Two simple pendulums have time periods T and . They start vibrating at the same instant from the mean position in the same phase. The phase difference between them when bigger pendulum completes one oscillation will be:
1.
2.
3.
4.
There is a simple pendulum hanging from the ceiling of a lift. When the lift is stand still, the time period of the pendulum is T. If the resultant acceleration becomes g/4, then the new time period of the pendulum is
(1) 0.8 T
(2) 0.25 T
(3) 2 T
(4) 4 T
When two displacements represented by y1=asin(ωt) and y2=bcos(ωt) are superimposed,the motion is -
(1) not a simple harmonic
(2) simple harmonic with amplitude a/b
(3) simple harmonic with amplitude
(4) simple harmonic with amplitude (a+b)/2
A S.H.M. has amplitude ‘a’ and time period T. The maximum velocity will be -
(1)
(2)
(3)
(4)
Two particles P and Q start from origin and execute Simple Harmonic Motion along X-axis with same amplitude but with periods 3 seconds and 6 seconds respectively. The ratio of the velocities of P and Q when they meet is -
(1) 1 : 2
(2) 2 : 1
(3) 2 : 3
(4) 3 : 2
1. | \(A_1 \omega_1=A_2 \omega_2=A_3 \omega_3\) |
2. | \(A_1 \omega_1^2=A_2 \omega_2^2=A_3 \omega_3^2\) |
3. | \(A_1^2 \omega_1=A_2^2 \omega_2=A_3^2 \omega_3\) |
4. | \(A_1^2 \omega_1^2=A_2^2 \omega_2^2=A^2\) |
The amplitude of a particle executing SHM is 4 cm. At the mean position the speed of the particle is 16 cm/sec. The distance of the particle from the mean position at which the speed of the particle becomes
will be
(1)
(2)
(3) 1 cm
(4) 2 cm
The maximum velocity of a simple harmonic motion represented by is given by
(1) 300
(2)
(3) 100
(4)
The displacement equation of a particle is The amplitude and maximum velocity will be respectively
(a) 5, 10 (b) 3, 2
c) 4, 2 (d) 3, 4
The instantaneous displacement of a simple pendulum oscillator is given by . Its speed will be maximum at time
(1)
(2)
(3)
(4)