Litcius/Paper detail

Geometric Algebra Framework Applied to Symmetrical Balanced Three-Phase Systems for Sinusoidal and Non-Sinusoidal Voltage Supply

Francisco G. Montoya, Raúl Baños, Alfredo Alcayde, Francisco M. Arrabal‐Campos, Javier Roldán‐Pérez

2021Mathematics14 citationsDOIOpen Access PDF

Abstract

This paper presents a new framework based on geometric algebra (GA) to solve and analyse three-phase balanced electrical circuits under sinusoidal and non-sinusoidal conditions. The proposed approach is an exploratory application of the geometric algebra power theory (GAPoT) to multiple-phase systems. A definition of geometric apparent power for three-phase systems, that complies with the energy conservation principle, is also introduced. Power calculations are performed in a multi-dimensional Euclidean space where cross effects between voltage and current harmonics are taken into consideration. By using the proposed framework, the current can be easily geometrically decomposed into active- and non-active components for current compensation purposes. The paper includes detailed examples in which electrical circuits are solved and the results are analysed. This work is a first step towards a more advanced polyphase proposal that can be applied to systems under real operation conditions, where unbalance and asymmetry is considered.

Topics & Concepts

Geometric algebraPolyphase systemHarmonicsThree-phaseCurrent (fluid)Power (physics)Compensation (psychology)VoltageEuclidean spaceElectronic circuitComputer scienceAlgebra over a fieldMathematicsTopology (electrical circuits)Electronic engineeringElectrical engineeringMathematical analysisEngineeringPure mathematicsAlgebra representationPhysicsPsychoanalysisPsychologyQuantum mechanicsCombinatoricsAlgebraic and Geometric Analysis
Geometric Algebra Framework Applied to Symmetrical Balanced Three-Phase Systems for Sinusoidal and Non-Sinusoidal Voltage Supply | Litcius