The Branch-and-Bound Algorithm in Optimizing Mathematical Programming Models to Achieve Power Grid Observability

IF 1.9 3区数学 Q1 MATHEMATICS, APPLIED

Axioms Pub Date : 2023-11-08 DOI:10.3390/axioms12111040

Nikolaos P. Theodorakatos, Rohit Babu, Angelos P. Moschoudis

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引用次数: 0

Abstract

Phasor Measurement Units (PMUs) are the backbone of smart grids that are able to measure power system observability in real-time. The deployment of synchronized sensors in power networks opens up the advantage of real-time monitoring of the network state. An optimal number of PMUs must be installed to ensure system observability. For that reason, an objective function is minimized, reflecting the cost of PMU installation around the power grid. As a result, a minimization model is declared where the objective function is defined over an adequate number of constraints on a binary decision variable domain. To achieve maximum network observability, there is a need to find the best number of PMUs and put them in appropriate locations around the power grid. Hence, maximization models are declared in a decision-making way to obtain optimality satisfying a guaranteed stopping and optimality criteria. The best performance metrics are achieved using binary integer, semi-definite, and binary polynomial models to encounter the optimal number of PMUs with suitable PMU positioning sites. All optimization models are implemented with powerful optimization solvers in MATLAB to obtain the global solution point.

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优化数学规划模型实现电网可观测性的分支定界算法

相量测量单元(pmu)是智能电网的支柱，能够实时测量电力系统的可观测性。同步传感器在电网中的部署，开辟了对电网状态进行实时监测的优势。为了保证系统的可观测性，必须安装最佳数量的pmu。因此，目标函数被最小化，反映了在电网周围安装PMU的成本。因此，声明了一个最小化模型，其中目标函数在二元决策变量域上的足够数量的约束上定义。为了实现最大的网络可观察性，需要找到最佳数量的pmu，并将它们放置在电网周围的适当位置。因此，以决策的方式声明最大化模型，以获得满足保证停止和最优性标准的最优性。采用二进制整数、半确定和二进制多项式模型，在合适的PMU定位位置上遇到最优PMU数量，从而获得最佳性能指标。所有的优化模型都在MATLAB中使用强大的优化求解器来实现，以获得全局解点。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Axioms Mathematics-Algebra and Number Theory

自引率

10.00%

发文量

604

审稿时长

11 weeks

期刊介绍： Axiomatic theories in physics and in mathematics (for example, axiomatic theory of thermodynamics, and also either the axiomatic classical set theory or the axiomatic fuzzy set theory) Axiomatization, axiomatic methods, theorems, mathematical proofs Algebraic structures, field theory, group theory, topology, vector spaces Mathematical analysis Mathematical physics Mathematical logic, and non-classical logics, such as fuzzy logic, modal logic, non-monotonic logic. etc. Classical and fuzzy set theories Number theory Systems theory Classical measures, fuzzy measures, representation theory, and probability theory Graph theory Information theory Entropy Symmetry Differential equations and dynamical systems Relativity and quantum theories Mathematical chemistry Automata theory Mathematical problems of artificial intelligence Complex networks from a mathematical viewpoint Reasoning under uncertainty Interdisciplinary applications of mathematical theory.