Circuit Theory/Complex Power

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Just like the other values of voltage, current, and resistance, power also has a complex phasor quantity that we are going to become familiar with. Complex power is denoted with a ${\displaystyle 𝕊}$ symbol. It is calculated as such:

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${\displaystyle 𝕊=\frac{𝕍{𝕀}^{*}}{2}}$

Where the quantity ${\displaystyle {𝕀}^{*}}$ denotes the complex conjugate of the phasor current. To get the complex conjugate of ${\displaystyle 𝕀}$, we have two formulas:

Given: ${\displaystyle 𝕀=A+jB=M\mathrm{\angle }\varphi }$

• ${\displaystyle {𝕀}^{*}=A-jB}$ (rectangular)
• ${\displaystyle {𝕀}^{*}=M\mathrm{\angle }-\varphi }$ (polar)

There is more information on complex conjugation of phasors in the Appendix.

If we take the magnitude of our Complex power variable, we get the following:

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${\displaystyle |𝕊|=\frac{|𝕍||{𝕀}^{*}|}{2}}$

Where ${\displaystyle |𝕊|}$ is called the apparent power. It is this quantity that we can measure, because it makes no sense to measure an imaginary number or a complex value.

Let us break up our voltage and current phasors for a moment:

${\displaystyle 𝕍=M_v\mathrm{\angle }{\varphi }_v}$, and ${\displaystyle 𝕀=M_i\mathrm{\angle }{\varphi }_i}$

if we plug those two values into our equation for complex power, above, we get the following:

${\displaystyle 𝕊=\frac{(M_v\mathrm{\angle }{\varphi }_v)(M_i\mathrm{\angle }-{\varphi }_i)}{2}=\frac{M_v{M}_i}{2}\mathrm{\angle }({\varphi }_v-{\varphi }_i)}$

We can then convert this quantity into rectangular form where:

${\displaystyle 𝕊=P+jQ}$

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${\displaystyle P=\frac{M_v{M}_i}{2}\cos ({\varphi }_v-{\varphi }_i)}$

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${\displaystyle Q=\frac{M_v{M}_i}{2}\sin ({\varphi }_v-{\varphi }_i)}$

We call P the Average Power and Q the Reactive Power. We will discuss these quantities later.

Unfortunately, Power is not as simple a quantity as impedance. Unlike Impedance and resistance, The different power quantities do not all share the same units. We list the units for each type of power, below:

Time-Domain Power

Watts (w)

Average Power

Watts (w)

Complex Power

Volt-Amps (VA)

Reactive Power

Volt-Amps Reactive (VAR)

Technically, all these units are equatable, but they are called different things as a matter of common convention.

Complex power can be expressed in terms of impedance and complex current, using the following formula:

${\displaystyle 𝕊=\left(\frac{I_m^2}{2}\right)\mathrm{Re}(\mathbb{Z})+j\left(\frac{I_m^2}{2}\right)\mathrm{Im}(\mathbb{Z})}$

If the element in question is a resistor, the reactive power delivered will be 0. Likewise, if the element is a capacitor or an inductor, the average power delivered will be zero. If the impedance is complex, then the delivered power will be complex.

Power in a circuit is conserved. Therefore, the following equation holds true:

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${\displaystyle \sum _{circuit}\frac{𝕍{𝕀}^{*}}{2}=0}$

Remember that sources supply power, and that impedance elements (resistors, capacitors and inductors) absorb power.

The relationship between the average power, and the apparent power is called the power factor. Power factor is given the variable ${\displaystyle p_f}$, and is calculated as such:

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${\displaystyle p_f=\cos ({\varphi }_v-{\varphi }_i)}$

There is also a quantity called the power-factor angle, which is equal to the differences in phase angle between the current and the voltage:

${\displaystyle p_{fangle}={\varphi }_v-{\varphi }_i}$

Since the cosine is an even function, the following values are equal:

${\displaystyle \cos ({\varphi }_v-{\varphi }_i)=\cos ({\varphi }_i-{\varphi }_v)}$

This means that to be able to accurately calculate the phase angles of the current and the voltage from the power factor, we need an additional specifier of either leading or lagging.

Lagging

The phase angle of the voltage is greater then the phase angle for the current.

${\displaystyle {\varphi }_V>{\varphi }_I}$

Leading

The phase angle of the current is greater then the phase angle for the voltage.

${\displaystyle {\varphi }_V<{\varphi }_I}$

Similarly to DC power, AC power has it's own maximum power transfer theorem that can be expressed in terms of phasors.

Maximum power transfer is attained when, for a thevenin equivalent source with an impedance ${\displaystyle {\mathbb{Z}}_{thevenin.}}$, the load impedance is:

${\displaystyle {\mathbb{Z}}_{thevenin}={\mathbb{Z}}_{load}^{*}}$

In plain english, the source impedance must be the complex conjugate of the load impedance, to attain maximum power transfer.