The electric power transferred by a cell to an external resistance is maximum when the external resistance is equal to (r internal resistance)

Show that the power supplied by a battery to an external reistance is maximum when it is equal to the internal resistance of the batter. Further show that this maximum power is (e^(2))/(4r) where is the emf of the battery and r is internal reisistance.

A battery is of emt E and internal resistance r . The value of external resistance R so that the power across eternal resistance is maximum :

An total resistance R is connected to a cell of internal resistance r the maximum current flows in the external resistance, when

An accumulator of emf epsilon and internal resistance r is first connected to an external resistance R_(1) and then to an external resistance R_(2) for the same time. For what value of r the beats dissipated in R_(1) and R_(2) will be same?

An accumulator of emf epsilon and internal resistance r is first connected to an external resistance R_(1) and then to an external resistance R_(2) for the same time. For what value of r the beats dissipated in R_(1) and R_(2) will be same?

In the electric circuit shown each cell has an emf of 2 V and internal resistance of 1Omega . The external resistance is 2Omega . The value of the current is (in A)

Two batteries each of E and internal resistance r are connected turen by turn in series and in parallel, and areused to find current in an external resistance R . If the current in series is equal to that in parallel, the internal resistance of each battery is

If E is the emf of a cell of internal resistance r and external resistance R, then potential difference across R is given as

Acell of internal resistance r drives a current through an external resistance R . The power delivered by the cell to the external resistance is maximum when