Two identical rods are arranged int wo different ways as shown in the figure If `R_(1)` is rate at which ice is melting in figure 1 and `R_(2)` is the rate at which ice is melting in figure 2 then `(R_(2))/(R_(1))` is equal to

In the figure shown the current flowing 2 R is:

Four identical resistances are joined as shown in the figure. The equivalent resistance between points A and B is R_(1) and that between A anc C is R_(2) then ratio R_(1)//R_(2) is

Six resistances each of v ale r= 6Omega are connected between points A,B and C as shown in the figure if R_(1),R_(2) and R_(3) are the net resistances between A and B, between B and C and between A and C respectively, the R_(1):R_(2):R_(3) will be equal to

Six resistance each of value r=5 Omega are connected between points A, B and C as shown in figure. If R_(1), R_(2) and R_(3) are the net resistance between A and B, between B and C and between A and C respectively, then R_(1):R_(2):R_(3) will be equal to

In the circuit shown in the figure, the value of maximum rate of heat production in resistance R is

Two identical rods are connected in parallel. One end of the rods is maintained at 100^(@)C and other end is kept in 0^(@)C ice . The rate at which the ice melts is Q_(1) gm/sec . Now the rods are connected in series . The ends are again maintained at 100^(@) C and kept in 0^(@)C ice . Now the rate at which ice melts is Q_(2) gm/sec . Then Q_(2) //Q_(1) is

An infinite sequence of resistance is shown in the figure. The resultant between A and B will be, when R_(1) = ohm and R_(2) = 2 ohm

In the circuit shown in figure Current thorugh R_(1) is independent of