ? × 50 ? cos (50 ?t + 0.643)
For maximum acceleration cos (50 ?t + 0.643) = – 1 cos ? (max) (so a is max)
? t = 1.6 × 10
–2
sec.
c) When the particle comes to rest for second time,
50 ?t + 0.643 = 2 ?
? t = 3.6 × 10
–2
s.
8. y
1
= 
2
r
, y
2
= r (for the two given position)
Now, y
1
= r sin ?t
1
?
2
r
= r sin ?t
1 
? sin ?t
1
= 
2
1
? ?t
1
= 
2
?
?
t
2 ?
× t
1
= 
6
?
? t
1
? ?
12
t
Again, y
2
= r sin ?t
2
? r = r sin ?t
2
? sin ?t
2
= 1 ? ?t
2
= ?/2 ? ?
?
?
?
?
? ?
t
2
t
2
= 
2
?
? t
2
= 
4
t
So, t
2
– t
1
= 
12
t
4
t
? = 
6
t
?
9. k = 0.1 N/m
T = 2 ?
k
m
?= 2 sec [Time period of pendulum of a clock = 2 sec]
So, 4 ?
2+ ?
?
?
?
?
?
k
m
= 4
? m = 2
k
?
= 
10
1 . 0
= 0.01kg ? 10 gm.
10. Time period of simple pendulum = 2 ?
g
1
Time period of spring is 2 ?
k
m
?
T
p
= T
s
[Frequency is same]
?
g
1
???
k
m
? ??
k
m
g
1
? ?
??????
k
mg
???
k
F
= x. (Because, restoring force = weight = F =mg)
? 1 = x (proved)
11. x = r = 0.1 m
T = 0.314 sec
m = 0.5 kg.
Total force exerted on the block = weight of the block + spring force.
T = 2 ?
k
m
?? 0.314 = 2 ?
k
5 . 0
? k = 200 N/m
? Force exerted by the spring on the block is 
F = kx = 201.1 × 0.1 = 20N
? Maximum force = F + weight = 20 + 5 = 25N
12. m = 2kg.
T = 4 sec.
T = 2 ?
k
m
? 4 = 2 ?
K
2
? 2 = ?
K
2
x
? ?
0.5kg
Page 4


12.1
SOLUTIONS TO CONCEPTS 
CHAPTER 12
1. Given, r = 10cm.
At t = 0, x = 5 cm.
T = 6 sec.
So, w = 
T
2 ?
= 
6
2 ?
= 
3
?
sec
–1
At, t = 0, x = 5 cm.
So, 5 = 10 sin (w × 0 + ?) = 10 sin ? [y = r sin wt]
Sin ? = 1/2 ? ? = 
6
?
? Equation of displacement x = (10cm) sin ?
?
?
?
?
? ?
3
(ii) At t = 4 second
x = 10 sin 
?
?
?
?
?
? ?
? ?
?
6
4
3
= 10 sin 
?
?
?
?
?
? ? ? ?
6
8
= 10 sin ?
?
?
?
?
? ?
2
3
= 10 sin ?
?
?
?
?
? ?
? ?
2
= - 10 sin ?
?
?
?
?
? ?
2
= -10
Acceleration a = – w
2
x = –
?
?
?
?
?
?
?
?
?
9
2
× (–10) = 10.9 ? 0.11 cm/sec. ?
2. Given that, at a particular instant,
X = 2cm = 0.02m
V = 1 m/sec
A = 10 msec
–2
We know that a = ?
2
x 
? ? = 
x
a
= 
02 . 0
10
= 500 = 10 5
T = 
?
? 2
= 
5 10
2 ?
= 
236 . 2 10
14 . 3 2
?
?
= 0.28 seconds.
Again, amplitude r is given by v = ?
?
?
?
?
?
?
?
2 2
x r ?
? v
2
= ?
2
(r
2
– x
2
)
1 = 500 (r
2
– 0.0004)
? r = 0.0489 ? 0.049 m
? r = 4.9 cm. ?
3. r = 10cm
Because, K.E. = P.E.
So (1/2) m ?
2
(r
2
– y
2
) = (1/2) m ?
2
y
2
r
2
– y
2
= y
2
? 2y
2 
= r
2
? y = 
2
r
= 
2
10
= 5 2 cm form the mean position. ?
4. v
max
= 10 cm/sec.
? r ? = 10
? ?
2
= 
2
r
100
…(1)
A
max
= ?
2
r = 50 cm/sec
? ?
2
= 
y
50
= 
r
50
…(2)
Chapter 12
12.2
?
2
r
100
= 
r
50
? r = 2 cm.
? ? = 
2
r
100
= 5 sec
2
Again, to find out the positions where the speed is 8m/sec,
v
2
= ?
2
(r
2
– y
2
)
? 64 = 25 ( 4 – y
2
)
? 4 – y
2
= 
25
64
? y
2
= 1.44 ? y = 44 . 1 ? y = ?1.2 cm from mean position.
5. x = (2.0cm)sin [(100s
–1
) t + ( ?/6)]
m = 10g.
a) Amplitude = 2cm.
? = 100 sec
–1
? T = 
100
2 ?
= 
50
?
sec = 0.063 sec.
We know that T = 2 ?
k
m
? T
2
= 4 ?
2
×
k
m
? k = m
T
4
2
2
?
= 10
5
dyne/cm = 100 N/m. [because ? = 
T
2 ?
= 100 sec
–1
]
b) At t = 0
x = 2cm sin ?
?
?
?
?
? ?
6
= 2 × (1/2) = 1 cm. from the mean position.
We know that x = A sin ( ?t + ?)
v = A cos ( ?t + ?)
= 2 × 100 cos (0 + ?/6) = 200 × 
2
3
= 100 3 sec
–1
= 1.73m/s
c) a = – ?
2
x = 100
2
× 1 = 100 m/s
2
?
6. x = 5 sin (20t + ?/3)
a) Max. displacement from the mean position = Amplitude of the particle.
At the extreme position, the velocity becomes ‘0’.
? x = 5 = Amplitude.
? 5 = 5 sin (20t + ?/3)
sin (20t + ?/3) = 1 = sin ( ?/2)
? 20t + ?/3 = ?/2
? t = ?/120 sec., So at ?/120 sec it first comes to rest.
b) a = ?
2
x = ?
2
[5 sin (20t + ?/3)]
For a = 0, 5 sin (20t + ?/3) = 0 ? sin (20t + ?/3) = sin ( ?) ?
? 20 t = ? – ?/3 = 2 ?/3 
? t = ?/30 sec.
c) v = A ? cos ( ?t + ?/3) = 20 × 5 cos (20t + ?/3)
when, v is maximum i.e. cos (20t + ?/3) = –1 = cos ?
? 20t = ? – ?/3 = 2 ?/3
? t = ?/30 sec. ?
7. a) x = 2.0 cos (50 ?t + tan
–1
0.75) = 2.0 cos (50 ?t + 0.643)
v = 
dt
dx
= – 100 sin (50 ?t + 0.643)
? sin (50 ?t + 0.643) = 0
As the particle comes to rest for the 1
st
time
? 50 ?t + 0.643 = ?
? t = 1.6 × 10
–2
sec.
Chapter 12
12.3
b) Acceleration a = 
dt
dv
= – 100 ? × 50 ? cos (50 ?t + 0.643)
For maximum acceleration cos (50 ?t + 0.643) = – 1 cos ? (max) (so a is max)
? t = 1.6 × 10
–2
sec.
c) When the particle comes to rest for second time,
50 ?t + 0.643 = 2 ?
? t = 3.6 × 10
–2
s.
8. y
1
= 
2
r
, y
2
= r (for the two given position)
Now, y
1
= r sin ?t
1
?
2
r
= r sin ?t
1 
? sin ?t
1
= 
2
1
? ?t
1
= 
2
?
?
t
2 ?
× t
1
= 
6
?
? t
1
? ?
12
t
Again, y
2
= r sin ?t
2
? r = r sin ?t
2
? sin ?t
2
= 1 ? ?t
2
= ?/2 ? ?
?
?
?
?
? ?
t
2
t
2
= 
2
?
? t
2
= 
4
t
So, t
2
– t
1
= 
12
t
4
t
? = 
6
t
?
9. k = 0.1 N/m
T = 2 ?
k
m
?= 2 sec [Time period of pendulum of a clock = 2 sec]
So, 4 ?
2+ ?
?
?
?
?
?
k
m
= 4
? m = 2
k
?
= 
10
1 . 0
= 0.01kg ? 10 gm.
10. Time period of simple pendulum = 2 ?
g
1
Time period of spring is 2 ?
k
m
?
T
p
= T
s
[Frequency is same]
?
g
1
???
k
m
? ??
k
m
g
1
? ?
??????
k
mg
???
k
F
= x. (Because, restoring force = weight = F =mg)
? 1 = x (proved)
11. x = r = 0.1 m
T = 0.314 sec
m = 0.5 kg.
Total force exerted on the block = weight of the block + spring force.
T = 2 ?
k
m
?? 0.314 = 2 ?
k
5 . 0
? k = 200 N/m
? Force exerted by the spring on the block is 
F = kx = 201.1 × 0.1 = 20N
? Maximum force = F + weight = 20 + 5 = 25N
12. m = 2kg.
T = 4 sec.
T = 2 ?
k
m
? 4 = 2 ?
K
2
? 2 = ?
K
2
x
? ?
0.5kg
Chapter 12
12.4
? 4 = ?
2
?
?
?
?
?
?
k
2
? k = 
4
2
2
?
? k = 
2
2
?
= 5 N/m 
But, we know that F = mg = kx
? x = 
k
mg
= 
5
10 2 ?
= 4
?Potential Energy = (1/2) k x
2
= (1/2) × 5 × 16 = 5 × 8 = 40J
13. x = 25cm = 0.25m
E = 5J
f = 5
So, T = 1/5sec.
Now P.E. = (1/2) kx
2
?(1/2) kx
2
= 5 ? (1/2) k (0.25)
2
= 5 ? k = 160 N/m.
Again, T = 2 ?
k
m
???
5
1
??????
160
m
? m = 0.16 kg.
14. a) From the free body diagram, 
? R + m ?
2
x – mg = 0 …(1)
Resultant force m ?
2
x = mg – R
? m ?
2
x = m ?
?
?
?
?
?
? m M
k
? x = 
m M
mkx
?
[ ? = ) m M /( k ? for spring mass system]
b) R = mg – m ?
2
x = mg - m x
m M
k
?
= mg –
m M
mkx
?
For R to be smallest, m ?
2
x should be max. i.e. x is maximum. ?
The particle should be at the high point.
c) We have R = mg – m ?
2
x 
The tow blocks may oscillates together in such a way that R is greater than 0. At limiting condition, R 
= 0, mg = m ?
2
x
X = 
2
m
mg
?
= 
mk
) m M ( mg ?
So, the maximum amplitude is = 
k
) m M ( g ?
15. a) At the equilibrium condition,
kx = (m
1
+ m
2
) g sin ?
? x = 
k
sin g ) m m (
2 1
? ?
b) x
1
= 
k
2
(m
1
+ m
2
) g sin ? (Given)
when the system is released, it will start to make SHM
where ? = 
2 1
m m
k
?
When the blocks lose contact, P = 0
So m
2
g sin ? = m
2 
x
2 
?
2
= m
2 
x
2
?
?
?
?
?
?
?
?
?
2 1
m m
k
? x
2
= k
sin g ) m m (
2 1
? ?
So the blocks will lose contact with each other when the springs attain its natural length.
A
B
M
K
x
m
mg
R
a= ?
2
x ?
m ?
2
x ?
m 2
x 2
m 1g
m 1
x 1
g
k
m 2g
F
R
(m 1 +m 2)g
R
P
m 2a
a
m 2g
Page 5


12.1
SOLUTIONS TO CONCEPTS 
CHAPTER 12
1. Given, r = 10cm.
At t = 0, x = 5 cm.
T = 6 sec.
So, w = 
T
2 ?
= 
6
2 ?
= 
3
?
sec
–1
At, t = 0, x = 5 cm.
So, 5 = 10 sin (w × 0 + ?) = 10 sin ? [y = r sin wt]
Sin ? = 1/2 ? ? = 
6
?
? Equation of displacement x = (10cm) sin ?
?
?
?
?
? ?
3
(ii) At t = 4 second
x = 10 sin 
?
?
?
?
?
? ?
? ?
?
6
4
3
= 10 sin 
?
?
?
?
?
? ? ? ?
6
8
= 10 sin ?
?
?
?
?
? ?
2
3
= 10 sin ?
?
?
?
?
? ?
? ?
2
= - 10 sin ?
?
?
?
?
? ?
2
= -10
Acceleration a = – w
2
x = –
?
?
?
?
?
?
?
?
?
9
2
× (–10) = 10.9 ? 0.11 cm/sec. ?
2. Given that, at a particular instant,
X = 2cm = 0.02m
V = 1 m/sec
A = 10 msec
–2
We know that a = ?
2
x 
? ? = 
x
a
= 
02 . 0
10
= 500 = 10 5
T = 
?
? 2
= 
5 10
2 ?
= 
236 . 2 10
14 . 3 2
?
?
= 0.28 seconds.
Again, amplitude r is given by v = ?
?
?
?
?
?
?
?
2 2
x r ?
? v
2
= ?
2
(r
2
– x
2
)
1 = 500 (r
2
– 0.0004)
? r = 0.0489 ? 0.049 m
? r = 4.9 cm. ?
3. r = 10cm
Because, K.E. = P.E.
So (1/2) m ?
2
(r
2
– y
2
) = (1/2) m ?
2
y
2
r
2
– y
2
= y
2
? 2y
2 
= r
2
? y = 
2
r
= 
2
10
= 5 2 cm form the mean position. ?
4. v
max
= 10 cm/sec.
? r ? = 10
? ?
2
= 
2
r
100
…(1)
A
max
= ?
2
r = 50 cm/sec
? ?
2
= 
y
50
= 
r
50
…(2)
Chapter 12
12.2
?
2
r
100
= 
r
50
? r = 2 cm.
? ? = 
2
r
100
= 5 sec
2
Again, to find out the positions where the speed is 8m/sec,
v
2
= ?
2
(r
2
– y
2
)
? 64 = 25 ( 4 – y
2
)
? 4 – y
2
= 
25
64
? y
2
= 1.44 ? y = 44 . 1 ? y = ?1.2 cm from mean position.
5. x = (2.0cm)sin [(100s
–1
) t + ( ?/6)]
m = 10g.
a) Amplitude = 2cm.
? = 100 sec
–1
? T = 
100
2 ?
= 
50
?
sec = 0.063 sec.
We know that T = 2 ?
k
m
? T
2
= 4 ?
2
×
k
m
? k = m
T
4
2
2
?
= 10
5
dyne/cm = 100 N/m. [because ? = 
T
2 ?
= 100 sec
–1
]
b) At t = 0
x = 2cm sin ?
?
?
?
?
? ?
6
= 2 × (1/2) = 1 cm. from the mean position.
We know that x = A sin ( ?t + ?)
v = A cos ( ?t + ?)
= 2 × 100 cos (0 + ?/6) = 200 × 
2
3
= 100 3 sec
–1
= 1.73m/s
c) a = – ?
2
x = 100
2
× 1 = 100 m/s
2
?
6. x = 5 sin (20t + ?/3)
a) Max. displacement from the mean position = Amplitude of the particle.
At the extreme position, the velocity becomes ‘0’.
? x = 5 = Amplitude.
? 5 = 5 sin (20t + ?/3)
sin (20t + ?/3) = 1 = sin ( ?/2)
? 20t + ?/3 = ?/2
? t = ?/120 sec., So at ?/120 sec it first comes to rest.
b) a = ?
2
x = ?
2
[5 sin (20t + ?/3)]
For a = 0, 5 sin (20t + ?/3) = 0 ? sin (20t + ?/3) = sin ( ?) ?
? 20 t = ? – ?/3 = 2 ?/3 
? t = ?/30 sec.
c) v = A ? cos ( ?t + ?/3) = 20 × 5 cos (20t + ?/3)
when, v is maximum i.e. cos (20t + ?/3) = –1 = cos ?
? 20t = ? – ?/3 = 2 ?/3
? t = ?/30 sec. ?
7. a) x = 2.0 cos (50 ?t + tan
–1
0.75) = 2.0 cos (50 ?t + 0.643)
v = 
dt
dx
= – 100 sin (50 ?t + 0.643)
? sin (50 ?t + 0.643) = 0
As the particle comes to rest for the 1
st
time
? 50 ?t + 0.643 = ?
? t = 1.6 × 10
–2
sec.
Chapter 12
12.3
b) Acceleration a = 
dt
dv
= – 100 ? × 50 ? cos (50 ?t + 0.643)
For maximum acceleration cos (50 ?t + 0.643) = – 1 cos ? (max) (so a is max)
? t = 1.6 × 10
–2
sec.
c) When the particle comes to rest for second time,
50 ?t + 0.643 = 2 ?
? t = 3.6 × 10
–2
s.
8. y
1
= 
2
r
, y
2
= r (for the two given position)
Now, y
1
= r sin ?t
1
?
2
r
= r sin ?t
1 
? sin ?t
1
= 
2
1
? ?t
1
= 
2
?
?
t
2 ?
× t
1
= 
6
?
? t
1
? ?
12
t
Again, y
2
= r sin ?t
2
? r = r sin ?t
2
? sin ?t
2
= 1 ? ?t
2
= ?/2 ? ?
?
?
?
?
? ?
t
2
t
2
= 
2
?
? t
2
= 
4
t
So, t
2
– t
1
= 
12
t
4
t
? = 
6
t
?
9. k = 0.1 N/m
T = 2 ?
k
m
?= 2 sec [Time period of pendulum of a clock = 2 sec]
So, 4 ?
2+ ?
?
?
?
?
?
k
m
= 4
? m = 2
k
?
= 
10
1 . 0
= 0.01kg ? 10 gm.
10. Time period of simple pendulum = 2 ?
g
1
Time period of spring is 2 ?
k
m
?
T
p
= T
s
[Frequency is same]
?
g
1
???
k
m
? ??
k
m
g
1
? ?
??????
k
mg
???
k
F
= x. (Because, restoring force = weight = F =mg)
? 1 = x (proved)
11. x = r = 0.1 m
T = 0.314 sec
m = 0.5 kg.
Total force exerted on the block = weight of the block + spring force.
T = 2 ?
k
m
?? 0.314 = 2 ?
k
5 . 0
? k = 200 N/m
? Force exerted by the spring on the block is 
F = kx = 201.1 × 0.1 = 20N
? Maximum force = F + weight = 20 + 5 = 25N
12. m = 2kg.
T = 4 sec.
T = 2 ?
k
m
? 4 = 2 ?
K
2
? 2 = ?
K
2
x
? ?
0.5kg
Chapter 12
12.4
? 4 = ?
2
?
?
?
?
?
?
k
2
? k = 
4
2
2
?
? k = 
2
2
?
= 5 N/m 
But, we know that F = mg = kx
? x = 
k
mg
= 
5
10 2 ?
= 4
?Potential Energy = (1/2) k x
2
= (1/2) × 5 × 16 = 5 × 8 = 40J
13. x = 25cm = 0.25m
E = 5J
f = 5
So, T = 1/5sec.
Now P.E. = (1/2) kx
2
?(1/2) kx
2
= 5 ? (1/2) k (0.25)
2
= 5 ? k = 160 N/m.
Again, T = 2 ?
k
m
???
5
1
??????
160
m
? m = 0.16 kg.
14. a) From the free body diagram, 
? R + m ?
2
x – mg = 0 …(1)
Resultant force m ?
2
x = mg – R
? m ?
2
x = m ?
?
?
?
?
?
? m M
k
? x = 
m M
mkx
?
[ ? = ) m M /( k ? for spring mass system]
b) R = mg – m ?
2
x = mg - m x
m M
k
?
= mg –
m M
mkx
?
For R to be smallest, m ?
2
x should be max. i.e. x is maximum. ?
The particle should be at the high point.
c) We have R = mg – m ?
2
x 
The tow blocks may oscillates together in such a way that R is greater than 0. At limiting condition, R 
= 0, mg = m ?
2
x
X = 
2
m
mg
?
= 
mk
) m M ( mg ?
So, the maximum amplitude is = 
k
) m M ( g ?
15. a) At the equilibrium condition,
kx = (m
1
+ m
2
) g sin ?
? x = 
k
sin g ) m m (
2 1
? ?
b) x
1
= 
k
2
(m
1
+ m
2
) g sin ? (Given)
when the system is released, it will start to make SHM
where ? = 
2 1
m m
k
?
When the blocks lose contact, P = 0
So m
2
g sin ? = m
2 
x
2 
?
2
= m
2 
x
2
?
?
?
?
?
?
?
?
?
2 1
m m
k
? x
2
= k
sin g ) m m (
2 1
? ?
So the blocks will lose contact with each other when the springs attain its natural length.
A
B
M
K
x
m
mg
R
a= ?
2
x ?
m ?
2
x ?
m 2
x 2
m 1g
m 1
x 1
g
k
m 2g
F
R
(m 1 +m 2)g
R
P
m 2a
a
m 2g
Chapter 12
12.5
c) Let the common speed attained by both the blocks be v.
1/2 (m
1
+ m
2
) v
2
– 0 = 1/2 k(x
1
+ x
2
)
2
– (m
1
+ m
2
) g sin ? (x + x
1
)
[ x + x
1
= total compression]
? (1/2) (m
1
+ m
2
) v
2
= [(1/2) k (3/k) (m
1
+ m
2
) g sin ? –(m
1
+ m
2
) g sin ???(x + x
1
)
? (1/2) (m
1
+ m
2
) v
2 
= (1/2) (m
1
+ m
2
) g sin ? × (3/k) (m
1
+ m
2
) g sin ?
? v = 
) m m ( k
3
2 1
?
g sin ?.
16. Given, k = 100 N/m, M = 1kg and F = 10 N
a) In the equilibrium position,
compression ??= F/k = 10/100 = 0.1 m = 10 cm
b) The blow imparts a speed of 2m/s to the block towards left.
?P.E. + K.E. = 1/2 k ?
2
+ 1/2 Mv
2
= (1/2) × 100 × (0.1)
2
+ (1/2) × 1 × 4 = 0.5 + 2 = 2.5 J
c) Time period = 2 ?
k
M
= 2 ?
100
1
= 
5
?
sec
d) Let the amplitude be ‘x’ which means the distance between the mean position and the extreme 
position.
So, in the extreme position, compression of the spring is (x + ?).
Since, in SHM, the total energy remains constant.
(1/2) k (x + ?)
2
= (1/2) k ?
2
+ (1/2) mv
2
+ Fx = 2.5 + 10x
[because (1/2) k ?
2
+ (1/2) mv
2
= 2.5]
So, 50(x + 0.1)
2
= 2.5 + 10x
? 50 x
2
+ 0.5 + 10x = 2.5 + 10x
?50x
2
=2 ? x
2 
=
50
2
= 
100
4
? x = 
10
2
m = 20cm.
e) Potential Energy at the left extreme is given by,
P.E. = (1/2) k (x + ?)
2
= (1/2) × 100 (0.1 +0.2)
2
=50 × 0.09 = 4.5J
f) Potential Energy at the right extreme is given by, 
P.E. = (1/2) k (x + ?)
2
– F(2x) [2x = distance between two extremes]
= 4.5 – 10(0.4) = 0.5J
The different values in (b) (e) and (f) do not violate law of conservation of energy as the work is done by 
the external force 10N.
17. a) Equivalent spring constant k = k
1
+ k
2
(parallel)
T = 2 ?
k
M
= 2 ?
2 1
k k
m
?
b) Let us, displace the block m towards left through displacement ‘x’ ?
Resultant force F = F
1
+ F
2
= (k
1
+ k
2
)x
Acceleration (F/m) = 
m
x ) k k (
2 1
?
Time period T = 2 ?
on Accelerati
nt displaceme
= 2 ?
m
) k k ( m
x
2 1
?
= 2 ?
2 1
k k
m
?
?
The equivalent spring constant k = k
1
+ k
2
c) In series conn equivalent spring constant be k. 
So, 
k
1
= 
1
k
1
+ 
2
k
1
= 
2 1
1 2
k k
k k ?
? k = 
2 1
2 1
k k
k k
?
T = 2 ?
k
M
= 2 ?
2 1
2 1
k k
) k k ( m ?
?
M
F
k
M
(a)
parallel
k 2
k 1
x-1
k 2
m
k 1  
k 2
m
k 1
Read More
96 videos|388 docs|105 tests
Join Course for Free

Top Courses for NEET

FAQs on HC Verma Solutions: Chapter 12 - Simple Harmonics Motion - Physics Class 11 - NEET

1. What is simple harmonic motion?
Ans. Simple harmonic motion is a type of periodic motion where an object oscillates back and forth around a stable equilibrium position, with a restoring force proportional to its displacement. The motion follows a sinusoidal pattern and can be described by parameters such as amplitude, frequency, and period.
2. What is the formula for the time period of a simple harmonic motion?
Ans. The formula for the time period (T) of a simple harmonic motion is given by T = 2π√(m/k), where m represents the mass of the object undergoing the motion and k represents the spring constant or the stiffness of the restoring force.
3. How is the amplitude of a simple harmonic motion related to its energy?
Ans. The amplitude of a simple harmonic motion is directly proportional to its energy. As the amplitude increases, the maximum displacement of the object from its equilibrium position increases, resulting in higher potential energy and kinetic energy. Therefore, larger amplitudes correspond to greater energy in the system.
4. What is the relationship between the frequency and the period of a simple harmonic motion?
Ans. The frequency (f) and the period (T) of a simple harmonic motion are inversely related. The frequency is the number of oscillations or cycles completed per unit time, while the period is the time taken to complete one full oscillation or cycle. The formula relating frequency and period is f = 1/T or T = 1/f.
5. How does the mass of an object affect its period in simple harmonic motion?
Ans. The mass of an object does not affect its period in simple harmonic motion. The period depends solely on the stiffness of the restoring force (represented by the spring constant) and the mass does not play a role in determining the period. However, the mass does affect the amplitude of the motion, as objects with larger masses require more force to achieve the same displacement.
Related Exams
About this Document
2K Views
4.86/5 Rating
Nov 15, 2024 Last updated
Document Description: HC Verma Solutions: Chapter 12 - Simple Harmonics Motion for NEET 2024 is part of Physics Class 11 preparation. The notes and questions for HC Verma Solutions: Chapter 12 - Simple Harmonics Motion have been prepared according to the NEET exam syllabus. Information about HC Verma Solutions: Chapter 12 - Simple Harmonics Motion covers topics like and HC Verma Solutions: Chapter 12 - Simple Harmonics Motion Example, for NEET 2024 Exam. Find important definitions, questions, notes, meanings, examples, exercises and tests below for HC Verma Solutions: Chapter 12 - Simple Harmonics Motion.
Introduction of HC Verma Solutions: Chapter 12 - Simple Harmonics Motion in English is available as part of our Physics Class 11 for NEET & HC Verma Solutions: Chapter 12 - Simple Harmonics Motion in Hindi for Physics Class 11 course. Download more important topics related with notes, lectures and mock test series for NEET Exam by signing up for free. NEET: HC Verma Solutions: Chapter 12 - Simple Harmonics Motion | Physics Class 11 - NEET
Description
Full syllabus notes, lecture & questions for HC Verma Solutions: Chapter 12 - Simple Harmonics Motion | Physics Class 11 - NEET - NEET | Plus excerises question with solution to help you revise complete syllabus for Physics Class 11 | Best notes, free PDF download
Information about HC Verma Solutions: Chapter 12 - Simple Harmonics Motion
In this doc you can find the meaning of HC Verma Solutions: Chapter 12 - Simple Harmonics Motion defined & explained in the simplest way possible. Besides explaining types of HC Verma Solutions: Chapter 12 - Simple Harmonics Motion theory, EduRev gives you an ample number of questions to practice HC Verma Solutions: Chapter 12 - Simple Harmonics Motion tests, examples and also practice NEET tests
96 videos|388 docs|105 tests
Join Course for Free
Download as PDF
Explore Courses for NEET exam

Top Courses for NEET

Signup for Free!
Signup to see your scores go up within 7 days! Learn & Practice with 1000+ FREE Notes, Videos & Tests.
10M+ students study on EduRev
Related Searches

practice quizzes

,

Free

,

HC Verma Solutions: Chapter 12 - Simple Harmonics Motion | Physics Class 11 - NEET

,

shortcuts and tricks

,

HC Verma Solutions: Chapter 12 - Simple Harmonics Motion | Physics Class 11 - NEET

,

Summary

,

Exam

,

HC Verma Solutions: Chapter 12 - Simple Harmonics Motion | Physics Class 11 - NEET

,

Sample Paper

,

MCQs

,

past year papers

,

Semester Notes

,

Viva Questions

,

Extra Questions

,

ppt

,

video lectures

,

Objective type Questions

,

Important questions

,

Previous Year Questions with Solutions

,

study material

,

mock tests for examination

,

pdf

;
Additional Information about HC Verma Solutions: Chapter 12 - Simple Harmonics Motion for NEET Preparation

HC Verma Solutions: Chapter 12 - Simple Harmonics Motion Free PDF Download

The HC Verma Solutions: Chapter 12 - Simple Harmonics Motion is an invaluable resource that delves deep into the core of the NEET exam. These study notes are curated by experts and cover all the essential topics and concepts, making your preparation more efficient and effective. With the help of these notes, you can grasp complex subjects quickly, revise important points easily, and reinforce your understanding of key concepts. The study notes are presented in a concise and easy-to-understand manner, allowing you to optimize your learning process. Whether you're looking for best-recommended books, sample papers, study material, or toppers' notes, this PDF has got you covered. Download the HC Verma Solutions: Chapter 12 - Simple Harmonics Motion now and kickstart your journey towards success in the NEET exam.

Importance of HC Verma Solutions: Chapter 12 - Simple Harmonics Motion

The importance of HC Verma Solutions: Chapter 12 - Simple Harmonics Motion cannot be overstated, especially for NEET aspirants. This document holds the key to success in the NEET exam. It offers a detailed understanding of the concept, providing invaluable insights into the topic. By knowing the concepts well in advance, students can plan their preparation effectively. Utilize this indispensable guide for a well-rounded preparation and achieve your desired results.

HC Verma Solutions: Chapter 12 - Simple Harmonics Motion Notes

HC Verma Solutions: Chapter 12 - Simple Harmonics Motion Notes offer in-depth insights into the specific topic to help you master it with ease. This comprehensive document covers all aspects related to HC Verma Solutions: Chapter 12 - Simple Harmonics Motion. It includes detailed information about the exam syllabus, recommended books, and study materials for a well-rounded preparation. Practice papers and question papers enable you to assess your progress effectively. Additionally, the paper analysis provides valuable tips for tackling the exam strategically. Access to Toppers' notes gives you an edge in understanding complex concepts. Whether you're a beginner or aiming for advanced proficiency, HC Verma Solutions: Chapter 12 - Simple Harmonics Motion Notes on EduRev are your ultimate resource for success.

HC Verma Solutions: Chapter 12 - Simple Harmonics Motion NEET Questions

The "HC Verma Solutions: Chapter 12 - Simple Harmonics Motion NEET Questions" guide is a valuable resource for all aspiring students preparing for the NEET exam. It focuses on providing a wide range of practice questions to help students gauge their understanding of the exam topics. These questions cover the entire syllabus, ensuring comprehensive preparation. The guide includes previous years' question papers for students to familiarize themselves with the exam's format and difficulty level. Additionally, it offers subject-specific question banks, allowing students to focus on weak areas and improve their performance.

Study HC Verma Solutions: Chapter 12 - Simple Harmonics Motion on the App

Students of NEET can study HC Verma Solutions: Chapter 12 - Simple Harmonics Motion alongwith tests & analysis from the EduRev app, which will help them while preparing for their exam. Apart from the HC Verma Solutions: Chapter 12 - Simple Harmonics Motion, students can also utilize the EduRev App for other study materials such as previous year question papers, syllabus, important questions, etc. The EduRev App will make your learning easier as you can access it from anywhere you want. The content of HC Verma Solutions: Chapter 12 - Simple Harmonics Motion is prepared as per the latest NEET syllabus.
© EduRev
Education Revolution
Follow Us
Signup to see your scores go up within 7 days!
Access 1000+ FREE Docs, Videos and Tests
Takes less than 10 seconds to signup