A particle of mass 0.1 kg is held between two rigid supports by two springs of force constant `8 N m^(-1) and 2 N m^(-1)`. If the particle is displaced along the direction of length of the springs, its frequency of vibration is

A body of mass 0.4 kg is held between two massless springs whose ends are fixed to rigid walls as shown in the figure. The spring constants are 8 N/m and 2 N/m. If the body is displaced along the direction of the lengths of the springs and released, the time period (in second) of the oscillations will be (ignore vertical oscillation, if any )

Two springs of spring constants 1000 N m^(-1) and 2000 N m^(-1) are stretched with same force. They will have potential energy in the ratio of

A mass M is suspended by two springs of force constants K_(1) and K_(2) respectively as shown in the diagram. The total elongation (stretch) of the two springs is

A body of mass 16 kg is made to oscillate on a spring of force constant 100 N kg^(-1) . Deduce the angular frequency.

A body of mass 0.1 g moving with a velocity of 10 m/s hits a spring (fixed at the other end) of force constant 1000 N/m and comes to rest after compressing the spring. The compression of the spring is

A body of mass 1 kg oscillates on a spring of force constant 16 N/m. Calculate the angular frequency.

Two spring of spring constants k_(1) and k_(2) ar joined and are connected to a mass m as shown in the figure. Calculate the frequency of oscillation of mass m.