A particle is in S.H.M. along a straight line 0.2 m long with a period of 6 s. Its displacement after `1/2` second, if its epoch is `((pi)/(6))^c`, will be

A particle is executing S.H.M. along a straight line. The graph showing the variation of kinetic, potential and total energy K, U and T respectively with displacement is -

A particle oscillates along a straight line 1m long, if it completes one oscillation in 0.1s, then the distance covered by it and its average speed in one oscillation is, A. 1m, 20 m / s B. 2m, 20 m / s C. 2m, 15 m / s D. 1m, 15 m / s

When a particle undergoes S.H.M., there is always a constant ratio between its displacement and

A particle is executing SHM along a straight line. Its velocities at distances x_(1) and x_(2) from the mean position are v_(1) and v_(2) , respectively. Its time period is

A particle performing SHM starts equilibrium position and its time period is 16 seconds. After 2 seconds its velocity is pi m//s . Amplitude of oscillation is (cos 45^(@) = 1/(sqrt(2)))

The equation of motion of a particle moving along a straight line is s=2t^(3)-9t^(2)+12t , where the units of s and t are cm and second. The acceleration of the particle will be zero after: a) 3/2 seconds b) 2/3 seconds c) 1/2 seconds d) 2 seconds

A particle is executing S.H.M. of amplitude 5 cm and period of 2 s. Find the speed of the particle at a point where its acceleration is half of its maximum value.

A particle is performing linear S.H.M. with frequency 1 Hz and amplitude 10 cm. Initially, the particle is at a distance +5 cm. Its epoch is

A particle of mass m executing S.H.M. about its mean position. The total energy of the particle at given instant is

A particle performs linear S.H.M. starting from the mean position. Its amplitude is A and time period is T. At the instance when its speed is half the maximum speed , its displacement x is