Two batteries of different emfs and different internal resistances are connected as shown. The equivalent emf is

Two batteries of different emfs and different internal resistances are connected as shown. The voltage across AB in volts is. .

3.0 A current passing through Two batteries of different emf and internal resistances connected in series with each other and with an external load resistor. The current reversed, the current becomes 1.0 A. the ratio of the emf of the two batteries is

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 cells of same emf but different internal resistance are connected in parallel so as to send current in same direction. STATEMENT-1 : The equivalent emf of the combination is equal to individual emf of each cell. and STATEMENT-2 : The equivalent emf is the arithmetic mean of the individual emfs.

Six batteries of increasing emf and increasing internal resistance are as shown in figure. Match the following:

Two batteries, one of emf 18V and internal resistance 2Omega and the other of emf 12 and internal resistance 1Omega , are connected as shown. The voltmeter V will record a reading of

Two batteries, one of emf 18V and internal resistance 2Omega and the other of emf 12 and internal resistance 1Omega , are connected as shown. The voltmeter V will record a reading of

Six batteris of increasing emf and increasing internal resistance are as shown in figure. Match the following

Seven identical cells each of e.m.f. E and internal resistance r are connected as shown . The potential difference between A and B 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