Symmetrical components

In electrical engineering, the method of symmetrical components simplifies analysis of unbalanced three-phase power systems under both normal and abnormal conditions. The basic idea is that an asymmetrical set of N phasors can be expressed as a linear combination of N symmetrical sets of phasors by means of a complex linear transformation.[1] Fortescue's theorem (symmetrical components) is based on superposition principle,[2] so it is applicable to linear power systems only, or to linear approximations of non-linear power systems.

In the most common case of three-phase systems, the resulting "symmetrical" components are referred to as direct (or positive), inverse (or negative) and zero (or homopolar). The analysis of power system is much simpler in the domain of symmetrical components, because the resulting equations are mutually linearly independent if the circuit itself is balanced.[3]

  1. ^ Hadjsaïd, Nouredine; Sabonnadière, Jean-Claude (2013). Power Systems and Restructuring. John Wiley & Sons. p. 244. ISBN 9781118599921.
  2. ^ Mathis, Wolfgang; Pauli, Rainer (1999). Network Theorems. Wiley Online Library. doi:10.1002/047134608X.W2507. ISBN 047134608X. […] the results of Fortescue […] are proven by the superposition theorem, and for this reason, a direct generalization to nonlinear networks is impossible.
  3. ^ Blackburn, J. Lewis (1993-06-07). Symmetrical Components for Power Systems Engineering (1st ed.). New York: CRC Press. ISBN 978-0-8247-8767-7.