The distance travelled by a particle in a straight line motion is directly proportional to `t^(1//2)`, where `t` is the time elapsed.

The distance travelled by a particle in a straight line motion is directly poroportional to t^(1//2) , where t is the time elapsed.

The distance travelled by a particle in a straight line motion is directly proportional to t^(1/2) ,where t = time elapsed.The nature of motion is

Assertion : Distance-time graph of the motion of a body having uniformly accelerated motion is a straight line inclined to the time axis. Reason : Distance travelled by a body having uniformly accelerated motion is directly proportional to the square of the time taken.

The velocity of a particle moving in a straight line is directly proportional to 3//4th power of time elapsed. How does its displacement and acceleration depend on time?

The distance s travelled by a particle moving on a straight line in time t sec is given by s=2t^(3)-9t^(2)+12t+6 then the initial velocity of the particle is

The displacement x of a particle in a straight line motion is given by x=1-t-t^(2) . The correct representation of the motion is

The position of a particle moving on a straight line is proportional to the cube of the time elapsed. How does the acceleration of the particle depend on time elapsed?

The distance travelled by an object along a straight line in time t is given by s = 3 -41 + 5t^(2) , the initial velocity of the objectis

The distance travelled by a particle is proportional to the squares of time, then the particle travels with

The distance travelled (in meters) by the particle from time t = 0 to t = t will be –