A 10 kg metal block is attached to a spring constant `1000 Nm^(-1)`. A block is displaced from equilibrium position by 10 cm and released. The maximum acceleration of the block is

A 10 kg metal block is attached to a spring of spring constant 1000 N m^(-1) . A block is displaced from equilibrium position by 10 cm and released. The maximum acceleration of the block is

A 2kg collar is attached to a spring of spring constant 800 Nm^(-1) . It slides without friction over a horizontal rod. The collar is displaced from its equilibrium position by 10.0 cm and released. Calculate maximum acceleration of the collar.

A 5-kg block rests on a smooth inclined plane of inclination 37^(@) as shown in the diagram if the extension of spring is 6cm, find (a) the spring constant (b). If the block is pulled dow the incline 4 cm from its equilibrium position and released, find the initial acceleration of the block.

An oscillator consists of a block attached to a spring of spring constant K=300 N/m. At some time t the position (measured from its equilibrium position), velocity and acceleration of the block are x=0.1 m, v= - 15 m//s " and " a= -90 m//s^(2) . What is the ampliof motion and the mass of the block ?

A 2.5 kg collar attached to a spring of foce constant 1000 Nm^(-1) slides without friction on a horizontal rod. The collar is displaced from its equilibrium position by 5.0 cm and released. Calculate (i) the period of oscillation (ii) the maximum speed of the collar and (iii) the maximum acceleration of the collar.

A 2.5 kg collar attached to a spring of foce constant 1000 Nm^(-1) slides without friction on a horizontal rod. The collar is displaced from its equilibrium position by 5.0 cm and released. Calculate (i) the period of oscillation (ii) the maximum speed of the collar and (iii) the maximum acceleration of the collar.

A mass 2kg is attached to the spring of spring constant 50 Nm^(-1) . The block is pulled to a distance of 5 cm from its equilibrium position at x= 0 on a horizontal frictionless surface from rest at t=0. Write the expression for its displacement at anytime t.