Acceleration -time graph of a particel executing `SHM` is as shown in fig. Then
(i) displacement of particle at `1` is -ve
(ii) velocity of particel at `2` is +ve
(iii) potential enegry of particel at `3` is maximum
(iv) speed of particel at `4` is decreasing.

The displacement - time graph of a particle executing SHM is as shown in the figure. The maximum velocity of the particle is

The acceleration-displacement graph of a particle executing SHM is as shown in the figure. The velocity of the particle at y = 0 is (take tan 14^(@) = 0.25)

The velocity-time graph of a particle executing SHM is as shown in the figure. The amplitude and maximum acceleration of the particle respectively are

Velocity -time graph of a particle executing SHM is as shown in fig. Select the ocrrect alternatives. (i) at position 1, displacement of particle may be +ve or-ve (ii) at position 2, displacement of particel is -ve (iii) at position 3, acceleration of particel is+v (iv) at position 4, acceleration of particle is +ve

The velocity time graph of a particle executing SHM is shown. The maximum acceleration of the particle is npi m//s^2 , where n is______.

The acceleration time graph of a particle is shown in the Fig. 2 (CF). 11. At time t= 10 s is the particle is 8 ms^(-1) . Its velocity t= 10 s is. .

Displacement versus time curve for a particle executing SHM is shown in figure. Identify the points marked at which (i) velocity of the oscillator is zero, (ii) speed of the oscillator is maximum.

A particle executing SHM has an acceleration of 0.5cms^(-1) when its displacement is 2 cm. find the time period.

In SHM at the equilibrium position (i) displacement is minimum (ii) acceleration is zero (iii) velocity is maximum (iv) potential energy is maximum