A cell of emf `epsilon` and internal resistance r is connected across a load resistance R
(i) Find the maximum power delivered at the load ?
(ii) Draw the power (P ) vs load resistance ( R ) graph.

A cell of emf epsi and internal resistance r is connected across a load resistance R . (i) Find the maximum power delivered at the load ? (ii) Draw the power (P) vs load resistance (R) graph .

A cell of emf epsilon and internal resistance r is connected across a variable load resistance R. The graph drawn between its terminal voltage and resistance R is

A battery of emf E and internal resistance 'r' is connected to an external resistance 'R', the condition for maximum power transfer is

A cell of internal resistance "r" is connected to an external resistance "R". p.d. will be maximum across "R" if

A cell of emf (E) and of internal resistance (r ) is connected across an external resistance (R ). Deduce the condition for current in the ciruit to be maximum.

A battery of emf epsilon and internal resistance r is connected across a load resistance R_L . The plot between output power and load resistance is shown in the figure The value of emf epsilon and internal resistance r respectively will be

A battery of emf epsilon and internal resistance r is connected across a load resistance R_L . The plot between output power and load resistance is shown in the figure. The value of emf epsilon and internal resistance r respectively will

A battery of emf (epsilon) and internal resistance r is connected across a load resistance R_L The plot between output power and load resistance is shown in the figure. value of emf (epsilon) and internal resistance respectively will be

A battery of emf (epsilon) and internal resistance r is connected across a load resistanvce (RundersetL). The plot between output power and load resistance is shown in the figure. value of emf (epsilon) and internal resistance respectively will be