A particle takes a time `t_(1)` to move down a straight tunnel from the surface of earth to its centre. If gravity were to remain constant this time would be `t_(2)` calculate the ratio `(t_(1))/(t_(2))`

A train accelerates from at the constant rate b for time t_(2) at a constant rate a and then it retards at the comes to rest. Find the ratio t_(1) // t_(2) .

A particle move with velocity v_(1) for time t_(1) and v_(2) for time t_(2) along a straight line. The magntidue of its average acceleration is

A particle moves with a velocity v(t)= (1/2)kt^(2) along a straight line . Find the average speed of the particle in a time t.

A partical in SHM ha a period of 4s .It takes time t_(1) to start from mean position and reach half the amplitude. In another case it taken a time t_(2) to start from mean position and reach half the amplitude. Find the ratio t_(1)//t_(2)

A simple pendulum has a time period T_(1) on the surface of earth of radius R. When taken to a height of R above the earth's surface, its time period is T_(2) , ratio (T_(2))/(T) is

The time period of a simple pendulum is T_(1) on the surface of earth. If taken to a height 2 R above the surface of earth, the time period becomes T_(2) . What will be the value of T_(1)//T_(2) ? (R is the radius of earth).

A ring takes time t_(1) in slipping down an inclined plane of length L, whereas it takes time t_(2) in rolling down the same plane. The ratio of t_(1) and t_(2) is -

Time period of a pendulum on earth surface is T_1 . It is arranged on earth surface at a height R and thus its time period is T_2 . What is the ratio of T_1 and T_2 ?

A particle is moving in a straight line. At time t, the distance between the particle from its starting point is given by x =t- 9t^(2) + t^(3) . lts acceleration will be zero at