For the spring pendulum shown in fig. the value of spring constant is `3xx10^4(N)/(m)` and amplitude of oscillation is `0.1m`. The total mechanical energy of oscillating system is 200 J. Mark out the correct option (s).

A linear harmonic oscillator of force constant 2 xx 10^(6)N//m and amplitude 0.01 m has a total mechanical energy of 160 J . Its

A linear harmonic oscillator of force constant 2 xx 10^(6)N//m and amplitude 0.01 m has a total mechanical energy of 160 J . Its

A linear harmonic oscillator of force constant 2 xx 10^6 N//m and amplitude (0.01 m) has a total mechanical energy of (160 J). Its.

A linear harmonic oscillator of force constant 2 xx 10^6 N//m and amplitude (0.01 m) has a total mechanical energy of (160 J). Its.

A linear harmonic oscillator of force constant 2 xx 10^(6) N //m and amplitude 10 mm has a total mechanical energy is 160 J . Its

For the small damping oscillator, the mass of the block is 500 g and value of spring constant is k = 50 N/m and damping constant is 10 gs^(-1) The time period of oscillation is (approx.)

Force acting on a particle is F=-8x in S.H.M. The amplitude of oscillation is 2 (in m) and mass of the particle is 0.5 kg. The total mechanical energy of the particle is 20 J. Find the potential energy of the particle in mean position (in J).

A system of springs with their spring constants are as shown in figure. What is the frequency of oscillations of the mass m ?

A linear harmonic oscillator of force constant 6 xx 10^(5) N/m and amplitude 4cm, has a total energy 600J. Select the correct statement.

A block of mass m is connected to a spring of spring constant k as shown in Fig. The block is found at its equilibrium position t=1s and it has a velocity of +0.25(m)/(s) at t=2s . The time period of oscillation is 6 s. Based on the given information answer the following question: Q. the amplitude of oscillation is