In the circuit shown, both cells are ideal and of fixed emf, the resistance of resistance `R_(1)` has fixed resistance and the resistance of resistor `R_(2)` can be varied (but the value of `R_(2)` is not zero). Then:

Statement I : In the circuit in Fig. 7.46 , both cells are ideal and of fixed emf, the resistor R_(1) has fixed resistance and the resistance of resistor R_(2) can be varied ( but R_(2) is always non zero). Then the electric power delivered to the resistor of resistance R_(1) is independent of the value of resistance R_(2) . Statement II: If potential difference across a fixed resistance is unchanged , the poweer delivered to the resistor remains constant.

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 circuit shown in figure resistance of each wire is r. Net resistance across

In the circuit shown the cells are ideal and of equal emfs, the capacitance of the capacitor is C and the resistance of the resistor is R . X is first joined to Y and then to Z . After a long time, the total heat produced in the resistor will be

In the circuit shown, each resistor is of resistance R. the equivalent resistance between the terminals A and B is

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

A cell develops the same power across two resistances R_(1) and R_(2) separately. The internal resistance of the cell is

A cell develops the same power across two resistances R_(1) and R_(2) separately. The internal resistance of the cell is

Each of the resistor shown in fig. has resistance R. Find the equivalent resistance between A and B