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

Four capacitors, C1, C2, C3, and C4 , are connected as shown in the figure. A potential di fference is applied between points A and B. What should the relationship between the capacitances of the capacitors be so that the potential difference between points a and b is zero?

Four capacitors and two batteries are connected as shown in the figure. The potential difference between the points a and b is:

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 are connected as shown in figuere to a 30 V battery. The potential difference between points a and b

Four capacitors C_(1), C_(2), C_(3) and C_(3) are connected as shown in figure 6.12. Calculate the equivalent capacitance when (i) witch S is open, (ii) switch S is closes. Take capacitance of the capacitor tobe 1,2,3 and 4 muF, respectively.

In an isolated parallel plate capacitor of capacitance C the four surfaces have charges Q_(1), Q_(2), Q_(3) and Q_(4) as shown in the figure. The potential difference between the plates is :

Four capacitors with capacitances C_(1) = 1 muF, C_(2) = 1.5 muF, C_(3) = 2.5 muF and C_(4) = 0.5 muF are connected as shown in Fig, to a 30 voltg source. The potentail difference between points a and b is

Six equal capacitors each of capacitance C are connected as shown in the figure. The equivalent capacitance between points A and B is

Three uncharged capacitors of capacitance C_(1)=1mu F, C_(2)=2mu F and C_(3)=3mu F are connected as shown in the figure. The potential of point A, B and D are 10 volt, 25 volt and 20 volt respectively. Determine the potential at point O.