A, B, C are points in a vertical line such that AB = BC. If a body falls freely from rest at A and `t_(1)` and `t_(2)` are times taken to travel distances AB and BC, then ratio `(t_(2)//t_(1))` is

Let A, B, C, D be points on a vertical line such that AB = BC = CD. If a body is released from position A, the times of descent through AB, BC and CD are in the ratio.

Time taken by an object falling from rest to cover the height of h_(1) and h_(2) is respectively t_(1) and t_(2) then the ratio of t_(1) to t_(2) is

A body is dropped from a large height h in time t_(0) second. Find the time taken to cover the last meter of fall in terms of t_(0)

The temperature of an spherical isolated black body falls from T_(1) and T_(2) in time t them time t is

P,Q,R and S are the points in a vertical line. It is given that PQ=QR=RS. A particle is released from rest from the point P. particle takes time t_(PQ),t_(QR) and t_(RS) to cover three equal distance, respectively. Find ratio t_(PQ):t_(QR):t_(RS)

The displacement of a particle undergoing S.H.M. as a function of time t is given by x = A sin((4pit)/(3)) Where x is in cm and t in second The time taken by the particle to travel from (a) x = 0 to A/2 is t_(a) and time taken by it to travel from (b) x = A/2 to A is t_(b) . Calculate the ratio t_(b)//t_(a) .

A freely falling body takes t second to travel (1//x)^(th) distance then time of descent is

The given figure shows the elliptical orbit of a planet m about the sun S. If t_(1) is the time taken by the planet of move from C to D and t_(2) is the time taken by the planet to move from A to B, then the relation between t_(1) and t_(2) is [Given, area SCD = 2 (area SAB)]