Under the action of variable force, at any instant the displacement is

You have learnt how to calculate the work done on an object when the displacement is in the direction of the applied force. But if the displacement is not in the direction of the applied force, how do we calculate the amount of work done

A particle moves in the xy-plane under the action of a force F such that the components of its linear momentum p at any time t and p_(x)=2cos t, p_(y)=2sin t. the angle between F and p at time l is

A particle moves in the x-y plane under the action of a force vec(F) such that the components of its linear momentum vec(P) at any time t are p_(x) = cos t and p_(y) = 3 sin t. What is the magnitude of the vector vec(F) ?

If the relative displacement between any two particles of a body does not change under the application of force of any magnitude, the body is said to be a _____________.

Choose the correct options If the relative displacement between any two particles of a body does not change under the application of force of any magnitude, the body is said to be a

The displacement x of a particle moving in one dimension under the action of a constant force is related to the time t by the equation t = sqrtx + 3 , where x is in metre and t is in second. The work done by the force in the first 6 second is

Wavelength of the transverse wave is 30 cm. If the particle at some instant has displacement 2 cm, find the displacement of the particle 15 cm away at the same instant.

A particle moves in the x-y plane under the action of a force vecF such that the value of its linear momentum vecP at any time t is P_(x)=2 cost and p_(y)=2sint . What is the angle theta between vecF and P at a given time t?

How is work calculated if the direction of force and the displacement are inclined to each other?

Answer the following questions: Derive the expression for the work done when the displacement is in the direction of the force.