Combination Of Capacitors

How are Capacitors connected?

The equivalent capacitance of a combination of capacitors connected to a battery to apply a potential difference (V) and charge the plates (Q) can be defined as the capacitance between two points.

C=QV

Two frequently used methods of combination are:

  • Parallel combination
  • Series combination

Related Topics

Parallel Combination of Capacitors

The potential difference V across each capacitor when they are connected in parallel is the same, however, the charge on C1 and C2 (Q1 and Q2) is different.

Parallel combination of Capacitors

The total charge is Q:

Q1+Q2V=C1+C2

Equivalent capacitance between a and b is:

C = C1 + C2

The charge on capacitors is given as:

Q1=C1C1+C2Q

Q2=C2C1+C2Q

C=i=1nCi

Series Combination of Capacitors

The magnitude of charge Q on each capacitor is the same when connected in series, however, the potential difference across C1 and C2 is different, i.e., V1 and V2.

Series Combination of Capacitors

Q = C1 V1 = C2 V2

The total potential difference across combination is:

V = V1 + V2

V=QC1+QC2

VQ=1C1+1C2

The ratio of Q to V, denoted as C, is referred to as the equivalent capacitance between point a and b.

1C=1C1+1C2C=C1C2C1+C2

The potential difference across C1 and C2 is V1 and V2 respectively, as follows:

V1=C2C1+C2;V2=C1C1+C2V

In case of more than two capacitors, the relation is:

1C=1C1+1C2+1C3+1C4+

Important Points:

If N identical capacitors of capacitance C are connected in series, then the effective capacitance = C/N

If N identical capacitors of capacitance C are connected in parallel, then the effective capacitance is equal to C multiplied by N

Problems on Combination of Capacitors

Problem 1: Calculate the potential difference across each capacitor when two capacitors of capacitance C1 = 6 μF and C2 = 3 μF are connected in series across a cell of emf 18 V.
  • (a) The Equivalent Capacitance
  • (b) The potential difference across each capacitor
  • (c) The Charge on Each Capacitor

Sol:

(a)

C=C1C2C1+C2=6×36+3=2μF

(b)

Q = CeqV

Substituting the values, we obtain

Q = 36 μC = 2 μF × 18 V

V1 = Q/C1 = 36 μC/ 6 μF = 6V

V2 = Q/C2 = 36 μC/ 3 μF = 12 V

The magnitude of charge Q on each capacitor when connected in series will be the same and will equal 36 μC.

Example 2: Find the equivalent capacitance between points A and B.

Answer: The equivalent capacitance between points A and B is 4 μF.

Problem 2 on Combination of Capacitors

Sol: In the system given, 1 and 3 are in parallel and 5 is connected between A and B. They can be represented as follows:

    1. As 1 and 3 are in parallel, their effective capacitance is 4μF
    1. The effective capacitance of a series circuit with 2.4μF and 2μF is 4/3μF.
    1. The effective capacitance of 3.4/3μF and 2μF in parallel is 10/3μF.
    1. The effective capacitance of a series circuit of 10/3μF and 2μF is 5/4μF.
    1. The combined capacitance of 5/4μF and 2μF in parallel is 13/4μF

Therefore, the equivalent capacitance of the given system is 13/4 μF.

Problem 2 on Combination of Capacitors - Solution