Two cells X an Y are connected to a resistance of `10 Omega` as shown in figure. The terminal voltage of cell Y is:

Two cells X and Y are connected to a resistance of 10Ω as shown in the figure.if the polarity of the cell Y is reversed, then the terminal voltage of the cell Y will be

Two batteries of e.m.f. 4V and 8V with internal resistances 1 Omega and 2 Omega are connected in a circuit with a resistance of 9 Omega as shown in figure. The current and potential difference between the points A and B

For a Cell, the terminal potential difference is 2.2 V when circuit is open and reduces to 1.8 V, when cell is connected to a resistance R = 5Omega . The internal resistance of cell (r ) is

Four identical cells each of emf 2V, are joined in parallel providing supply of current to external circuit consisting of two 15 Omega resistors joined in parallel. The terminal voltage of the cells ae read by an ideal voltmeter is 1.6V. Calculate the internal resistance of each cell.

The internal resistance of a cell of e.m.f. 2 V is 0.1 Omega . It is connected to a resistance of 3.9Omega . The voltage across the cell will be

The internal resistance of a cell of e.m.f. 2 V is 0.1 Omega . It is connected to a resistance of 3.9Omega . The voltage across the cell will be

Four identical cells each of emf 2V, are joined in parallel providing supply of current to external circuit consisting of two 5 Omega resistors joined in parallel. The terminal voltage of the cells ae read by an ideal voltmeter is 1.6V. Calculate the internal resistance of each cell.

A cell of e.m.f E is connected across a resistance r. The potential differene between the terminals of the cell is found to be V. The internal resistance fo the cell must be

Two identical cells, whether joined together in series or in parallel give the same current, when connected to an external resistance of 1Omega . Find the internal resistance of each cell.