Two cells of emf `E_(1)` and `E_(2)` have internal resistance `r_(1)` and `r_(2)`. Deduce an expression for equivalent emf of their parallel combination.

Two batteries of e.m.f. E_(1) and E_(2) and internal resistance r_(1) and r_(2) are connected in parallel. Determine their equivelent e.m.f.

Assertion:- To cells of unequal emf E_(1) and E_(2) having internal resistances r_(1) and r_(3) are connected as shown in figure. Then the potential difference across any cell cannot be zero. Reason:- If two cells having nonzero internal resistance and unequal emf are connected across each other as shown, then the current in the circuit cannot be zero.

The two batteries of emf E_(1) and E_(2) having internal resistances r_(1) and r_(2) respectively are connected in series to an external resistor R. Both the batteries are gatting discharged. The above described combination of these two batteries has to produce a weaker current then when any one of the battery is connected to same resistor. For this requirement to be fulfilled.

Two cells of emfs epsilon_(1)and epsilon_(2) and internal resistances r_(1)and r_(2) respectively are connected in parallel . Obtain expressions for the equivalent (i) resistance and , (ii) emf of the combination.

Two batteries of emf E_(1) and E_(2)(E_(2) gt E_(1)) and internal resistance r_(1) and r_(2) respectively are connected in parallel as shown in the figure. Then, which of the followings statements is correct ?

STATEMENT-1 : If two cells of emf E_(1) and E_(2)(E_(1) cancel(=) E_(2)) and internal resistace r_(1) and r_(2) are joined together as shown, then one cell will continuously supply energy to the other. and STATEMENT-2 : The potential drop across one cell will be larger than other

Two batteries of emf epsi_(1) and epsi_(2)(epsi_(2) gt epsi_(1)) and internal resistance r_(1) and r_(2) respectively are connected in parallel as shown in figure.

Two cells of unequal emfs epsi_(1)" and "epsi_(2) , and internal resistances r_(1)" and "r_(2) are joined as shown. V_(A)" and "V_(B) are the potentials as A and B respectively.