Assertion : In a simple battery circuit the point of lowest potential is positive terminal of the battery. Reason
: The current flows towardi, the point of the higher potential as It nows In such a circuit from the negative to the positive terminal.

In the circuit shown in the figure, if potentail at point A is taken to be zero, the potential at point B is

In the circuit shown in figure potential difference between the points A and B in the steady state is

Assertion: Potentiometer measures correct value of emf of a cell. Reason: No current flows through cell at null point of potentiometer.

For a cell, the graph between the potential difference (V) across the terminals of the cells and the current I drawn from the cell is as shown in figure. Calculate the e.m.f. and the internal resistance of the cell.

Assertion: In parallel combination of electrical appliances, total power consum ption is equal to the sum of the powers of the indivisual appliances. Reason : Electrons move away from a region of lower potential to a region of higher potential.

An insulating solid sphere of radius R has a uniformaly positive charge density rho . As a result of this uniform charge distribution there is a finite value of electric potential at the centre of the sphere, at the surface of the sphere and also at a point out side the sphere. The electric potential at infinity is zero. Statement-1: Wgen a charge 'q' is taken from the centre to the surface of the sphere, its potential energy charges by (qrho)/(3 in_(0)) Statement-2 : The electric field at a distance r (r lt R) from the centre of the the sphere is (rho r)/(3in_(0))

For the given part of circuit calculate potential V_(p) of centre point P and then find current I_(1) .

In the circuit element given here, if the potential at point B = V_(B) = 0 , then the potentials of A and D are given as

For the circuit shown in the following figure, determine the eqUivalent resistance between points A and B. Also find the current I flowing through the circuit.

The potential difference between the terminals or a battery is 10 V and internal resistance 1 Omega drops to 8 V when connected across an external resistor . Find the resistance of the external resistor.