The displacement of a body is given by `s=(1)/(2)g t^(2)` where g is acceleration due to gravity. The velocity of the body at any time t is

The displacement of a body is given by r=sqrt(a^(2)-t^(2))+t cost^(2) , where t is the time and a is constant. Its velosity is :

The displace ment of a body at any time t after starting is given by s=10t-(1)/(2)(0.2)t^2 . The velocity of the body is zero after:

The displacement of a body at any time t after starting is given by s=15t-0.4t^2 . Find the time when the velocity of the body will be 7ms^-1 .

The velocity of a body which has fallen under gravity varies as g^(a) h^(b) where g is the acceleration due to gravity at a place and h is the height through which the body has fallen, a and b are given by

The height at which the acceleration due to gravity becomes (g)/(9) (where g =the acceleration due to gravity on the surface of the earth) in terms of R, the radius of the earth, is :

The height at which the acceleration due to gravity becomes (g)/(9) (where g =the acceleration due to gravity on the surface of the earth) in terms of R, the radius of the earth, is :

The velocity of a freely falling body changes as g^ph^q where g is acceleration due to gravity and h is the height. The values of p and q are

The angular displacement of a body is given by theta = 2t^(2) + 5t -3 . Find the value of the angular velocity and angular acceleration when t = 2s.

The position of a body moving along x-axis at time t is given by x= (t^(2)-4t+6)m . The velocity of the body at time t = 3s is

A point mass m, is placed at the surface of a hypothetical planet where acceleration due to gravity is g/2 , where g acceleration due to gravity at the poles the planet. The latitude of that position is [T is time period of planet rotation about its own axis and R is radius of planet]