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Geometric algebra: a multivectorial proof of Tellegen's theorem in multiterminal networks

Geometric algebra: a multivectorial proof of Tellegen's theorem in multiterminal networks

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A generalised and multivectorial proof of Tellegen's theorem in multiterminal systems is presented using a new power multivector concept defined in the frequency domain. This approach permits in nonsinusoidal/linear and nonlinear situations formulating Tellegen's theorem in a novel complex-multivector representation, similar to Steinmetz's phasor model, based on complex numbers and limited to the purely sinusoidal case. In this sense, a suitable notation of voltage and current complex-vectors, associated to the elements and nodes of the network, is defined for easy development to Kirchhoff's laws in this environment. A numerical example illustrates the clear advantages of the suggested proof.

Inspec keywords: frequency-domain analysis; network analysis; vectors; multiterminal networks

Other keywords: Tellegen's theorem; current waveforms; Kirchhoff's laws; voltage complex-vectors; geometric algebra; Steinmetz's phasor model; multiterminal network system; frequency domain analysis; current complex-vectors; n-dimensional linear decomposition; periodic nonsinusoidal voltage; multivectorial proof; power multivector concept; apparent power; reactive power

Subjects: General circuit analysis and synthesis methods; Linear algebra (numerical analysis)

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