RL-RC Circuits & Applications

SVES Circuits Theory

Introduction

• In this chapter, phasor algebra will be used to develop a quick, direct method for solving both the series and the parallel ac circuits.

• Describe the relationship between current and voltage in an RC & RL circuits • Determine impedance and phase angle in RC and RL circuits

Impedance and the Phasor Diagram

• Resistive Elements • Use  R =0° in the following polar format to ensure the proper phase relationship between the voltage and the current resistance: • The boldface Roman quantity

Z

R

, having both magnitude and an associate angle, is referred to as the

impedance

of a resistive element.

• Z

R

is not a phasor since it does not vary with time.

• Even though the format R  0° is very similar to the phasor notation for sinusoidal current and voltage, R and its associated angle of 0° are fixed, non-varying quantities.

Resistive

ac circuit.

Resistive

ac circuit Voltage is 100 volts Peak

Waveforms for Last Example

Resistive

Phasor diagram of Example

Resistive

20.0

100

Analysis of Resistive Circuits

• The application of Ohm’s law to series circuits involves the use of the quantities Z, V, and I as:

V = IZ I = V/Z Z = V/I R = Z

Impedance and the Phasor Diagram

• Capacitive Reactance (

X C

) • Use 

C

= – 90° in the following polar format for capacitive reactance to ensure the proper phase relationship between the voltage and current of an capacitor: • The boldface roman quantity

Z

c

, having both magnitude and an associated angle, is referred to as the

impedance

of a capacitive element.

Impedance and the Phasor Diagram

•

Z C

is measured in ohms and is a measure of how much the capacitive element will “control or impede” the level of current through the network.

• This format like the one for the resistive element, will prove to be a useful “tool” in the analysis of ac networks.

• Be aware that

Z C

is not a phasor quantity for the same reason indicated for a resistive element.

Analysis of Capacitive ac Circuit

• The current leads the voltage by 90  in a purely capacitive ac circuit

Capacitive ac circuit.

Capacitive ac circuit, Voltage is 15 volts peak

Waveforms for Example current leads the voltage by 90 degrees

Phasor diagrams for Example 7.50

15.00

Impedance and the Phasor Diagram

• Inductive Reactance (

X L

) • Use  L = 90° in the following polar format for inductive reactance to ensure the proper phase relationship between the voltage and the current of an inductor: • The boldface roman quantity

Z

L

, having both magnitude and an associated angle, in referred to as the

impedance

of an inductive element.

Impedance and the Phasor Diagram

•

Z L

is measured in ohms and is a measure of how much the inductive element will “control or impede” the level of current through the network.

• This format like the one for the resistive element, will prove to be a useful “tool” in the analysis of ac networks.

• Be aware that

Z

L

is not a phasor quantity for the same reason indicated for a resistive element.

Inductive ac circuit.

Inductive ac circuit Voltage is 24 volts Peak

Inductor Waveforms for Example voltage leads the current by 90 degrees

Phasor diagrams for Example.

8.0

24.0 V

Three cases of impedance R – C series circuit

Illustration of sinusoidal response with general phase relationships of

V R

, phase;

V V C R

, and leads

I V

relative to the source voltage.

V R S

;

V C

lags

V S

; and

V R

and

V C

and

I

are in the are 90º out of phase.

Impedance of a series

RC

circuit.

Development of the impedance triangle for a series

RC

circuit.

Impedance of a series

RC

circuit.

Impedance of a series

RC

circuit.

Phase relation of the

voltages and current

in a series

RC

circuit .

Voltage and current phasor diagram for the waveforms

Voltage diagram for the voltage in a R-C circuit

Voltage diagram for the voltage in a R-C circuit

An illustration of how

Z

and

X C

change with frequency.

As the frequency increases,

X C

 decreases,

Z

decreases, and decreases. Each value of frequency can be visualized as forming a different impedance triangle.

Illustration of sinusoidal response with general phase relationships of

V V R R

,

V L

, and lags

V S I

relative to the source voltage.

V R

; and

V L

leads

V S

.

V R

and

V L

and

I

are in phase; are 90º out of phase with each other.

Impedance of a series

RL

circuit.

Development of the Impedance triangle for a series

RL

circuit.

Impedance of a series

RL

circuit.

Impedance of a series

RL

circuit.

Phase relation of current and voltages in a series

RL

circuit.

Voltage phasor diagram for the waveforms .

Voltage and current phasor diagram for the waveforms

61 V Voltages of a series

RL

circuit.

Voltages of a series

RL

circuit.

Reviewing the frequency response of the basic elements.

Frequency Selectivity of RC Circuits

• Frequency-selective circuits permit signals of certain frequencies to pass from the input to the output, while blocking all others • A

low-pass circuit

is realized by taking the output across the capacitor, just as in a

lag network

• A

high-pass circuit

is implemented by taking the output across the resistor, as in a

lead network

The

RC

lag network (

V out

=

V C

)

FIGURE 10-17

An illustration of how

Z

and

X C

change with frequency.

Frequency Selectivity of RC Circuits

• The frequency at which the capacitive reactance equals the resistance in a low pass or high-pass RC circuit is called the

cutoff frequency:

f

c

= 1/(2



RC)

Normalized

general response curve of a low-pass

RC

circuit showing the cutoff frequency and the bandwidth - 3 dB point normalized Cutoff point

Example of low-pass filtering action. As frequency increases,

V out

decreases

The

RC

lead network (

V out

=

V R

)

Example of high-pass filtering action. As frequency increases,

V out

increases

High-pass filter responses.

High-pass filter responses, filters in series Each r-c combination

- 20dB / decade

Observing changes in

Z

and

X L

with frequency by watching the meters and recalling Ohm’s law

RL Circuit as a Low-Pass Filter

• An inductor acts as a short to dc • As the frequency is increased, so does the inductive reactance – As inductive reactance increases, the output voltage across the resistor decreases – A series RL circuit, where output is taken across the resistor, finds application as a low pass filter

Example of low-pass filtering action. Winding resistance has been neglected. As the input frequency increases, the output voltage decreases

RL Circuit as a High-Pass Filter

• For the case when output voltage is measured across the inductor – At dc, the inductor acts a short, so the output voltage is zero – As frequency increases, so does inductive reactance, resulting in more voltage being dropped across the inductor – The result is a high-pass filter

FIGURE 12-39

Example of high-pass filtering action. Winding resistance has been neglected. As the input frequency increases, the output voltage increases.