A group of six identical cells each of emf `E` and internal resistance r are joined in series to form a loop. The terminal voltage across each cells is

A group of n identical cells each of EMF E and internal resistance r are joined in series to form a loop as shown . The terminal voltage across each cell is

n identical cells each of emfe and internal resistance r are joined in series so as to form a closed circuit. The P.D. across any one cell is

n identical cells, each of emf E and internal resistance r, are joined in series to form a closed circuit. Find the potential difference across any one cell.

Four cells each of emf E and internal resistance r are connected in series to form a loop ABCD. Find potential difference across (1) AB, (2) AC

n identical cells, each of emf epsilon and internal resistance r, are joined in series to form a closed cirucit. One cell A is joined with reversed polarity. The potential difference across any one cell is

Four identical cells each having emf E and internal resistance r are connected in series to form a loop ABCD as shown in figure . Find potential difference across AB and AC .

Three identical cells each of emf 2 V and internal resistance 1 Omega are connected in series to form a battery. The battery is then connected to a parallel combination of two identical resistors, each of resistance 6 Omega Find the current delivered by the battery.

If n cells each of emf E and internal resistance rare connected in parallel, then the total emf and internal resistances will be

N identical cells, each of emf epsilon and internal resistances r are joined in series. Out of these, n cells are wrongly connected, i.e. their terminals are connected in reverse order as required for series connection. If epsilon_(o) be the emf of the resulting battery and r_(o) be its internal resistance then for n lt N//2

n identical cells each of e.m.f. E and internal resistance r are connected in series. An external resistance R is connected in series to this combination. The current through R is