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`

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

A circuit has section AB as shown in figure. The emf of the source equals E=10V , the capacitor capacitances are equal to C_1 =1.0muF and C_2=2.0muF , and the potential difference V_A-V_B=5.0V . Find the voltage across each capacitor.

A circuit has a section Ab shown in fig. The emf of the source equals E = 10V , the capacitances are equal to C_(1) = 1.0 muF and C_(2) = 2.0 muF , and the potential difference varphi_(A) - varphi_(B) = 5.0 V . Find the voltage across each capacitor.

A circuit has section AB as shown in The emf of the cell is 10 V , and the capacitors have capacitances C_(1)=1 muF and C_(2)=2 muF . .

Find the potential difference V_(A)-C_(B) for the circuit shown in the figure .

Find the dimension of C/V where C= Capacitance and V is potential difference

Two capacitors A and B of capacitances 2muF and 5 mu F are connected to two battery as shown in figure The potential difference in volt between the plate of A is

In each capacitance C_(1) is 6.0 muF , and each capacitance C_(2) is 4.0 muF . . With 420 V across a and b the value of V_(c)-V_(d) is.

Two capacitors A and B having capacitances 10 muf and 20 muF are connected in series with a 12 V battery. The ratio of the charge on A and B is

In each capacitance C_(1) is 6.0 muF , and each capacitance C_(2) is 4.0 muF . . The charge on C_(1) nearest to a when V_(ab)=420 V is.