The terminal velocity of a ball in air is v, where acceleration due to gravity is g. Now the same ball is taken in a gravity free space where all other conditions are same. The ball is now pushed at a speed v, then –

A solid sphere moves at a terminal velocity of 20ms^-1 in air at a place where g=9.8ms^-2 . The sphere is taken in a gravity free hall having air at the same pressure and pushed down at a speed of 20 ms^-1

Given that v is speed, r is the radius and g is the acceleration due to gravity. Which of the following is dimensionless

If density (D), acceleration due to gravity (g) and frequency (v) are taken as base quantities , find the dimensions of force.

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

If rocket engine ejects fuel at the rate mu kg/s with relative velocity v_(r) . At time t = 0, speed of rocket is u. Consider the value of acceleration due to gravity is constant and equal to g. If rocket is in gravity free space then find velocity of rocket as function of time.

A rubber ball is dropped from a height of 5m on a plane, where the acceleration due to gravity is not shown. On bouncing it rises to 1.8 m. The ball loses its velocity on bouncing by a factor of

Find the value of a and b in the following cases : (a) The velocity v of the ball falling freely under gravity is proportional to g^(a) h^(b) , where g is the acceleration due to gravity, h is the height from which the ball is dropped. (b) The kinetic energy K of a rotating body is proportional to I^(a) omega^(b) where I is the moment if inertia and omega is the angular speed. (c ) The time-period T of spring pendulum is proportiona to m^(a) k^(b) , where m is the mass of block attached to the spring and k is the spring constant. The speed of sound v in a gaseous medium is proportional to P^(a) rho^(b) , where P is the pressure and rho is the density of medium.

If g is acceleration due to gravity at the equator when earth were at rest and g_(1) is acceleration due to gravity at the same place when earth spins with angular velocity omega, the relation between them is

The terminal velocity v of a small steel ball ofradius r fal ling under gravity through a column ofa viscous liquid of coefficient of viscosity eta depends on mass of the ball m, acceleration due to gravity g, coefficient of viscosity eta and radius r. Which of the following relations is dimensionally correct?

Two identical balls are interconnected with a massless and inextensible thread. The system is in gravity free space with the thread just taut. Each ball is imparted a velocity v , one towards the other ball and the other perpendicular to the first, at t=0 . Then,