Two non-ideal batteries have e.m.f 2V and 8V respective ly and internal resistance 1 Omega and 2 Omega respectively as shown in the figure. If the potential difference between a and b is zero then the resistance R has a value

Two identical batteries, each having emf of 1.8 V and of equal internal resistances are connected as shown in the figure. Potential difference between A and B will be equal to (Ignore the resistance of lead wires)

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 P and Q

Two batteries one of the emf 3V , internal resistance 1Omega and the other of emf 15 V , internal resistance 2Omega are connected in series with a resistance R as shown. If the potential difference between points a and b is zero, the resistance R in Omega is

Two batteries of emf 4 V and 8 V with internal resistances 1Omega and 2Omega are connected in a circuit with a resistance of 9Omega as shown in figure. The current and potential difference between the points P and Q are

epsi_(1) and epsi_(2) are two batteries having e.m.f of 34V and 10V respectively and internal resistance of 1Omega and 2Omega respectively. They are connected as shown in figure below. Using Kirchhoff.s Laws of electrical networks, calculate the current I_(1) and I_(2)

A circuit consists of three bateries of emf E_(1) = 1V, E_(2)=2V and E_(3)=3V and internal resistance 1Omega, 2Omega and 1Omega respectively which are connected in parallel as shown in figure. The potential difference between points P and Q is

Two ideal batteries of emf V_1 and V_2 and three resistances R_1, R_2 and R_3 are connected as shown in the figure. The current in resistance R_2 would be zero if

In the circuit shown in figure 16, E, F, G and H are cells of emf 2 V, 1 V, 3 V and 1 V and their internal resistance are 2 Omega, 1 Omega, 3 Omega and 1 Omega respectively. Calculate (i) the potential differnce between B and D and (ii) the potential difference across the terminals of each of the cells G and H.

In the circuit shown in figure below, E_(1) and E_(2) are batteries having emfs 4.0 V and 3.5 V respectively and internal resistance 1Omega and 2Omega respectively. Using Kirchhoff.s laws, calculate currents : I_(1),I_(2) and I_(3) .

In the ciruit the cells E_1 and E_2 have emfs of 4V and 8V and internal resistance 0.5 Omega and 1.0 Omega, respectively. Calculate the current through 6 Omega resistance.