EENG 2610: Circuit AnalysisClass 10: Capacitors and Inductors

Oluwayomi AdamoDepartment of Electrical EngineeringCollege of Engineering, University of North Texas

Capacitors and Inductors

Both are linear elements Their terminal characteristics are described by linear differential

equations. Both are storage elements

Able to absorb energy, store energy temporarily, and later supply energy to circuit. Capacitors are capable of storing energy when a voltage is present

across the element. Energy is stored in electric field. Inductors are capable of storing energy when a current is passing

through them. Energy is stored in magnetic field. Important application: op-amp integrator

It produces an output voltage that is proportional to the integral of the input voltage.

It can be used to simulate complex systems.

Capacitors A capacitor is a circuit element that consists of two conducting

surfaces separated by non-conducting, or dielectric, material. Capacitors are categorized by the type of dielectric material

used between the conducting plates. Each type is more suitable for particular applications.

Unit of capacitance is coulombs per volt, or Farad (F). Typical values range from thousands of micro-farads to a few

pico-farads.

Capacitance of two parallel plates of area ASeparated by distance d:

between.in isulator theof

y permitivit relativeor constant dielectric :

space, free ofy permitivit ticelectrosta :0

r

d

AC r 0

Cvq The charge on the capacitor is proportionalto the voltage across it:

faradsin capacitor theof ecapacitanc :C

dt

tdvCtCv

dt

d

dt

tdqti

)()}({

)()(

t

t

tdxxi

Ctvdxxi

Ctv

0

)(1

)()(1

)( 0

dt

tdvtCvtitvtp

)()()()()( Power: Energy:

C

tqtCv

dxxptwt

C

)(

2

1)(

2

1

)()(

22

dt

tdvCti

)()(

Capacitors only store and release electrostatic energy; they don’t create energy.

The capacitor is passive element and follows passive sign convention.

dt

tdvCti

)()(

dt

tdvCti

)()(

Some Characteristics of Capacitor Capacitor blocks DC current or capacitor is an open

circuit to DC current. Capacitor is often used to filter out unwanted DC

voltage/current. When analyzing a circuit containing only DC

voltage/current source, we can replace capacitors with an open circuit before analysis.

Capacitor has continuity of voltage Voltage across capacitor is always continuous.

dt

dvCi

dt

tdvtCvtitvtp

)()()()()(

dt

tdv )(v(t) is continuous!

Example 6.1: If the charge accumulated on two parallel conductors charged to 12V is 600 pC, what is the capacitance of the parallel conductors?

Example 6.2: The voltage across a 5 μF capacitor has the waveform shown in (a). Determine the current waveform.

Example 6.3: Determine the energy stored in the electric field of the capacitor in Example 6.2 at t = 6 ms.

Example 6.4: The current in an initially uncharged 4 μF capacitor is shown below. Derive the waveforms for the voltage, power, and energy and compute the energy stored at t = 2 ms.

Inductors An inductor is a circuit element that consists of a

conducting wire usually in the form of a coil. Inductors are typically categorized by the type of

core on which they are wound. Each type is more suitable for particular applications.

The unit of inductance is volt-second per ampere, or Henry (H).

dt

tdiLtv

)()(

t

t

t

dxxvL

ti

dxxvL

ti

0

)(1

)(

)(1

)(

0

Inductors only store and release electromagnetic energy; they don’t create energy.

The inductor is passive element and follows passive sign convention.

)()(

)()()( tidt

tdiLtitvtp

)(2

1)()( 2 tLidxxptw

t

L

Power:

Energy:

dt

tdiLtv

)()(

Some Characteristics of Inductors Inductor is a short circuit to DC current.

In analyzing a circuit containing only DC voltage/current source, we can replace inductors with a short circuit before analysis.

Inductor has continuity of current Current flowing through an inductor is always continuous.

dt

tdi )(

dt

tdiLtv

)()(

)()(

)()()( tidt

tdiLtitvtp

i(t) is continuous!

Example 6.5: Find the total energy stored in the circuit.

1V 2V 3V

Example 6.7: The current in a 2 mH inductor isDetermine the voltage across the inductor and the energy stored in the inductor.

A 377sin2)( tti

Example 6.8: The voltage across a 200 mH inductor is given by the following expression. Derive the waveforms for the current, energy, and power.

0 0

0 )31()(

3

t

tettv

t

Capacitor and Inductor Specifications Capacitors: capacitance, working voltage, and

tolerance The working voltage is specified to keep the applied

voltage below the breakdown point of the dielectric. Inductors: inductance, resistance, tolerance, current

rating The major difference between wire-wound resistors and

inductors is the wire material. Low resistance materials are used in inductors.