For the circuit shown, with `R_1=1.0Omega`, `R_2=2.0Omega`, `E_1=2V` and `E_2=E_3=4V` the potential difference between the points 'a' and 'b' is approximately (in V):

The potential difference (V_(A) - V_(B)) between the point A and B in the given figure is

Two batteries of e.m.f. 4 V and 8 V with internal resistance 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 respectively

The internal resistance of two cells shown are 0.1Omega and 0.3Omega . If R=0.2Omega, the potential difference across the

Potentiometer wire of length 1 m is connected in series with 490 Omega resistance and 2 V battery. If 0.2 mV / cm is the potential gradient, then resistance of the potentiameter wire is approximately

A potentiometer wire of length 1m and resistance 10 Omega is connected in series with a cell of emf 2V with internal resistance 1 Omega and a resistance box including a resistance R. If potential difference between the ends of the wire is 1 mV, the value of R is

A circuit consists of two cells, each of e.m.f. E and internal resistances r_(1) and r_(2) are connected in series through an external resistance X. If the potential difference between the ends of the first cell is zero, the value of X in terms of r_(1) and r_(2) will be

A, B and C are voltmeters of resistance R, 1.5R and 3R respectively as shown in the figure. When some potential difference is aaplied between X and Y, the voltmeter readings are V_(A),V_(B) and V_(C) respectively, then

Choose correct alternative. The emf of a cell of negligible internal resistance is 2 V. It is connected to the series combination of 2 Omega , 3 Omega and 5 Omega resistances. The potential difference across 3 Omega resistance will be (in volt)

Calculate : total resistance and R_1 = 3 Omega , R_2= 6 Omega , R_3 = 5Omega, V = 14 V.