The force acting on a body moving along x -axis varies with the position of the particle as shown in the fig. The body is in stable equilibrium at.

The force acting on a body moving along x-axis variation of the particle particle shown in the figure. The body is in stable equilibrium at .

The force acting on a body moving along x-axis variation of the particle particle shown in the figure. The body is in stable equilibrium at .

The variation of force F acting on a body moving along x - axis varies with its position (x) as shown in figure The body is in stable equilibrium stable at

The variation of potential energy U of a body moving along x - axis varies with its position (x) as shown in figure The body is in equilibrium state at

The kinetic energy of a body moving along a straight line varies with time as shown in figure. The force acting on the body:

The velocity (upsilon) of a particle moving along X-axis varies with its position x as shown in figure. The acceleration (a) of particle varies with position (x) as

The kinetic energy K of a particle moving along x - axis varies with its position (x) as shown in figure The magnitude of force acting on particle at x = 9 mis

The magnitude of force acting on a particle moving along x-axis varies with time (t) as shown in figure. If at t = 0 the velocity of particle is v_(0) , then its velocity at t=T_(0) will be

The rate of doing work by force acting on a particle moving along x-axis depends on position x of particle and is equal to 2x. The velocity of particle is given by expression :-

The net force acting on a particle moving along a straight line varies with time as shown in the diagram. Force is parallel to velocity. Which of the following graph is best representative of its speed with time? (Initial velocity of the particle is zero)