Two capacitors `C_(1)` and `C_(2)` are connected in a circuit as shown in figure. The potential difference `(V_(A) - V_(B))` is

Four capacitors C_(1),C_(2),C_(3) and C_(4) are connected as shown in figure.If potential difference between points A and B is zero, then

A circuit shown in the figure consists of a battery of emf 10V and two capacitance C_(1) and C_(2) of capacitances 1.0muF and 2.0muF respectively. The potential difference V_(A) - V_(B) is 5V

A circuit shown in the figure consists of a battery of emf 10V and two capacitance C_(1) and C_(2) of capacitances 1.0muF and 2.0muF respectively. The potential difference V_(A) - V_(B) is 5V

A combination of five resistors are connected to a cell of emf 10 V as shown in figure. The potential difference V_(B) - V_(E) will be .

Three capacitors C_(1),C_(2) and C_(3) are connected as shown in, The potentials of P,Q , and R are V_(1),V_(2), and V_(3) , respectively. Find the potential V_(0) at the function O . .

Three capacitors C_(1),C_(2) and C_(3) are connected as shown in, The potentials of P,Q , and R are V_(1),V_(2), and V_(3) , respectively. Find the potential V_(0) at the function O . .

Two capacitors C_(1) and C_(2) are connected to a battery of 6 V as shown in Fig. Find the charge on each capacitor.

Three uncharged capacitors of capacities C_(1),C_(2) and C_(3) are connected as shown in the figure to one another and the potentials V_(1),V_(2) and V_(3) respectively. Then the potential at O will be .

Two capacitances of capacity C_(1) and C_(2) are connected in series and potential difference V is applied across it. Then the potential difference across C_(1) will be

Two capacitances of capacity C_(1) and C_(2) are connected in series and potential difference V is applied across it. Then the potential difference across C_(1) will be