A force `F` acting on a body depends on its displacement `x` as `Fpropx^(a)`. The power delivered by `F` will be independent of `x` if `n` is `-`

The buoyant force acting on a body partly immersed in liquid, depend on the total volume of the object.

f the net force acting on an object is zero, then the body is said to be in the state of

A body of mass m is executing SHM with amplitude a. When its displacement x=1 unit, the force is b then what will be its maximum kinetic energy?

The work done by a force F_1 is larger than the work done by another force F_2 . Is it neccesary that power delivered by F_1 is also larger than that of F_2 ? Why

The position (x) of body moving along x-axis at time (t) is given by x=3t^(2) where x is in matre and t is in second. If mass of body is 2 kg, then find the instantaneous power delivered to body by force acting on it at t=4 s.

The position (x) of body moving along x-axis at time (t) is given by x=3t^(3) where x is in matre and t is in second. If mass of body is 2 kg, then find the instantaneous power delivered to body by force acting on it at t=2 s.

A block of mass 2 kg is plased on a smooth horizontal surface. Two forces F_(1)=20 N and F_(2)=5 N start acting on the block in opposite directions as shown. If block gets displaced by 5 m in the direction of net force then work done by F_(2) is :-

Two force F_(1)" and "F_(2) are acting on a body. One force is double that of the other force and the resultant is equal to the greater force. Then the angle between the two forces is :-

An object of mass m is attached to a spring. The restroing force of the spring is F - lambdax^(3) , where x is the displacement. The oscillation period depends on the mass, l mabd and oscillation amplitude. Suppose the object is initially at rest. If the initial displacement is D then its period is tau . If the initial displacement is 2D , find the period.