In the circuit shown the cells A and B have negligible resistance. For `V_(A) = 12V, R_(1) = 500Omega " and " R = 100 Omega` the galvanometer (G) shows no deflection. The value of VB is

In the circuit shown the cells A and B have negligible resistance. For V_(A) = 12 V, R_(1) = 500 Omega and R = 100 Omega , the galvanometer (G) shows no deflection. The value of V_(B) is

In the circuit shown the cells A and B have negligible resistance. For V_(A) = 12 V, R_(1) = 500 Omega and R = 100 Omega , the galvanometer (G) shows no deflection. The value of V_(B) is

In the circuit shown in fig. the cell has emf 10V and internal resistance 1 Omega

In the circuit shown, the galvanometer shows zero current. The value of resistance R is :

In the circuit shown, the galvanometer shows zero current. The value of resistance R is :

In the potentiometer circuit shown in the figure the internal resistance of the 6V battery is 1Omega and length of the wire AB is 100 cm . When AD = 60 cm , the galvanometer shows no deflection . The EMF of the cell C is (the resistance of the wire AB is 2Omega )

In the circuits shown in the figures, the galvanometers show no deflection. Find the ratio of R_(1) and R_(2) .

In the circuit shown in Fig., the cell is ideal with e.m.f = 2V. The resistance of the coil of the galvanometer G is 1Omega . Then

In the circuit shown below E_(1) = 4.0 V, R_(1) = 2 Omega, E_(2) = 6.0 V, R_(2) = 4 Omega and R_(3) = 2 Omega . The current I_(1) is

In the circuit shown in Fig. the emf of the sources is equal to xi = 5.0 V and the resistances are equal to R_(1) = 4.0 Omega and R_(2) = 6.0 Omega . The internal resistance of the source equals R = 1.10 Omega . Find the currents flowing through the resistances R_(1) and R_(2) .