Online Distributed Optimization in Radial Power Distribution Systems: Closed-Form Expressions

Sadnan, Rabayet; Asaki, Tom; Dubey, Anamika

doi:10.48550/arxiv.2109.01208

Cited by 1 publication

(1 citation statement)

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“…The macro-iteration stops when the shared boundary variables reach a consensus among all the neighbors, and then the decision variables are dispatched within the area. The consensus at the boundary can also be achieved using other Fixed Point Iteration methods [13], [16].…”

Section: B Distributed Opf (D-opf) Problemsmentioning

confidence: 99%

Distributed Optimization in Distribution Systems with Grid-Forming and Grid-Supporting Inverters

Sadnan¹,

Dubey²

2022

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With massive penetrations of active grid-edge technologies, distributed computing and optimization paradigm has gained significant attention to solve distribution-level optimal power flow (OPF) problems. However, the application of generic distributed optimization techniques to OPF problems leads to a very large number of macro-iterations or communication rounds among the distributed computing agents delaying the decisionmaking process or resulting in suboptimal solutions. Moreover, the existing distribution-level OPF problems typically model inverter-interfaced distributed energy resources (DERs) as gridfollowing inverters; grid-supporting and grid-forming functionalities have not been explicitly considered. The added complexities introduced by different inverter models require further attention to developing an appropriate model for new types of inverterbased DERs and computationally-tractable OPF algorithms. In this paper, we expand the distribution-level OPF model to include a combination of the grid-forming, grid-supporting, gridfollowing inverter-based DERs and also present the application of a domain-specific problem decomposition and distributed algorithm for the topologically radial power distribution systems to efficiently solve distribution-level OPF problem.

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Section: B Distributed Opf (D-opf) Problemsmentioning

confidence: 99%