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)`

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 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

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

A particle is moving with uniform acceleration along a straight line. Its velocities at A & B are respectively 7 m//s & 17 m//s . M is mid point of AB. If t_(1) is the time taken to go from A to M and t_(2) the time taken to go from M to B, the ratio t_(1)/t_(2) is equal to :-

Figure shows the motion of a planet around the Sun S in an elliptical orbit with the Sun at the focus. The shaded areas A and B are also shown in the figure which can be assumed to be equal. If t_(1) and t_(2) represent the time taken for the planet to move from a to b and c to d , respectively then

Figure shows the motion of a planet around the Sun S in an elliptical orbit with the Sun at the focus. The shaded areas A and B are also shown in the figure which can be assumed to be equal. If t_(1) and t_(2) represent the time taken for the planet to move from a to b and c to d , respectively then

The figure represents an elliptical orbit a planet around sun. The planet takes time T_(1) to travel from A to B and it takes time T_(2) to travel from C to D . If the area CSD is double that of area ASB , them

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