If `t_(1)` be the time taken by a body to clear the top of a building and `t_(2)` be the time spent in air, then `t_(2):t_(1)` will be -

A tank full of water has a small hole at its bottom. Let t_(1) be the time taken to empty first one third of the tank and t_(2) be the time taken to empty second one third of the tank and t_(3) be the time taken to empty rest of the tank then (a). t_(1)=t_(2)=t_(3) (b). t_(1)gtt_(2)gtt_(3) (c). t_(1)ltt_(2)ltt_(3) (d). t_(1)gtt_(2)ltt_(3)

The figure shows elliptical orbit of a plant P about the sun S. The shaded area CSD is twice tha shaded area ASB. If t_(1) is the time taken by the planet to move from C to D and t_(2) is the time to move from A to B, determine the ratio t_(1)//t_(2)

A tank is filled with a liquid upto a height H, A small hole is made at the bottom of this tank Let t_(1) be the time taken to empty first half of the tank and t_(2) time taken to empty rest half of the tank then find (t_(1))/(t_(2))

A particle executes SHM in accordance with x=A"sin"omegat . If t_(1) is the time taken by it to reach from x=0 to x=sqrt(3)(A//2) and t_(2) is the time taken by it to reach from x=sqrt(3)//2 A to x=A , the value of t_(1)//t_(2) 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)]

The half life of a radioactive substance is 20 days. If 2/3 part of the substance has decayed in time t_(2) and 1/3 part of it has decayed in time t_(1) then the time interval between t_(2) and t_(1) is (t_(2)-t_(1)) =…………….

A cane is taken out from a refrigerator at 0^(@)"C" . The atmospheric temperature is 25^(@)"C" . If t1 is the time taken to heat from 0^(@)"C" to 5^(@)"C" and t_(2) is the time taken from 10^(@)"C" to 15^(@)"C" , then the wrong statements are (1) t_(1)gtt_(2) (2) t_(1)=t_(2) (3) There is no relation (4) t_(1)ltt_(2)

A particle startsits SHM at t=0 . At a particular instant on its way to extreme position , x= (A)/(2) . Find the time taken by the particle to come back to this point after passing through the extreme position. Hint : t_(1) = time taken to go from x=0 to x= (A)/(2) t_(2) = time taken to go to extreme position and come back to mean position = (T)/(2) Required time = (T)/(2) - t_(1)