Phasor Calculator

An advanced tool for phasor arithmetic in electrical engineering and physics. Perform addition, subtraction, multiplication, and division of complex numbers in polar or rectangular form.

Phasor A

Phasor B

Calculation Results

Result in Polar Form

Result in Rectangular Form

Phasor A (Rectangular)

Phasor B (Rectangular)

Phasor Diagram (Argand Plane)

This diagram visualizes Phasor A (blue), Phasor B (green), and the Resultant Phasor (red) on the complex plane. The horizontal axis is the Real axis, and the vertical axis is the Imaginary axis.

What is a Phasor Calculator?

A phasor calculator is a specialized engineering tool designed to simplify the mathematics of sinusoidal waves, which are fundamental to AC (Alternating Current) circuits. In physics and electrical engineering, a phasor is a complex number that represents the amplitude and phase of a sinusoid. This calculator allows users to perform arithmetic operations—addition, subtraction, multiplication, and division—on these complex numbers, instantly providing results in both polar (magnitude and angle) and rectangular (real and imaginary) forms. It eliminates tedious manual conversions and calculations, making AC circuit analysis faster and less error-prone.

Anyone working with AC circuits, from students to professional engineers, can benefit from a phasor calculator. It is essential for tasks like calculating total impedance in series/parallel circuits, determining voltage drops, and analyzing power factor. A common misunderstanding is that phasors represent frequency; however, phasors are used when all components in a system share the same frequency, which is factored out of the calculation, simplifying the problem significantly.

Phasor Calculator Formula and Explanation

A phasor can be represented in two primary forms: Rectangular and Polar. The ability to convert between them is key to phasor arithmetic.

• Rectangular Form: Z = a + jb, where ‘a’ is the real component and ‘b’ is the imaginary component.
• Polar Form: Z = r∠θ, where ‘r’ is the magnitude (amplitude) and ‘θ’ is the phase angle in degrees.

Conversions are handled using these formulas:

• Polar to Rectangular: a = r * cos(θ), b = r * sin(θ)
• Rectangular to Polar: r = sqrt(a² + b²), θ = atan2(b, a)

Operations follow specific rules:
Addition and subtraction are easiest in rectangular form. Multiplication and division are easiest in polar form. This phasor calculator automates these conversions. For a more detailed look at the math, consider our article on AC theory basics.

Variables Table

Key variables in phasor calculations. The unit for magnitude is typically Volts (V) or Amps (A) but is considered unitless here for general-purpose calculation.

Variable	Meaning	Unit	Typical Range
r (or |Z|)	Magnitude	Unitless, V, A, Ω	0 to ∞
θ (or arg(Z))	Phase Angle	Degrees (°) or Radians (rad)	-180° to +180° or 0° to 360°
a (or Re(Z))	Real Part	Unitless, V, A, Ω	-∞ to ∞
b (or Im(Z))	Imaginary Part	Unitless, V, A, Ω	-∞ to ∞

Practical Examples

Example 1: Adding Two Voltages

Imagine two voltage sources in series in an AC circuit. V1 is 120V with a 30° phase lead, and V2 is 100V with a 45° phase lag. How do we find the total voltage?

• Input V1 (Phasor A): Magnitude = 120, Angle = 30°
• Input V2 (Phasor B): Magnitude = 100, Angle = -45°
• Operation: Addition (+)
• Result: The phasor calculator first converts both to rectangular form (V1 ≈ 103.92 + j60, V2 ≈ 70.71 – j70.71). It then adds the components to get (174.63 – j10.71). Finally, it converts back to polar form, giving a resultant voltage of approximately 174.96V at an angle of -3.51°.

Example 2: Calculating Impedance

In AC circuits, impedance (Z) is the complex opposition to current. Let’s find the current (I) flowing through an impedance Z given a voltage V, using Ohm’s Law for AC: I = V / Z. For this, you could use an Ohm’s law calculator adapted for AC.

• Input V (Phasor A): Magnitude = 50V, Angle = 0°
• Input Z (Phasor B): Magnitude = 10Ω, Angle = 53.13° (representing a resistor and inductor)
• Operation: Division (/)
• Result: The phasor calculator divides the magnitudes (50 / 10 = 5) and subtracts the angles (0 – 53.13 = -53.13). The resulting current is 5A at an angle of -53.13°. This indicates the current lags the voltage.

How to Use This Phasor Calculator

Using this calculator is straightforward:

1. Select Input Format: For each phasor (A and B), choose whether you will enter it in Polar (magnitude and angle) or Rectangular (real and imaginary) form. The inputs will adjust automatically.
2. Enter Values: Fill in the corresponding input fields for both phasors. Angles should be entered in degrees.
3. Choose Operation: Select the desired arithmetic operation (+, -, *, /) from the dropdown menu between the two phasors.
4. Interpret Results: The calculator instantly updates. The primary result is shown in a large font in polar form. Below, you’ll find the result in rectangular form and the rectangular equivalents of your input phasors.
5. Analyze the Diagram: The phasor diagram provides a visual representation of your inputs and the result, which is crucial for understanding the geometric relationships in impedance calculation.

Key Factors That Affect Phasor Calculations

• Correct Form for Operation: Remember to use rectangular for addition/subtraction and polar for multiplication/division. The calculator handles this, but it’s a key conceptual point.
• Angle Units (Degrees vs. Radians): This calculator uses degrees, which is common in many textbooks. However, internal math functions often use radians, so correct conversion is critical. Failure to do so leads to incorrect results.
• Component Signs: The quadrant of the phasor is determined by the signs of the real and imaginary parts. Be careful with negative signs, especially in the rectangular form.
• Reference Phasor: In circuit analysis, one phasor (usually a voltage source) is often set as the reference with an angle of 0°. All other phase angles are measured relative to it.
• Magnitude Units: Ensure all input magnitudes (Volts, Amps, Ohms) are consistent. While the calculator is unitless, real-world problems require unit consistency.
• Frequency (ω): While not an input to the calculator, it is assumed that all phasors in a given calculation operate at the same frequency. This is a fundamental principle of phasor analysis. For calculating frequency-dependent properties, see our reactance calculator.

Frequently Asked Questions (FAQ)

1. What is the ‘j’ in ‘a + jb’?

In electrical engineering, ‘j’ is used to represent the imaginary unit (the square root of -1) instead of ‘i’ to avoid confusion with the symbol for current (i). This phasor calculator uses ‘j’ in its notation for the same reason.

2. Why are addition and subtraction done in rectangular form?

Because it allows for simple component-wise addition. To add (a + jb) + (c + jd), you simply add the real parts (a+c) and the imaginary parts (b+d) separately, resulting in (a+c) + j(b+d). Doing this in polar form is mathematically complex.

3. Why are multiplication and division done in polar form?

It’s much simpler. To multiply (r1∠θ1) * (r2∠θ2), you multiply the magnitudes (r1 * r2) and add the angles (θ1 + θ2). To divide, you divide the magnitudes and subtract the angles. Rectangular multiplication is more work (requiring the FOIL method).

4. Can this calculator handle different units?

The calculator is numerically agnostic. You can work with Volts, Amps, or Ohms, as long as you are consistent. For example, if you divide a voltage phasor by a current phasor, the resulting magnitude will have units of Ohms (impedance).

5. What does a negative phase angle mean?

A negative phase angle signifies a “lagging” waveform. For example, if current has a negative angle relative to voltage, the current waveform reaches its peak after the voltage waveform. This is typical in inductive circuits.

6. Does the phasor diagram work for all operations?

Yes, the diagram visually represents Phasor A, Phasor B, and the final Resultant Phasor for all four arithmetic operations. It’s especially intuitive for addition, where you can see the “head-to-tail” vector addition.

7. What is the difference between a phasor and a vector?

A phasor is a specific type of vector that represents a sinusoidal signal. It is a “phase vector” that is ‘frozen’ in time. While all phasors can be treated as vectors on the complex plane, not all vectors are phasors.

8. How does this relate to a complex number calculator?

A phasor is a complex number. This tool is essentially a complex number calculator tailored with the language and defaults (like angles in degrees) common in electrical engineering. The underlying mathematics are identical.

Related Tools and Internal Resources

Enhance your understanding of AC circuits and related concepts with these resources:

• Ohm’s Law Calculator: For basic DC and AC circuit calculations.
• Reactance Calculator: Calculate inductive and capacitive reactance based on frequency.
• AC Theory Basics: An introduction to the fundamental concepts of alternating current.
• Understanding Impedance: A deep dive into the concept of complex impedance in AC circuits.
• Power Factor Calculator: Analyze efficiency in AC power systems.
• Series and Parallel Circuits: Learn how to combine components and apply phasor analysis.