Phasor (electronics)
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See wikibooks' book on [Phasors]
A phasor is a constant complex number representing the complex amplitude (magnitude and phase) of a sinusoidal function of time. It is usually expressed in exponential form. Phasors are used in engineering to simplify computations involving sinusoids, where they can often reduce a differential equation problem to an algebraic one.
Introduction
A sinusoid (or sine waveform) is defined to be a function of the form (the reason for using cosine rather than sine will become apparent later)
- [y=A\cos\,\!]
- y is the quantity that is varying with time
- φ is a constant (in radians) known as the phase or phase angle of the sinusoid
- A is a constant known as the amplitude of the sinusoid. It is the peak value of the function.
- ω is the angular frequency given by [\omega=2\pi f] where f is frequency.
- t is time.
- [y=\Re \Big(A\big(\cost+\phi)}+j\sin\big)\Big)\,\!]
- j is the imaginary unit [\sqrt]. Note that i is not used in electrical engineering as it is commonly used to represent the changing current.
- [\Re (z)] gives the real part of the complex number z
- [y=\Re(Ae^t+\phi)})\,\!]
- [y=\Re(Ae^e^t})\,\!]
- [Y = Ae^\,]
- [y=\Re(Ye^t})\,\!]
- [Y = A \angle \phi \,]
Phasor Calculus
When sinusoids are represented as phasors, differential equations become algebraic equations. This result follows from the fact that the complex exponential is the eigenfunction of the derivative operation:
- [\frac(e^) = j \omega e^]
- [\frac \cos = - \omega \sin\,]
As an example, consider the following differential equation for the voltage across the capacitor in an RC circuit:
- [\frac + \fracv_C = \fracv_S]
- [v_S(t) = V_P \cos(\omega t + \phi)\,]
- [j \omega V_c + \frac V_c = \fracV_s]
- [V_s = V_P e^\,]
- [V_c = \frac V_s]
- [V_c = \frac}e^ V_s]
- [\theta(\omega) = -\arctan(\omega RC)\,]
- [v_C(t) = \frac} V_P \cos(\omega t + \phi + \theta(\omega))]
Circuit laws
With phasors, the techniques for solving DC circuits can be applied to solve AC circuits. A list of the basic laws is given below.- Ohm's law for resistors: a resistor has no time delays and therefore doesn't change the phase of a signal therefore V=IR remains valid.
- Ohm's law for resistors, inductors, and capacitors: V=IZ where Z is the complex impedance.
- In an AC circuit we have real power (P) which is a representation of the average power into the circuit and reactive power (Q) which indicates power flowing back and forward. We can also define the complex power S=P+jQ and the apparent power which is the magnitude of S. The power law for an AC circuit expressed in phasors is then S=VI* (where I* is the complex conjugate of I).
- Kirchhoff's circuit laws work with phasors in complex form
Phasor transform
The phasor transform or phasor representation allows transformation from complex form to trigonometric form:
[ V_m e^ = \mathcal \ ]
where the notation [ \mathcal \ ] is read "the phasor transform of ____."
The phasor transform transfers the sinusoidal function from the time domain to the complex-number domain or frequency domain.
Inverse phasor transform
The inverse phasor transform [ \mathcal^ ] allows one to move back from the phasor domain to the time domain.[ V_m cos( \omega t + \phi ) = \mathcal^ \ \} = \Re \ e^ \} ]
Phasor arithmetic
As with other complex quantities the exponential (polar) form [Ae^]simplifies multiplication and division, while the Cartesian (rectangular) form [a+jb] simplifies addition and subtraction.
See also
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