In the given network capacitance, `C_(1) = 10muF, C_(2) = 5 muF` and `C_(3) = 4muF`. What is the resultant capacitance between `A` and `B`?

In, given C_(1)=3 muF, C_(2)=5muF, C_(3)=9 muF , and C_(4)=13 muF . What is the potential differnce between points A and B ? .

The effective capacitence in muF in between A and B will be

In each capacitance C_(1) is 6.0 muF , and each capacitance C_(2) is 4.0 muF . . The equivalent capacitance of the netwok between ponts a and b is.

Six equal capacitors each of capacitance 10muF are connect as shown in the figure. Then the equivalent capacitance between A and B is

In the circuit shown C_(1) = 15 mu F, C_(2) == 30 muF , C_(3) = 30 muF , C_(4) = 30 muF and C_(5) = 60 muF . At steady state, the potential difference between points P and Q is 50 V. Calculate the potential difference across capacitor with capacitance C_(5)

All the capacitances shown in figure are in muF . Find the equivalent capacitance between A and B.

Some capacitors each of capacitance 30 muF are connected as shown in. Calculate the equivalent capacitance between terminals A and B .

In the given network of capacitors as shown in, given that C_(1) = C_(2)C_(3)=400pF , and C_(4)=C_(5)=C_(6)=200pF , The effective capacitance of the circuit between X and Y is.

(i) Find the equivalent capacitance of the combination shown in the figure (a), when C_(1)=2.0 muF,C_(2)=4.0 muF and C_(3) = 3.0 muF (ii) The input terminals A and B in Fig. (a) are connected to a battery of 12 V. Find the potential and the charge of each capacitor.

In the given figure the capacitors C_(1), C_(3), C_(4),C_(5) have a capaciance 4 muF each if the capaitor C_(2) has a capacitance 10 muF , then effective capacitance between A and B will be