A body of mass `0.4kg` starting at origin at `t=0` with a speed of `10ms^(-1)` in the positive x-axis direction is subjected to a constant `F=8` N towards negative x-axis. The position of body after 25s is

A body of mass m = 3.513 kg is moving along the x-axis with a speed of 5.00ms^(-1) . The magnetude of its momentum is recorded as

A body of mass 0 .40 kg moving intially with a constant speed of 10 m//s to the north is subjected to a constant force of 8.0 N directed towards the south for 30 s Take the instant the force is applied to be t = 0 , and the position of the particle at that time to be x = 0 , predict its position at t = -5 s , 25 s , 100 s ?

A ball of mass 0.2 kg travelling in a straight line with a speed of m//s along negative x- axis id deflected by a bat 15 m//s along negative x - axis is deflected by a bat at an angle of 30^(@) If the speed of the ball after deflection is 10 m//s , find the impulse on the ball.

A body of mass 0.4 kg is whirled in a horizontal circle of radius 2 m with a constant speed of 10 ms^-1 . Calculate its frequency of revolution.

A body of mass 2kg is moving towards east with a uniform speed of 2ms^(-1) . A force of 3N is applied to it towaeds north. The magnitude of the displacement of the body 2s after the application of force is.

The inclination of the line x-y+3=0 with the positive direction of x-axis is

A particle starts from the origin at time t = 0 and moves along the positive x-axis. The graph of velocity with respect to time is shown in figure. What is the position of the particle at time t = 5s ?

The inclination of the line x-y+3=0 with the positive direction of x-axis is :

A body is at rest at x =0 . At t = 0 , it starts moving in the positive x - direction with a constant acceleration . At the same instant another body passes through x= 0 moving in the positive x - direction with a constant speed . The position of the first body is given by x_(1)(t) after time 't', and that of the second body by x_(2)(t) after the same time interval . which of the following graphs correctly describes (x_(1) - x_(2)) as a function of time 't' ?