A body starts with a velocity `(2hati + 3hatj + 11hatk)` m/s and moves with an acceleration `(5hati + 5hatj - 5hatk) m//s^(2)` . What is its velocity after 0.2 sec ?

A body starts with a velocity 2 hati +3hatj +11 hatk m/s and moves with an acceleration 10 hati +10 hatj +10 hatk m//s^2 . What is its velocity after 0.2 seconds ?

The velocity of an object at t =0 is vecv_(0) =- 4 hatj m/s . It moves in plane with constant acceleration veca = ( 3hati + 8 hatj) m//s^(2) . What is its velocity after 1 s?

A particle P is at the origin starts with velocity u=(2hati-4hatj)m//s with constant acceleration (3hati+5hatj)m//s^(2) . After travelling for 2s its distance from the origin is

A particle starts from the origin at t = 0 s with a velocity of 10.0 hatj m/s and moves in plane with a constant acceleration of (8hati + 2hatj)ms^(-2) . The y-coordinate of the particle in 2 sec is

A body of mass 3 kg moving with a velocity (2hati+3hatj+3hatk) m/s collides with another body of mass 4 kg moving with a velocity (3hati+2hatj-3hatk) m/s. The two bodies stick together after collision. The velocity of the composite body is

The work done by the forces vecF = 2hati - hatj -hatk in moving an object along the vectors 3hati + 2hatj - 5hatk is:

The ratio in which hati + 2 hatj + 3 hatk divides the join of -2hati + 3 hatj + 5 hatk and 7 hati - hatk , is

A particle of mass 2kg is moving in free space with velocity vecv_0=(2hati-3hatj+hatk)m//s is acted upon by force vecF=(2hati+hatj-2hatk)N . Find velocity vector of the particle 3s after the force starts acting.

If angular velocity of a point object is vecomega=(hati+hat2j-hatk) rad/s and its position vector vecr=(hati+hatj-5hatk) m then linear velocity of the object will be

A particle moving with velocity (2hati-3hatj) m/s collides with a surface at rest in xz–plane as shown in figure and moves with velocity (2hati+2hatj) m/s after collision. Then coefficient of restitution is :