6.11 : Source Transformation for AC Circuits

Consider a circuit composed of a current source and a combination of resistors, capacitors, and inductors with known impedance values.

The aim is to utilize the source transformation technique to determine the voltage drop across the circuit's right-most branch.

Using source transformation, a current source in parallel with an impedance can be converted into a voltage source in series with the same impedance or vice-versa.

By applying Ohm's law, the source voltage is calculated. This value can then be expressed in terms of phasor.

In the transformed circuit, the impedance is in series with the voltage source, along with the other two elements of the top branch. The equivalent series impedance is obtained.

Now, the source transformation technique is applied again to convert the voltage source back into a current source.

Next, the impedance of the new parallel combination is obtained, which is utilized to transform the current source back into a voltage source.

Finally, the voltage division rule determines the voltage drop across the right-most branch.

The process of source transformation in the frequency domain entails the conversion of a voltage source, positioned in series with an impedance, into a current source that is parallel to an impedance, or the other way around. It is essential to maintain the following relationships while transitioning from one source type to another.

Equation1

Equation2

In order to determine the unknown voltage for a circuit composed of a current source and a collection of resistors, capacitors, and inductors - each with their distinct known impedance, a series of steps are followed. Initially, the voltage source is converted into a current source, and the values of the source current (I_s) and impedance (Z_s) are established.

Subsequently, transforming the current source back to a voltage source results in a different circuit. From this derived circuit, the source voltage (V_s) is calculated using the previously determined values. Finally, by applying the voltage division rule, the unknown voltage across the resistance can be identified.

Tags

Source Transformation AC Circuits Voltage Source Current Source Impedance Frequency Domain Unknown Voltage Circuit Analysis Resistors Capacitors Inductors Voltage Division Rule

来自章节 6:

article

Now Playing

6.11 : Source Transformation for AC Circuits

AC Circuit Analysis

511 Views

article

6.1 : Sinusoidal Sources

AC Circuit Analysis

463 Views

article

6.2 : Graphical and Analytic Representation of Sinusoids

AC Circuit Analysis

363 Views

article

6.3 : Phasors

AC Circuit Analysis

479 Views

article

6.4 : Phasor Arithmetics

AC Circuit Analysis

236 Views

article

6.5 : Phasor Relationships for Circuit Elements

AC Circuit Analysis

474 Views

article

6.6 : Kirchoff's Laws using Phasors

AC Circuit Analysis

380 Views

article

6.7 : Impedances and Admittance

AC Circuit Analysis

542 Views

article

6.8 : Impedance Combination

AC Circuit Analysis

306 Views

article

6.9 : Node Analysis for AC Circuits

AC Circuit Analysis

279 Views

article

6.10 : Mesh Analysis for AC Circuits

AC Circuit Analysis

333 Views

article

6.12 : Thévenin Equivalent Circuits

AC Circuit Analysis

177 Views

article

6.13 : Norton Equivalent Circuits

AC Circuit Analysis

324 Views

article

6.14 : Superposition Theorem for AC Circuits

AC Circuit Analysis

595 Views

article

6.15 : Op Amp AC Circuits

AC Circuit Analysis

173 Views

See More

版权所属 © 2025 MyJoVE 公司版权所有，本公司不涉及任何医疗业务和医疗服务。