In the circuit shown if the internal resistance of each cell is r, then the rate at which the chemical energy of `epsilon_1` is being consumed is

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

For the given circuit, If internal resistance of cell is 1.5 Omega , then

In the circuit shown , the internal resistance of the cell is negligible . The steady stale current in the 2 Omega resistor is

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

In the circuit shown below, the internal resistance of the cell is negligible. The distance of the slider from the left-hand end of the slide wire is l. The graph shows the variation with l of the current I in the cell. Value of the resistance R is:

If internal resistance of cell is negligible, then current flowing through the circuit is

In the given circuit determine (a) Equivalent resistance (Including internal resistance ). (b) Current in each resistance ( c) Potential difference across each resistance (d) The rate awich the chemical energy of the cell is consumed ( e) The rate at which heat is generated inside the battery (f) Electric power output (h) Which resistance consumes maximum power (f) Power dissipated in 3 Omega resistance.

In given circuit determine (a) Equivalent resistance (Including internal resistance). (b) Current I, i_(1), i_(2)'" and "i_(3) ( c) Potential difference across battery and each resistance (d) The rate at which the chemical energy of the cell is consumed (e ) The rate at which heat is generated insisde the battry (f) Electric power output (g) Which resistance consumes miximum power ? (h) Power dissipated across 4Omega resistance.

In the circuit shown below, the voltmeter is of large resistance. The E.M.F. of the cell is epsilon . The reading of the voltmeter is

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