In the figure shown surface is frictionless and spring is in natural condition. If `x_(1), x_(2) " and " x_(3)` are the maximum compression in spring for elastic, completely inelastic and inelastic (e=0.5) respectively then :

The spring constant of the spring shown in the figure is 250Nm^(-1) . Find the maximum compression of the spring?

The mass in the figure can slide on a frictionless surface. When the mass is pulled out, spring 1 is stretched a distance x_(1) and spring 2 is stretched a distance x_(2). The spring constants are k_(1) and k_(2) respectively. Magnitude of spring force pulling back on the mass is

Consider three cases, same spring is attached with 2kg , 3kg and 1kg blocks as shown in figure. If x_(1) , x_(2) , x_(3) be the extensions in the spring in the three cases, then.

In the figure shown, all surfaces are smooth and force constant of spring is 10N//m . Block of mass (2 kg) is attaced with the spring. The spring is compressed by (2m) and then released. Find the maximum distance d travelled by the block over the inclined plane. Take g=10m//s^(2) . .

A block of mass m initially at rest is dropped from a height h on to a spring of force constant k . the maximum compression in the spring is x then

A system of wedge and block as shown in figure, is released with the spring in its natural length. All surfaces are frictionless. Maximum elongation in the spring will be .

Two blocks 1 and 2 of masses m and 2m respectively are connected by a spring of force constant k. The masses are moving to the right with uniform velocity v each, the heavier mass, leading the lighter one. The spring is of natural length in the motion. Block 2 collides head on with a third block 3 of mass m, at rest, the collision being completely inelastic. Determine the velocity of blocks at the instant of maximum compression of the spring.

A block of mass m = 25 kg on a smooth horizontal surface with a velocity vec v = 3 ms^(-1) meets the spring of spring constant k = 100 N//m fixed at one end as shown in figure. The maximum compression of the spring and velocity of block as it returns to the original position respectively are. .