In the arrangement of the capacitor shown in the figure, each `C_(1)` capacitor has capacitance of `3mu F` and each `C_(2)` capacitor has capacitance of `2mu F` then,

(iii) If `V_(ab)=900 V`, then potential difference across points c and d is :

In the arrangement of the capacitor shown in the figure, each C_(1) capacitor has capacitance of 3mu F and each C_(2) capacitor has capacitance of 2mu F then, (ii) If V_(ab)=900V , the charge on each capacitor nearest to the points 'a' and 'b' is :

In the arrangement of the capacitor shown in the figure, each C_(1) capacitor has capacitance of 3mu F and each C_(2) capacitor has capacitance of 2mu F then, (i) Equivalent capacitance of the network between the points a and b is :

Find the capacitance between P and O. Each capacitor has capacitance C. .

In the given circuit (as shown in figure), each capacitor has a capacity of 3 mu F . What will be the net charge on each capacitor ?

A combination arrangement of the capacitors is shown in the figure (i) C_(1)=3 mu F, C_(2) =6 mu F and C_(3)= 2 mu F then equivalent capacitance between 'a' and 'b' is :

In the circuit shown in the figure four capacitors are connected to a battery. The p.d across the 7 mu F capacitor is 6V . .

In the given arrangement of the capacitors, one 3mu F capacitor has got 600 mu J of energy. Then the potential difference across 2 mu F capacitor is

In the circuit shown in the figure all the capacitors have capacitance C. (a) Find the charge on capacitors marked as 1 and 2 when a battery of emf V is connected across points A and B. (b) Find the equivalent capacitance across points C and D marked in the Figure. (c) Find the equivalent capacitance across points E and G.

The minimum number of capacitors (each of capacitance 2 mu F ) required to get an effective capacitance of 9 mu F is?

Each capacitor has cpacitance C. . The capacitance between 1 and 3 is.