Figure shows the elipticla path of a planet about the sun. The two shaded parts have equal area. If `t_1 and t_2` be the tim taken by the planet to go from a to b and from c to d respectively

The figure shows elliptical orbit of a planet m about the sun S. The shaded area SCD is twice the shaded are SAB. If t_1 is the time for the planet to move from C to D and t_2 is the time to move from A to B then ......

The figure shows elliptical orbit of a planet m about the sun S. the shaded area SCD is twice the shaded area SAB. If t_(1) be the time for the planet to move from C to D and t_(2) is the time to move from A to B, then:

The figure shows elliptical orbit of a planet m about the sun S. the shaded area SCD is twice the shaded area SAB. If t_(1) be the time for the planet to move from C to D and t_(2) is the time to move from A to B, then:

Figure elliptical path abcd of a planet around the sun S such that the area of Delta csa is (1)/(4) the area of the ellipse, (see figure) with db as the semimajor axis, and ca as the semiminor axis if t_(1) is the time taken for planet to go over path abc and t_(2) for path taken over cda then:

Two liquids of densities d_(1) and d_(2) are flowing in identical capillaries under same pressure difference. If t_(1) and t_(2) are the time taken for the flow of equal quantities of liquid, then the ratio of coefficients of viscosities of liquids must be

In the picture below the planet orbits around the sun with a period of 40 months and takes 12 months to translate from the point D to point E and 1 month from point B to C. the area of the ellipse is A. mass of the satellite. Q. The area of the shaded region

A particle executes simple harmonic motion between x = -A and x = + A . The time taken for it to go from 0 to A//2 is T_1 and to go from A//2 to A is T_2 . Then.

The figure shows two paths for the change of state of a gas from A to B. The ratio of molar heat capacities in path 1 and path 2 is

A system goes from A and B via two processes. I and II as shown in figure. If DeltaU_1 and DeltaU_2 are the changes in internal energies in the processes I and II respectively, then

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)