Velocity of a particle depends upon t as `V = A + Bt + Ct^2`. If velocity is in m/s, the unit of A will be :

The wavelength lambda associated with a moving particle depends upon its mass m, its velocity v and Planck’s constant h Show dimensionally the relationship between them

The velocity of a body depends on time according to v = 20 + 0.1 t^2 . The body undergoes

Prove that V - u = 2as from velocity time graph.

The position of a particle is given by barr = 3.0thati + 2.0t^2hatj + 5.0hatk . Find the velocity of particle at t=2sec

Given that the velocity of sound in a medium depends on the modulus of elasticity and the density of the medium, find an expression for velocity of sound by dimensional analysis.

The acceleration of a particle in ms^(-s) is given by a =3t^2 + 2t + 2 , where time t is in seconds. If the particle starts with a velocity V = 2 ms^(-1) at t=0, find the velocity after 2 seconds.

The initial velocity of a particle moving along straight line is 20 m/s and its retardation Is 2 m/s_2. The distance moved by the particle in the fifth sec. of its motion is :

A particle is moving eastward with a velocity of 5ms^-1 in 10s, the velocity of the particle changes 5ms^-1 northward. The average acceleration is

The position of a moving particle is given by x = 6 + 18t + 9t^2 where x is the distance and t is the time. What is the velocity at t = 2sec.

The displacement of a particle ( in meter ) moving along x axis is given by x = 18 + 5t^2 . Calculate the instantaneous velocity at t = 2S and instantaneous acceleration.