Capacitance of network is

A network of four 20 muF capacitors is connected to a 600 V supply as shoen in the figure. The equivalent capacitance of the network is

A network of four 10 mu F capacitors is connected to a 500 V supply, as shown in Fig. Determine (a) the equivalent capacitance of the network and (b) the charge on each capacitor. (Note, the charge on a capacitor is the charge on the plate with higher potential, equal and opposite to the charge on the plate with lower potential.)

In the figure given below, find the, (a) equivalent capacitance of the network between points A and B. Given: C_1 = C_5 = 4muF , C_2 = C_3 = C_4 = 2 muF (b) maximum charge supplied by the battery, and (c) total energy stored in the network

In figure C_1=C_5=8.4muF and C_2=C_3=C_4=4.2muF .The applied potential is V_(ab)=220V (a) What is the equivalent capacitance of the network between points a and b ? (b) Calculate the charge on each capacitor and the potential difference across each capacitor.

The equivalent capacitance for the network shown in the figure is

A network of four each of 12 mu F capacitance is connected to a 500 V apply as shown in Fig. (a) Equivalent capacitance of the network. (b) Charge on each capacitor.

Three identical capacitors C_(1) , C_(2) and C_(3) of capacitance 6 mu F each are connected to a 12 V battery as shown in Fig. Find (i) charge on each capcitor (ii) equivalent capacitance of the network. (iii) energy stored in the network of capacitors.

A network of four capacitors each of 15 mu F capacitance is connected to a 500 V supply as shown in the figure . Determine (a) equivalent capacitance of the network and (b) charge on each capacitor .

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 equivalent resistance of the network shown in figure