A solid sphere of mass 2 kg rolls on a smooth horizontal surface at a speed of `10ms^(-1)` and then rolls up a smooth inclined plane of `30^(@)` inclination. The maximum height reached by it before coming to rest is (approx) :

A stone is thrown vertically at a speed of 30 ms^(-1) making an angle of 45^(@) with the horizontal. What is the maximum height reached by the stone ? Take g=10 ms^(-2) .

A stone is thrown vertically at a speed of 30 ms^(-1) taking an angle of 45^(@) with the horizontal. What is the maximum height reached by the stone ? Take g = 10 ms^(-2) .

A ball rolls down a horizontal smooth surface with 4 ms^(-1) and hits the floor after 0.4 s . Then pick the wrong one.

An object is placed on the surface of smooth inclined plane of inclination . It takes time to reach the bottom. If the same object is allowed to slide down the rough inclined plane of the same inclination, the time to reach the bottom is increased n times, where n gt 1 . The coefficient of friction for the plane is :

A block of mass m= 1 kg , moving on a horizontal surface with speed v_(t)= 2 ms^(-1) enters a rough patch ranging from x= 0.10m" to "x= 2.01m . The retarding force F_(r ) on the block in this range is inversely proportional to x over this range, F_(r )= (-k)/(x)" for "0.1 lt x lt 2.01m = 0 " for "x lt 0.1m" and "x gt 2.01m where k= 0.5 J . What is the final kinetic energy and speed v_(f) of the block as it crosses this patch?

A solid sphere of mass m rolls down an inclined plane without slipping from rest at the top of an inclined plane.The linear speed of the sphere at the bottom of the inclined plane is v .The kinetic energy of the sphere at the bottom is

A block released from rest from the top of a smooth inclined plane of angle of inclinatione, reaches the bottom in time t_(1) The same block, released from rest from the top of another smooth inclined plane of angle of inclination theta_(2) reaches the bottom in time ty. If the two inclined planes have the same height, the relation between t_(1) and t_(2) is :