A point object moves along an arc of a circle or radius'R' . Its velocity depends upon the distance covered 'S' as `V=KsqrtS` Where'K' is a constant. IF `theta` is the angle between the total acceleration and tangential accleration , then

A particle moves along a circle of radius'r' with constant tangential acceleration. If the velocity of the particle is 'v' at the end of second revolution , after the revolution has started then the tangential accleration is

A particle moves along a circle if radius (20 //pi) m with constant tangential acceleration. If the velocity of the particle is 80 m//s at the end of the second revolution after motion has begun the tangential acceleration is .

Tangential acceleration of a particle moving on a circle of radius 1 m varies with time t as shown in the graph (initial velocity of particle is zer). Time after which total acceleration of particle makes an angle of 30^@ with radial acceleration is,

If the body is moving in a circle of radius r with a constant speed v , its angular velocity is

A body moving along a circular path of radius r with velocity V, has centripetal acceleration 'a'. If its velocity is made equal to 2V, then its centripetal acceleration is.

The angular speed of a particle, moving along a circle of radius 20cm, increases from 2 rad/s to 40 rad/s in 19 s. The ratio of its centripetal acceleration to tangential acceleration at the end of 19 secs

An object is falling freely under the gravitational force. Its velocity after travelling a distance h is v. If v depend upon gravitational acceleration g and distance h, prove with dimensional analysis v = k sqrt(gh) , where k is constant.

A particle of mass m is moving in a circular path of constant radius r such that its centripetal acceleration a_(c) is varying with time t as a_(c) = k^(2)rt^(2) , where k is a constant. The power delivered to the particle by the forces acting on it is :

A point object is moving uniformly towards the pole of a concave mirror of focal length 25 cm along its axis as shown below. The speed of the object is 1 ms" . At t = 0, the distance of the object from the mirror is 50 cm. The average velocity of the image formed by the mirror between time t = 0 and t = 0.25 s is

A body of mass m starts moving from a position of rest with a constant acceleration a. After covering a distance, it has acquired velocity v. What will be the magnitude of its velocity after it has covered a distance 2s?