The distance of a particle moving on a circle of radius 12 m measured from a fixed point on the circle and measured along the circle is given by `s=2t^(3)` (in meters). The ratio of its tangential to centripetal acceleration at t = 2s is

The kinetic energy K of a particle moving along a circle of radius R depends upon the distance s as K=as^2 . The force acting on the particle is

If a particle moves in a circle of radius 4m at speed given by v=2t at t=4 sec, Total Acceleration of the particle will be:

A particle is moving in a circle of radius 1 m with speed varying with time as v=(2t)m//s . In first 2 s

a particle moves on a circular path of radius 8 m. distance traveled by the particle in time t is given by the equation s=2/3 t^(3) . Find its speed when tangential and normal accelerations have equal magnitude.

A particle moves in a circle of radius 20 cm . Its linear speed is given by v = 2t where t is in seconds and v in m s^-1 . Then

A particle is moving along a circle of radius 20cm , with a linear velocity of 2m//s. Calculate the angular velocity of the particle.

A particle is moving along a circle of radius 20cm , with a linear velocity of 2m//s. Calculate the angular velocity of the particle.

Figur shows the total acceleration and velocity of a particle moving clockwise in a circle of radius 2.5m at a given instant of time. At this instant, find: (a) the radius acceleration, (b) the speed of the acceleration, (c) its tangential acceleration.

Two cars of mass m_(1) and m_(2) are moving in circle of radii r_(1) and r_(2) , respectively . Their speeds are such that they make complete circles in the same time t . The ratio of their centripetal acceleration is :

Two cars of mass m_(1) and m_(2) are moving in circle of radii r_(1) and r_(2) , respectively . Their speeds are such that they make complete circles in the same time t . The ratio of their centripetal acceleration is :