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

Two cells e_(1) and e_(2) connected in opposition to each other as shown in figure. The cell of emf 9 V and internal resistance 3Omega the cell is of emf 7V and internal resistance 7Omega . The potential difference between the points A and B is

In the situation shown each cell has e.m.f. 4V and internal resistance 1Omega . The maximum power that can be delivered to the variable load resistance R is

In the circuit shown below, E is a battery of emf 6 V and internal resistance 1Omega . Find the reading of the ammeter A. if it has negligible resistance :

In the circuit shown in fig. the cell is ideal with emf 15V. Each resistance is of 3Omega. The potential difference across the capacitoro in steady state is

Three equal resistances, each of ROmega are connected as shown in figure. A battery of emf 2 V and internal resistance 0.1Omega is connected across the circuit. Calculate the value of R for which the heat generated in the circuit is maximum?

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 a potentiometer circuit, the emf of driver cell is 2V and internal resistance is 0.5 Omega . The potentiometer wire is 1m long . It is found that a cell of emf 1V and internal resistance 0.5 Omega is balanced against 60 cm length of the wire. Calculate the resistance of potentiometer wire.

Two cell with unequal emfs of 2V and 3V are connected as shown in the figure. If each cell has an internal resistance r = 0.45 Omega and external resistance is of 4 Omega . Then, Potential drop across resistor 4 Omega is

Find the current drawn from a cell of emf 2 V and internal resistance 2 Omega connected to the network given below.

In the circuit shows in Fig. 6.63, the cell is ideal with emf 9 V . If the resistance of the coil of galvanometer is 1 Omega , then