Simple Harmonic Motion
181 Questions
2021
JEE Mains
MCQ
JEE Main 2021 (Online) 25th February Evening Shift
Y = A sin($\omega$t + $\phi$0) is the time-displacement equation of a SHM. At t = 0 the displacement of the particle is $Y = {A \over 2}$ and it is moving along negative x-direction. Then the initial phase angle $\phi$0 will be:
A.
${{5\pi } \over 6}$
B.
${{\pi } \over 3}$
C.
${{2\pi } \over 3}$
D.
${{\pi } \over 6}$
2021
JEE Mains
MCQ
JEE Main 2021 (Online) 25th February Evening Shift
Two identical springs of spring constant '2k' are attached to a block of mass m and to fixed support (see figure). When the mass is displaced from equilibrium position on either side, it executes simple harmonic motion. The time period of oscillations of this system is :
A.
$2\pi \sqrt {{m \over k}} $
B.
$\pi \sqrt {{m \over k}} $
C.
$2\pi \sqrt {{m \over {2k}}} $
D.
$\pi \sqrt {{m \over {2k}}} $
2021
JEE Mains
MCQ
JEE Main 2021 (Online) 25th February Evening Shift
The point A moves with a uniform speed along the circumference of a circle of radius 0.36 m and covers 30$^\circ$ in 0.1 s. The perpendicular projection 'P' from 'A' on the diameter MN represents the simple harmonic motion of 'P'. The restoration force per unit mass when P touches M will be :
A.
9.87 N
B.
0.49 N
C.
50 N
D.
100 N
2021
JEE Mains
MCQ
JEE Main 2021 (Online) 25th February Morning Shift
If the time period of a two meter long simple pendulum is 2s, the acceleration due to gravity at the place where pendulum is executing S.H.M. is :
A.
16 m/s2
B.
2$\pi$2 ms$-$2
C.
$\pi$2 ms$-$2
D.
9.8 ms$-$2
2021
JEE Mains
MCQ
JEE Main 2021 (Online) 24th February Evening Shift
In the given figure, a body of mass M is held between two massless springs, on a smooth inclined plane. The free ends of the springs are attached to firm supports. If each spring has spring constant k, the frequency of oscillation of given body is :
A.
${1 \over {2\pi }}\sqrt {{{2k} \over {Mg\sin \alpha }}} $
B.
${1 \over {2\pi }}\sqrt {{k \over {Mg\sin \alpha }}} $
C.
${1 \over {2\pi }}\sqrt {{{2k} \over M}} $
D.
${1 \over {2\pi }}\sqrt {{k \over {2M}}} $
2021
JEE Mains
MCQ
JEE Main 2021 (Online) 24th February Evening Shift
When a particle executes SHM, the nature of graphical representation of velocity as a function of displacement is :
A.
circular
B.
straight line
C.
parabolic
D.
elliptical
2021
JEE Mains
MCQ
JEE Main 2021 (Online) 24th February Evening Shift
The period of oscillation of a simple pendulum is $T = 2\pi \sqrt {{L \over g}} $. Measured value of 'L' is 1.0 m from meter scale having a minimum division of 1 mm and time of one complete oscillation is 1.95 s measured from stopwatch of 0.01 s resolution. The percentage error in the determination of 'g' will be :
A.
1.30%
B.
1.33%
C.
1.13%
D.
1.03%
2021
JEE Mains
MCQ
JEE Main 2021 (Online) 24th February Morning Shift
In the given figure, a mass M is attached to a horizontal spring which is fixed on one side to a rigid support. The spring constant of the spring is k. The mass oscillates on a frictionless surface with time period T and amplitude A. When the mass is in equilibrium position, as shown in the figure, another mass m is gently fixed upon it. The new amplitude of oscillations will be :
A.
$A\sqrt {{M \over {M - m}}} $
B.
$A\sqrt {{{M - m} \over M}} $
C.
$A\sqrt {{{M + m} \over M}} $
D.
$A\sqrt {{M \over {M + m}}} $
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 31st August Morning Shift
A particle of mass 1 kg is hanging from a spring of force constant 100 Nm$-$1. The mass is pulled slightly downward and released so that it executes free simple harmonic motion with time period T. The time when the kinetic energy and potential energy of the system will become equal, is ${T \over x}$. The value of x is _____________.
Correct Answer: 8
Explanation:
KE = PE
$y = {A \over {\sqrt 2 }} = A\sin \omega t$
$t = {T \over 8} = {T \over x}$
x = 8
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 27th August Evening Shift
Two simple harmonic motion, are represented by the equations ${y_1} = 10\sin \left( {3\pi t + {\pi \over 3}} \right)$ ${y_2} = 5(\sin 3\pi t + \sqrt 3 \cos 3\pi t)$ Ratio of amplitude of y1 to y2 = x : 1. The value of x is ______________.
Correct Answer: 1
Explanation:
${y_1} = 10\sin \left( {3\pi t + {\pi \over 3}} \right)$ $\Rightarrow$ Amplitude = 10
${y_2} = 5(\sin 3\pi t + \sqrt 3 \cos 3\pi t)$
${y_2} = 10\left( {{1 \over 2}\sin 3\pi t + {{\sqrt 3 } \over 2}\cos 3\pi t} \right)$
${y_2} = 10\left( {\cos {\pi \over 3}\sin 3\pi t + \sin {\pi \over 3}\cos 3\pi t} \right)$
${y_2} = 10\left( {3\pi t + {\pi \over 3}} \right)$ $\Rightarrow$ Amplitude = 10
So ratio of amplitudes = ${{10} \over {10}}$ = 1
${y_2} = 5(\sin 3\pi t + \sqrt 3 \cos 3\pi t)$
${y_2} = 10\left( {{1 \over 2}\sin 3\pi t + {{\sqrt 3 } \over 2}\cos 3\pi t} \right)$
${y_2} = 10\left( {\cos {\pi \over 3}\sin 3\pi t + \sin {\pi \over 3}\cos 3\pi t} \right)$
${y_2} = 10\left( {3\pi t + {\pi \over 3}} \right)$ $\Rightarrow$ Amplitude = 10
So ratio of amplitudes = ${{10} \over {10}}$ = 1
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 26th August Evening Shift
Two simple harmonic motions are represented by the equations
${x_1} = 5\sin \left( {2\pi t + {\pi \over 4}} \right)$ and ${x_2} = 5\sqrt 2 (\sin 2\pi t + \cos 2\pi t)$. The amplitude of second motion is ................ times the amplitude in first motion.
${x_1} = 5\sin \left( {2\pi t + {\pi \over 4}} \right)$ and ${x_2} = 5\sqrt 2 (\sin 2\pi t + \cos 2\pi t)$. The amplitude of second motion is ................ times the amplitude in first motion.
Correct Answer: 2
Explanation:
${x_2} = 5\sqrt 2 \left( {{1 \over {\sqrt 2 }}\sin 2\pi t + {1 \over {\sqrt 2 }}\cos 2\pi t} \right)\sqrt 2 $
$ = 10\sin \left( {2\pi t + {\pi \over 4}} \right)$
$\therefore$ ${{{A_2}} \over {{A_1}}} = {{10} \over 5} = 2$
$ = 10\sin \left( {2\pi t + {\pi \over 4}} \right)$
$\therefore$ ${{{A_2}} \over {{A_1}}} = {{10} \over 5} = 2$
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 27th July Evening Shift
A particle executes simple harmonic motion represented by displacement function as
x(t) = A sin($\omega$t + $\phi$)
If the position and velocity of the particle at t = 0 s are 2 cm and 2$\omega$ cm s$-$1 respectively, then its amplitude is $x\sqrt 2 $ cm where the value of x is _________________.
x(t) = A sin($\omega$t + $\phi$)
If the position and velocity of the particle at t = 0 s are 2 cm and 2$\omega$ cm s$-$1 respectively, then its amplitude is $x\sqrt 2 $ cm where the value of x is _________________.
Correct Answer: 2
Explanation:
x(t) = A sin($\omega$t + $\phi$)
v(t) = A$\omega$ cos ($\omega$t + $\phi$)
2 = A sin$\phi$ ...... (1)
2$\omega$ = A$\omega$ cos$\phi$ ....... (2)
From (1) and (2)
tan$\phi$ = 1
$\phi$ = 45$^\circ$
Putting value of $\phi$ in equation (1),
$2 = A\left\{ {{1 \over {\sqrt 2 }}} \right\}$
$A = 2\sqrt 2 $
$ \therefore $ x = 2
v(t) = A$\omega$ cos ($\omega$t + $\phi$)
2 = A sin$\phi$ ...... (1)
2$\omega$ = A$\omega$ cos$\phi$ ....... (2)
From (1) and (2)
tan$\phi$ = 1
$\phi$ = 45$^\circ$
Putting value of $\phi$ in equation (1),
$2 = A\left\{ {{1 \over {\sqrt 2 }}} \right\}$
$A = 2\sqrt 2 $
$ \therefore $ x = 2
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 25th July Morning Shift
In the reported figure, two bodies A and B of masses 200 g and 800 g are attached with the system of springs. Springs are kept in a stretched position with some extension when the system is released. The horizontal surface is assumed to be frictionless. The angular frequency will be ____________ rad/s when k = 20 N/m.
Correct Answer: 10
Explanation:
$\omega = \sqrt {{{{k_{eq}}} \over \mu }} $
$\mu$ = reduced mass
springs are in series connection
${k_{eq}} = {{{k_1}{k_2}} \over {{k_1} + {k_2}}}$
${k_{eq}} = {{k \times 4k} \over {5k}} = {{4k} \over 5}$
${k_{eq}} = {{4 \times 20} \over 5}$ N/m = 16 N/m
$\mu = {{{m_1}{m_2}} \over {{m_1} + {m_2}}} = {{0.2 \times 0.8} \over {0.2 + 0.8}} = 0.16$ kg
$\omega = \sqrt {{{16} \over {0.16}}} = \sqrt {100} = 10$
$\mu$ = reduced mass
springs are in series connection
${k_{eq}} = {{{k_1}{k_2}} \over {{k_1} + {k_2}}}$
${k_{eq}} = {{k \times 4k} \over {5k}} = {{4k} \over 5}$
${k_{eq}} = {{4 \times 20} \over 5}$ N/m = 16 N/m
$\mu = {{{m_1}{m_2}} \over {{m_1} + {m_2}}} = {{0.2 \times 0.8} \over {0.2 + 0.8}} = 0.16$ kg
$\omega = \sqrt {{{16} \over {0.16}}} = \sqrt {100} = 10$
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 25th July Morning Shift
A pendulum bob has a speed of 3 m/s at its lowest position. The pendulum is 50 cm long. The speed of bob, when the length makes an angle of 60$^\circ$ to the vertical will be (g = 10 m/s2) ____________ m/s.
Correct Answer: 2
Explanation:
Applying work energy theorem :
wg + wT = $\Delta$K
$-$mgl(1 $-$ cos60$^\circ$) = ${1 \over 2}$mv2 $-$ ${1 \over 2}$mu2
v2 = u2 $-$ 2gl(1 $-$ cos60$^\circ$)
v2 = 9 $-$ 2 $\times$ 10 $\times$ 0.5$\left( {{1 \over 2}} \right)$
v2 = 4
v = 2 m/s
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 18th March Morning Shift
A particle performs simple harmonic motion with a period of 2 second. The time taken by the particle to cover a displacement equal to half of its amplitude from the mean position is ${1 \over a}$s. The value of 'a' to the nearest integer is _________.
Correct Answer: 6
Explanation:
Time period (T) = 2 sec.
X = A sin ($\omega$t + $\phi$) ($\phi$ = 0 at M.P.)
$ \Rightarrow $ ${A \over 2} = A\sin {{2\pi } \over T}t$
$ \Rightarrow $ ${{2\pi } \over 2}t = {\pi \over 6}$
$ \Rightarrow $ $t = {1 \over 6}$
$ \therefore $ a = 6
X = A sin ($\omega$t + $\phi$) ($\phi$ = 0 at M.P.)
$ \Rightarrow $ ${A \over 2} = A\sin {{2\pi } \over T}t$
$ \Rightarrow $ ${{2\pi } \over 2}t = {\pi \over 6}$
$ \Rightarrow $ $t = {1 \over 6}$
$ \therefore $ a = 6
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 17th March Morning Shift
Consider two identical springs each of spring constant k and negligible mass compared to the mass M as shown. Fig. 1 shows one of them and Fig. 2 shows their series combination. The ratios of time period of oscillation of the two SHM is Tb/Ta = $\sqrt x $, where value of x is ___________. (Round off to the Nearest Integer)
Correct Answer: 2
Explanation:
${T_a} = 2\pi \sqrt {{M \over k}} $
${K_{e{q_{series}}}} = {{{k_1}{k_2}} \over {{k_1} + {k_2}}} = {k \over 2}$
${T_b} = 2\pi \sqrt {{M \over {k/2}}} = 2\pi \sqrt {{{2M} \over k}} $
${T_b} = \sqrt 2 {T_a}$
${{{T_b}} \over {{T_a}}} = \sqrt 2 $
$ \therefore $ x = 2
${K_{e{q_{series}}}} = {{{k_1}{k_2}} \over {{k_1} + {k_2}}} = {k \over 2}$
${T_b} = 2\pi \sqrt {{M \over {k/2}}} = 2\pi \sqrt {{{2M} \over k}} $
${T_b} = \sqrt 2 {T_a}$
${{{T_b}} \over {{T_a}}} = \sqrt 2 $
$ \therefore $ x = 2
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 26th February Evening Shift
A particle executes S.H.M. with amplitude 'a', and time period 'T'. The displacement of the particle when its speed is half of maximum speed is ${{\sqrt x a} \over 2}$. The value of x is __________.
Correct Answer: 3
Explanation:
For a particle executes S.H.M.
$V = \omega \sqrt {{a^2} - {x^2}} $
Given, $V = {{{V_{\max }}} \over 2} = {{A\omega } \over 2}$
${{{A^2}{\omega ^2}} \over 4} = {\omega ^2}{a^2} - {\omega ^2}{x^2}$
$x = {{\sqrt 3 } \over 2}a$
$V = \omega \sqrt {{a^2} - {x^2}} $
Given, $V = {{{V_{\max }}} \over 2} = {{A\omega } \over 2}$
${{{A^2}{\omega ^2}} \over 4} = {\omega ^2}{a^2} - {\omega ^2}{x^2}$
$x = {{\sqrt 3 } \over 2}a$
2021
JEE Mains
Numerical
JEE Main 2021 (Online) 26th February Evening Shift
Time period of a simple pendulum is T. The time taken to complete ${5 \over 8}$ oscillations starting from mean position is ${\alpha \over \beta }T$. The value of $\alpha$ is _________.
Correct Answer: 7
Explanation:
${5 \over 8}$ oscillation = ${1 \over 2}$ oscillation + ${1 \over 8}$ oscillation
From figure, A to B = ${1 \over 2}$ oscillation and B to C is ${1 \over 8}$ oscillation.
$ \therefore $ $\pi { + \,\theta = \omega t} $
$ \Rightarrow $ $\pi { + {{\pi{} } \over 6}} = \omega t$
$ \Rightarrow $ ${{7\pi {} } \over 6} = \left( {{{2\pi {} } \over T}} \right)t$
$ \Rightarrow $ t = ${{7T} \over {12}}$
2020
JEE Mains
MCQ
JEE Main 2020 (Online) 6th September Evening Slot
When a particle of mass m is attached to a vertical spring of spring constant k and released, its
motion is described by
y(t) = y0 sin2 $\omega $t, where 'y' is measured from the lower end of unstretched spring. Then $\omega $ is:
y(t) = y0 sin2 $\omega $t, where 'y' is measured from the lower end of unstretched spring. Then $\omega $ is:
A.
$\sqrt {{g \over {{y_0}}}} $
B.
${1 \over 2}\sqrt {{g \over {{y_0}}}} $
C.
$\sqrt {{{2g} \over {{y_0}}}} $
D.
$\sqrt {{g \over {2{y_0}}}} $
2020
JEE Mains
MCQ
JEE Main 2020 (Online) 3rd September Evening Slot
A block of mass m attached to a massless spring is performing oscillatory motion of amplitude ‘A’ on
a frictionless horizontal plane. If half of the mass of the block breaks off when it is passing through
its equilibrium point, the amplitude of oscillation for the remaining system become fA. The value of
f is :
A.
1
B.
${1 \over 2}$
C.
$\sqrt 2 $
D.
${1 \over {\sqrt 2 }}$
2020
JEE Mains
MCQ
JEE Main 2020 (Online) 2nd September Evening Slot
The displacement time graph of a particle
executing S.H.M is given in figure :
(sketch is schematic and not to scale)
Which of the following statements is/are true for this motion?
(A) The force is zero at t = ${{3T} \over 4}$
(B) The acceleration is maximum at t = T
(C) The speed is maximum at t = ${{T} \over 4}$
(D) The P.E. is equal to K.E. of the oscillation at t = ${{T} \over 2}$
(sketch is schematic and not to scale)
Which of the following statements is/are true for this motion?
(A) The force is zero at t = ${{3T} \over 4}$
(B) The acceleration is maximum at t = T
(C) The speed is maximum at t = ${{T} \over 4}$
(D) The P.E. is equal to K.E. of the oscillation at t = ${{T} \over 2}$
A.
(B), (C) and (D)
B.
(A), (B) and (C)
C.
(A) and (D)
D.
(A), (B) and (D)
2020
JEE Mains
MCQ
JEE Main 2020 (Online) 9th January Evening Slot
A spring mass system (mass m, spring
constant k and natural length $l$) rest in
equilibrium on a horizontal disc. The free end
of the spring is fixed at the centre of the disc.
If the disc together with spring mass system,
rotates about it's axis with an angular velocity
$\omega $, (k $ \gg m{\omega ^2}$) the relative change in the length
of the spring is best given by the option :
A.
${{m{\omega ^2}} \over {3k}}$
B.
${{m{\omega ^2}} \over k}$
C.
${{2m{\omega ^2}} \over k}$
D.
$\sqrt {{2 \over 3}} \left( {{{m{\omega ^2}} \over k}} \right)$
2020
JEE Mains
MCQ
JEE Main 2020 (Online) 8th January Evening Slot
A simple pendulum is being used to determine
th value of gravitational acceleration g at a
certain place. Th length of the pendulum is
25.0 cm and a stop watch with 1s resolution
measures the time taken for 40 oscillations to
be 50 s. The accuracy in g is :
A.
4.40%
B.
3.40%
C.
2.40%
D.
5.40%
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 10th April Morning Slot
The displacement of a damped harmonic
oscillator is given by
x(t ) = e–0.1t cos (10$\pi $t + f).
Here t is in seconds. The time taken for its amplitude of vibration to drop to half of its initial value is close to :
x(t ) = e–0.1t cos (10$\pi $t + f).
Here t is in seconds. The time taken for its amplitude of vibration to drop to half of its initial value is close to :
A.
27 s
B.
13 s
C.
7 s
D.
4 s
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 8th April Evening Slot
A damped harmonic oscillator has a frequency
of 5 oscillations per second. The amplitude
drops to half its value for every 10 oscillations.
The time it will take to drop to
1/1000 of the original amplitude is close to :-
A.
100 s
B.
10 s
C.
20 s
D.
50 s
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 12th January Evening Slot
A simple harmonic motion is represented by :
y = 5 (sin 3 $\pi $ t + $\sqrt 3 $ cos 3 $\pi $t) cm
The amplitude and time period of the motion are :
y = 5 (sin 3 $\pi $ t + $\sqrt 3 $ cos 3 $\pi $t) cm
The amplitude and time period of the motion are :
A.
10 cm, ${3 \over 2}$ s
B.
5 cm, ${2 \over 3}$ s
C.
5 cm, ${3 \over 2}$ s
D.
10 cm, ${2 \over 3}$ s
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 12th January Morning Slot
Two light identical springs of spring constant k are attached horizontally at the two ends of a uniform horizontal rod AB of length $\ell $ and mass m. The rod is pivoted at its centre 'O' and can rotate freely in horizontal plane. The other ends of the two springs are fixed to rigid supports as shown in figure. The rod is gently pushed through a small angle and released. The frequency of resulting oscillation is :
A.
${1 \over {2\pi }}\sqrt {{{3k} \over m}} $
B.
${1 \over {2\pi }}\sqrt {{{6k} \over m}} $
C.
${1 \over {2\pi }}\sqrt {{k \over m}} $
D.
${1 \over {2\pi }}\sqrt {{{2k} \over m}} $
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 11th January Evening Slot
A pendulum is executing simple harmonic motion and its maximum kinetic energy is K1. If the length of the pendulum is doubled and it performs simple harmonic motion with the same amplitude as in the first case, its maximum kinetic energy is K2. Then :
A.
${K_2}$ = ${{{K_1}} \over 2}$
B.
K2 = 2K1
C.
K2 = K1
D.
K2 = ${{{K_1}} \over 4}$
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 11th January Evening Slot
The mass and the diameter of a planet are three times the respective values for the Earth. The period of oscillation of simple pendulum on the Earth is 2 s. The period of oscillation of the same pendulum on the planet would be :
A.
${{\sqrt 3 } \over 2}$ s
B.
${3 \over 2}$ s
C.
${2 \over {\sqrt 3 }}$ s
D.
$2\sqrt 3 $ s
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 11th January Evening Slot
A simple pendulum of length 1 m is oscillating with an angular frequency 10 rad/s. The support of the pendulum starts oscillating up and down with a small angular frequency of 1 rad/s and an amplitude of 10–2 m. The relative change in the angular frequency of the pendulum is best given by :
A.
1 rad/s
B.
10$-$3 rad/s
C.
10$-$1 rad/s
D.
10$-$5 rad/s
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 11th January Morning Slot
A particle undergoing simple harmonic motion has time dependent displacement given by x(t) = Asin${{\pi t} \over {90}}$. The ratio of kinetic to potential energy of this particle at t = 210 s will be:
A.
${1 \over 9}$
B.
3
C.
2
D.
1
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 10th January Evening Slot
A particle executes simple harmonic motion with an amplitude of 5 cm. When the particle is at 4 cm from the mean position, the magnitude of its velocity in SI units is equal to that of its acceleration. Then, its periodic time in seconds is -
A.
${{4\pi } \over 3}$
B.
${3 \over 8}\pi $
C.
${7 \over 3}\pi $
D.
${{8\pi } \over 3}$
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 10th January Evening Slot
A closed organ pipe has a fundamental frequency of 1.5 kHz. The number of overtones that can be distinctly heard by a person with this organ pipe will be (Assume that the highest frequency a person can hear is 20,000 Hz)
A.
4
B.
7
C.
6
D.
5
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 10th January Evening Slot
A cylindrical plastic bottle of negligible mass is filled with 310 ml of water and left floating in a pond with still water. If pressed downward slightly and released, it starts performing simple harmonic motion at angular frequency $\omega $. If the radius of the bottle is 2.5 cm then $\omega $ is close to – (density of water = 103 kg/m3).
A.
2.50 rad s$-$1
B.
3.75 rad s$-$1
C.
5.00 rad s$-$1
D.
7.90 rad s$-$1
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 9th January Evening Slot
A rod of mass 'M' and length '2L' is suspended at its middle by a wire. It exhibits torsional oscillations; If two masses each of 'm' are attached at distance 'L/2' from its centre on both sides, it reduces the oscillation frequency by 20%. The value of radio m/M is close to :
A.
0.77
B.
0.57
C.
0.37
D.
0.17
2019
JEE Mains
MCQ
JEE Main 2019 (Online) 9th January Evening Slot
A particle is executing simple harmonic motion (SHM) of amplitude A, along the x-axis, about x = 0. When its potential Energy (PE) equals kinetic energy (KE), the position of the particle will be :
A.
${A \over 2}$
B.
${A \over {2\sqrt 2 }}$
C.
${A \over {\sqrt 2 }}$
D.
A
2018
JEE Mains
MCQ
JEE Main 2018 (Online) 16th April Morning Slot
An oscillator of mass M is at rest in its equilibrium position in a potential
V = ${1 \over 2}$ k(x $-$ X)2. A particle of mass m comes from right with speed u and collides completely inelastically with M and sticks to it. This process repeats every time the oscillator crosses its equilibrium position. The amplitude of oscillations after 13 collisions is : (M = 10, m = 5, u = 1, k = 1)
V = ${1 \over 2}$ k(x $-$ X)2. A particle of mass m comes from right with speed u and collides completely inelastically with M and sticks to it. This process repeats every time the oscillator crosses its equilibrium position. The amplitude of oscillations after 13 collisions is : (M = 10, m = 5, u = 1, k = 1)
A.
${1 \over {\sqrt 3 }}$
B.
${1 \over 2}$
C.
${2 \over 3}$
D.
${3 \over {\sqrt 5 }}$
2018
JEE Mains
MCQ
JEE Main 2018 (Online) 16th April Morning Slot
A particle executes simple harmonic motion and is located at x = a, b and c at times t0, 2t0 and 3t0 respectively. The freqquency of the oscillation is :
A.
${1 \over {2\,\pi \,{t_0}}}{\cos ^{ - 1}}\left( {{{a + c} \over {2b}}} \right)$
B.
${1 \over {2\,\pi \,{t_0}}}{\cos ^{ - 1}}\left( {{{a + b} \over {2c}}} \right)$
C.
${1 \over {2\,\pi \,{t_0}}}{\cos ^{ - 1}}\left( {{{2a + 3c} \over b}} \right)$
D.
${1 \over {2\,\pi \,{t_0}}}{\cos ^{ - 1}}\left( {{{a + 2b} \over {3c}}} \right)$
2018
JEE Mains
MCQ
JEE Main 2018 (Offline)
A silver atom in a solid oscillates in simple harmonic motion in some direction with a frequency of 1012/sec. What is the force constant of the bonds connecting one atom with the other? (Mole wt. of silver = 108 and Avogadro number = 6.02 × 1023 gm mole–1)
A.
5.5 N/m
B.
6.4 N/m
C.
7.1 N/m
D.
2.2 N/m
2018
JEE Mains
MCQ
JEE Main 2018 (Online) 15th April Evening Slot
Two simple harmonic motions, as shown below, are at right angles. They are combined to form Lissajous figures.
x(t) = A sin (at + $\delta $)
y(t) = B sin (bt)
Identify the correct match below.
x(t) = A sin (at + $\delta $)
y(t) = B sin (bt)
Identify the correct match below.
A.
Parameters A $ \ne $ B, a = b; $\delta $ = 0;
Curve Parabola
Curve Parabola
B.
Parameters A = B, a = b; $\delta $ = ${\raise0.5ex\hbox{$\scriptstyle \pi $}
\kern-0.1em/\kern-0.15em
\lower0.25ex\hbox{$\scriptstyle 2$}}$
Curve Line
Curve Line
C.
Parameters A $ \ne $ B, a = b; $\delta $ = ${\raise0.5ex\hbox{$\scriptstyle \pi $}
\kern-0.1em/\kern-0.15em
\lower0.25ex\hbox{$\scriptstyle 2$}}$
Curve Ellipse
Curve Ellipse
D.
Parameters A = B, a = 2b; $\delta $ = ${\raise0.5ex\hbox{$\scriptstyle \pi $}
\kern-0.1em/\kern-0.15em
\lower0.25ex\hbox{$\scriptstyle 2$}}$
Curve Circle
Curve Circle
2017
JEE Mains
MCQ
JEE Main 2017 (Online) 9th April Morning Slot
A block of mass 0.1 kg is connected to an elastic spring of spring constant 640 Nm−1 and oscillates in a damping medium of damping constant 10−2 kg s−1 . The system dissipates its energy gradually. The time taken for its mechanical energy of vibration to drop to half of its initial value, is closest to :
A.
2 s
B.
3.5 s
C.
5 s
D.
7 s
2017
JEE Mains
MCQ
JEE Main 2017 (Online) 8th April Morning Slot
The ratio of maximum acceleration to maximum velocity in a simple harmonic motion is 10 s−1 . At, t = 0 the displacement is 5 m. What is the maximum acceleration ? The initial phase is ${\pi \over 4}$.
A.
500 m/s2
B.
500 $\sqrt 2 m/$ s2
C.
750 m/s2
D.
750 $\sqrt 2 $m / s2
2017
JEE Mains
MCQ
JEE Main 2017 (Online) 8th April Morning Slot
A 1 kg block attached to a spring vibrates with a frequency of 1 Hz on a frictionless horizontal table. Two springs identical to the original spring are attached in parallel to an 8 kg block placed on the same table. So, the frequency of vibration of the 8 kg block is :
A.
${1 \over 4}Hz$
B.
${1 \over {2\sqrt 2 }}Hz$
C.
${1 \over 2}Hz$
D.
$2$ $Hz$
2017
JEE Mains
MCQ
JEE Main 2017 (Offline)
A particle is executing simple harmonic motion with a time period T. At time t = 0, it is at its position of
equilibrium. The kinetic energy – time graph of the particle will look like:
A.
B.
C.
D.
2016
JEE Mains
MCQ
JEE Main 2016 (Online) 10th April Morning Slot
In an engine the piston undergoes vertical simple harmonic motion with amplitude 7 cm. A washer rests on top of the piston and moves with it. The motor speed is slowly increased. The frequency of the piston at which the washer no longer stays in contact with the piston, is close to :
A.
0.1 Hz
B.
1.2 Hz
C.
0.7 Hz
D.
1.9 Hz
2016
JEE Mains
MCQ
JEE Main 2016 (Online) 9th April Morning Slot
Two particles are performing simple harmonic motion in a straight line about
the same equilibrium point. The amplitude and time period for both particles are same and equal to A and I, respectively. At time t = 0 one particle has
displacement A while the other one has displacement ${{ - A} \over 2}$ and they are moving towards each other. If they cross each other at time t, then t is :
A.
${T \over 6}$
B.
${5T \over 6}$
C.
${T \over 3}$
D.
${T \over 4}$
2016
JEE Mains
MCQ
JEE Main 2016 (Offline)
A particle performs simple harmonic motion with amplitude $A.$ Its speed is trebled at the instant that it is at a distance ${{2A} \over 3}$ from equilibrium position. The new amplitude of the motion is:
A.
$A\sqrt 3 $
B.
${{7A} \over 3}$
C.
${A \over 3}\sqrt {41} $
D.
$3A$
2015
JEE Mains
MCQ
JEE Main 2015 (Offline)
The period of oscillation of a simple pendulum is $T = 2\pi \sqrt {{L \over g}} $. Measured value of L is 20.0 cm known to 1 mm accuracy and time for 100 oscillations of the pendulum is found to be 90 s using wrist watch of 1 s resolution. The accuracy in the determination of g is:
A.
1 %
B.
5 %
C.
2 %
D.
3 %
2015
JEE Mains
MCQ
JEE Main 2015 (Offline)
A pendulum made of a uniform wire of cross sectional area $A$ has time period $T.$ When an additional mass $M$ is added to its bob, the time period changes to ${T_{M.}}$ If the Young's modulus of the material of the wire is $Y$ then ${1 \over Y}$ is equal to :
($g=$ $gravitational$ $acceleration$)
($g=$ $gravitational$ $acceleration$)
A.
$\left[ {1 - {{\left( {{{{T_M}} \over T}} \right)}^2}} \right]{A \over {Mg}}$
B.
$\left[ {1 - {{\left( {{T \over {{T_M}}}} \right)}^2}} \right]{A \over {Mg}}$
C.
$\left[ {{{\left( {{{{T_M}} \over T}} \right)}^2} - 1} \right]{A \over {Mg}}$
D.
$\left[ {{{\left( {{{{T_M}} \over T}} \right)}^2} - 1} \right]{{Mg} \over A}$
2015
JEE Mains
MCQ
JEE Main 2015 (Offline)
For a simple pendulum, a graph is plotted between its kinetic energy $(KE)$ and potential energy $(PE)$ against its displacement $d.$ Which one of the following represents these correctly?
$(graphs$ $are$ $schematic$ $and$ $not$ $drawn$ $to$ $scale)$
$(graphs$ $are$ $schematic$ $and$ $not$ $drawn$ $to$ $scale)$
A.
B.
C.
D.
