JoVE Logo
Auteurs
Contactez-nous

S'identifier

6.12 : Thévenin Equivalent Circuits

The household power distribution system, encompassing distribution lines and transformers, serves as the primary network. Electrical appliances within a household can be represented as load impedance. To simplify this intricate distribution system, Thévenin's theorem can be applied to create a Thévenin equivalent circuit. If an AC circuit is partitioned into two parts (circuit A and circuit B), connected by a single pair of terminals as shown in Figure 1.

Parallel circuit diagram, Circuit A and B, voltage nodes a and b, electrical analysis equipment.

Figure 1: Circuit portioned into two parts

circuit analysis diagram with open-circuit voltage and impedance, parallel circuit configuration

Figure 2:Circuit A replaced by its Thévenin equivalent circuit

Replacing circuit A with its Thévenin equivalent circuit (a voltage source in series with an impedance) does not alter the current or voltage of any element in circuit B (shown in Figure 2). The values of the currents and voltages of all the circuit elements in circuit B will be the same irrespective of whether circuit B is connected to circuit A or its Thévenin equivalent. Two parameters are required to find the Thévenin equivalent circuit: the Thévenin voltage and the Thévenin impedance. Figure 3 shows an open circuit connected across the terminals of circuit A to determine the open-circuit voltage Voc , while Figure 4 indicates that the Thévenin impedance Zt is the equivalent impedance of circuit A*.

Circuit diagram; electrical setup for open-circuit voltage analysis (Voc) with labeled terminals a, b.

Figure 3:Thévenin equivalent circuit with Voc .

Circuit diagram of Circuit A with terminals a and b, representing impedance Zt connection.

Figure 4:Thévenin equivalent circuit showing Zt. .

Circuit A* is formed from circuit A by replacing all independent voltage sources with short circuits and all independent current sources with open circuits. Generally, the Thévenin impedance Zt can be determined by replacing series or parallel impedances with equivalent impedances repeatedly.

Tags

Th venin Equivalent CircuitHousehold Power DistributionLoad ImpedanceTh venin s TheoremAC CircuitTh v nin VoltageTh venin ImpedanceOpen circuit VoltageEquivalent ImpedanceCircuit Analysis

Du chapitre 6:

article

Now Playing

6.12 : Thévenin Equivalent Circuits

AC Circuit Analysis

177 Vues

article

6.1 : Sinusoidal Sources

AC Circuit Analysis

463 Vues

article

6.2 : Graphical and Analytic Representation of Sinusoids

AC Circuit Analysis

363 Vues

article

6.3 : Phasors

AC Circuit Analysis

478 Vues

article

6.4 : Phasor Arithmetics

AC Circuit Analysis

236 Vues

article

6.5 : Phasor Relationships for Circuit Elements

AC Circuit Analysis

474 Vues

article

6.6 : Kirchoff's Laws using Phasors

AC Circuit Analysis

380 Vues

article

6.7 : Impedances and Admittance

AC Circuit Analysis

541 Vues

article

6.8 : Impedance Combination

AC Circuit Analysis

306 Vues

article

6.9 : Node Analysis for AC Circuits

AC Circuit Analysis

279 Vues

article

6.10 : Mesh Analysis for AC Circuits

AC Circuit Analysis

332 Vues

article

6.11 : Source Transformation for AC Circuits

AC Circuit Analysis

510 Vues

article

6.13 : Norton Equivalent Circuits

AC Circuit Analysis

324 Vues

article

6.14 : Superposition Theorem for AC Circuits

AC Circuit Analysis

595 Vues

article

6.15 : Op Amp AC Circuits

AC Circuit Analysis

173 Vues

See More

JoVE Logo

Confidentialité

Conditions d'utilisation

Politiques

Contactez-nous

RECOMMANDER À LA BIBLIOTHÈQUE

NEWSLETTERS JoVE

Recherche

Enseignement

Auteurs

Bibliothécaires

À PROPOS DE JoVE

Copyright © 2025 MyJoVE Corporation. Tous droits réservés.