At a given place where acceleration due to gravity is `g m/s^2`, a sphere of lead density `d kg/m^3`. If `d gt rho`, the sphere will

The acceleration due to gravity is 9.8m//s^(2)

At a given place where acceleration due to gravity is 'g' m//sec^(2) , a sphere of lead of density 'd kg//m^(3) is gently released in a column of liquid of density 'rho' kg//m^(3) . If d gt rho , the sphere will

At a given place where acceleration due to gravity is g m//s^(2) a sphere of lead of density d kgg//m^(3) is gently released in a column o liquid of desnsity rho kg/m^(3) . If dgtrho , the sphere will

Time period of simple pendulum of length l at a place, where acceleration due to gravity is g and period T. Then period of simple pendulum of the same length at a place where the acceleration due to gravity 1.02 g will be

A satellite is revolving around the earth in a circular orbit at an altitude h where the acceleration due to gravity is g'. If the earth is a sphere of radius R then the period of the satellite is give by

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]

Find ratio of acceleration due to gravity g at depth d and at height h where d=2h

A man can jump 2 m high on the surface of the earth. How high he can jump on a planet where the acceleration due to gravity is (g)/(12) , where g is the acceleration due to gravity on the surface of the earth ?

Suppose the acceleration due to gravity at a place is 10 m/s^2 . Find its value in cm//(minute).

The acceleration due to gravity at a place is pi^(2)m//s^(2) . Then, the time period of a simple pendulum of length 1 m is