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On the Matricial Formulation of Iterative Sweep Power Flow for Radial and Meshed Distribution Networks with Guarantee of Convergence

Oscar Danilo Montoya, Walter Gil-González, Diego Armando Giral

2020Applied Sciences21 citationsDOIOpen Access PDF

Abstract

This paper presents a general formulation of the classical iterative-sweep power flow, which is widely known as the backward–forward method. This formulation is performed by a branch-to-node incidence matrix with the main advantage that this approach can be used with radial and meshed configurations. The convergence test is performed using the Banach fixed-point theorem while considering the dominant diagonal structure of the demand-to-demand admittance matrix. A numerical example is presented in tutorial form using the MATLAB interface, which aids beginners in understanding the basic concepts of power-flow programming in distribution system analysis. Two classical test feeders comprising 33 and 69 nodes are used to validate the proposed formulation in comparison with conventional methods such as the Gauss–Seidel and Newton–Raphson power-flow formulations.

Topics & Concepts

Iterative methodMathematical optimizationMathematicsNewton's methodConvergence (economics)Gauss–Seidel methodPower flowDiagonalApplied mathematicsComputer sciencePower (physics)Electric power systemNonlinear systemGeometryEconomicsEconomic growthQuantum mechanicsPhysicsOptimal Power Flow DistributionElectric Power System OptimizationSmart Grid Energy Management