### Abstract

This paper presents a time domain model for the representation of powers in linear and nonlinear electrical circuits. The model can account, in a physical (or engineering) sense, for `active and reactive powers' as functions of time. The model is based on the time domain decomposition of the instantaneous power p(t) into two components: p(t) = a(t)+r(t). Where, a(t) represents the instantaneous power consumed by the (linear or nonlinear) load. The information regarding the store/restore process is contained in r(t). In contrast with the traditional frequency domain model in which powers are defined orthogonal (i.e. S
^{2} = P
^{2}+Q
^{2}+D
^{2}+ ...) and therefore they do not interact with each other, the proposed model permits the interaction of active and reactive powers at every instant. Using the model of the paper we can obtain the instantaneous power needed for compensation of both, wave shape and power factor.

Original language | English (US) |
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Title of host publication | IEEE Engineering Society, Winter Meeting |

Editors | Anon |

Publisher | IEEE |

Pages | 914 |

Number of pages | 1 |

Volume | 2 |

State | Published - 1999 |

Event | Proceedings of the 1999 Winter Meeting of IEEE Power Engineering Society. Part 1 (of 2) - New York, NY, USA Duration: Jan 31 1999 → Feb 4 1999 |

### Other

Other | Proceedings of the 1999 Winter Meeting of IEEE Power Engineering Society. Part 1 (of 2) |
---|---|

City | New York, NY, USA |

Period | 1/31/99 → 2/4/99 |

### Fingerprint

### ASJC Scopus subject areas

- Engineering(all)

### Cite this

*IEEE Engineering Society, Winter Meeting*(Vol. 2, pp. 914). IEEE.

**Physical time domain representation of powers in linear and nonlinear electrical circuits.** / Cohen, Jose; De Leon, Francisco; Hernandez, Luis M.

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

*IEEE Engineering Society, Winter Meeting.*vol. 2, IEEE, pp. 914, Proceedings of the 1999 Winter Meeting of IEEE Power Engineering Society. Part 1 (of 2), New York, NY, USA, 1/31/99.

}

TY - GEN

T1 - Physical time domain representation of powers in linear and nonlinear electrical circuits

AU - Cohen, Jose

AU - De Leon, Francisco

AU - Hernandez, Luis M.

PY - 1999

Y1 - 1999

N2 - This paper presents a time domain model for the representation of powers in linear and nonlinear electrical circuits. The model can account, in a physical (or engineering) sense, for `active and reactive powers' as functions of time. The model is based on the time domain decomposition of the instantaneous power p(t) into two components: p(t) = a(t)+r(t). Where, a(t) represents the instantaneous power consumed by the (linear or nonlinear) load. The information regarding the store/restore process is contained in r(t). In contrast with the traditional frequency domain model in which powers are defined orthogonal (i.e. S 2 = P 2+Q 2+D 2+ ...) and therefore they do not interact with each other, the proposed model permits the interaction of active and reactive powers at every instant. Using the model of the paper we can obtain the instantaneous power needed for compensation of both, wave shape and power factor.

AB - This paper presents a time domain model for the representation of powers in linear and nonlinear electrical circuits. The model can account, in a physical (or engineering) sense, for `active and reactive powers' as functions of time. The model is based on the time domain decomposition of the instantaneous power p(t) into two components: p(t) = a(t)+r(t). Where, a(t) represents the instantaneous power consumed by the (linear or nonlinear) load. The information regarding the store/restore process is contained in r(t). In contrast with the traditional frequency domain model in which powers are defined orthogonal (i.e. S 2 = P 2+Q 2+D 2+ ...) and therefore they do not interact with each other, the proposed model permits the interaction of active and reactive powers at every instant. Using the model of the paper we can obtain the instantaneous power needed for compensation of both, wave shape and power factor.

UR - http://www.scopus.com/inward/record.url?scp=0032686274&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=0032686274&partnerID=8YFLogxK

M3 - Conference contribution

VL - 2

SP - 914

BT - IEEE Engineering Society, Winter Meeting

A2 - Anon, null

PB - IEEE

ER -