Phasor Representation and Complex Numbers in AC Circuits

In alternating current (AC) circuit analysis, the behavior of sinusoidal voltages and currents can be complex due to their time-varying nature. To simplify analysis, engineers commonly use phasors and complex numbers—mathematical tools that transform sinusoidal waveforms into manageable, steady-state quantities.

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What Is a Phasor?

A phasor is a complex number that represents a sinusoidal waveform—like voltage or current—as a rotating vector in the complex plane.

A typical sinusoidal voltage is written as:

$$v(t) = V_{\text{peak}} \cdot \sin(\omega t + \phi)$$

Where:

• $V_{\text{peak}}$ = Peak voltage

• $\omega$ = Angular frequency in radians/second

• $\phi$ = Phase angle

• $t$ = Time

In phasor form, this becomes:

$$V = V_{\text{RMS}} \angle \phi$$

Where:

• $V_{\text{RMS}}$ = Root Mean Square value

• $\angle \phi$= Phase angle

Phasor notation transforms a time-varying signal into a constant vector, simplifying circuit analysis.

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Why Use Phasors?

Phasors convert differential equations into algebraic equations, allowing easier manipulation of sinusoidal AC signals. Key advantages include:

• Simplified operations: Addition, subtraction, multiplication, and division become straightforward.

• Vector visualization: Phasors show both magnitude and phase.

• Efficient analysis: Engineers can analyze circuits using basic algebra instead of calculus.

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Complex Numbers in AC Circuit Analysis

Phasors are expressed using complex numbers, which have both real and imaginary components:

Rectangular Form:

$$Z = x + jy$$Where:

• $x$ = Real part

• $y$ = Imaginary part

• $j$ = Imaginary unit ($\sqrt{-1}$; $j$ is used in electrical engineering to avoid confusion with current, $i$)

Polar Form:

$$Z = |Z| \angle \theta$$

Where:

• $|Z|$ = Magnitude

• $\theta$ = Phase angle (in degrees or radians)

This representation is key to describing voltages, currents, and impedances in AC systems.

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Application: Complex Impedance of Circuit Elements

Every passive component in an AC circuit has a complex impedance $Z$, which relates voltage and current phasors using Ohm’s Law:

$$V = I \cdot Z$$Impedances:

• Resistor: $Z_R = R$ (purely real)

• Inductor: $Z_L = j\omega L$ (positive imaginary)

• Capacitor:

$$Z_C = \frac{1}{j\omega C} = -j \cdot \frac{1}{\omega C}$$

(negative imaginary)

Where:

• $\omega = 2\pi f$: Angular frequency

• $f$: Frequency in Hz

These expressions allow for uniform treatment of different components using phasor algebra.

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Benefits of Phasor and Complex Number Analysis

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Summary Table

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Conclusion

Phasor representation and complex numbers are essential tools in AC circuit analysis. They turn time-domain problems into steady-state solutions, making the design, analysis, and troubleshooting of AC systems significantly more efficient and intuitive.

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