Prototypical communication systems for electrical distribution system analysis: Design basis and exemplification through co-simulation

IF 2.4 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
IET Smart Grid Pub Date : 2022-06-20 DOI:10.1049/stg2.12075
Bishnu Bhattarai, Laurentiu Marinovici, Francis Tuffner, Kevin Schneider, Xiaoyuan Fan, Frederick Rutz, Gowtham Kandaperumal
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引用次数: 2

Abstract

This paper develops prototypical communication system (PCS) models to support the analysis of electric distribution systems dependency on communication. Though there exist representative and prototypical distribution test systems, i.e., IEEE test feeders and the taxonomy of prototypical feeders, there are no standard definitions of communication systems appropriate for studies of system interdependence. To accurately represent the impact communication systems have on electric distribution system operations, the paper introduces the design basis for developing PCS models highlighting key characteristics of communication systems architectures and commonly-deployed technologies. It follows with functional definitions, implementations, and an example of how PCSs can be used for system analysis. The approach leverages existing open-source modeling and simulation tools. Co-simulation is achieved with ns-3 for PCSs, GridLAB-D\textsuperscript{\texttrademark} for distribution systems, and Python\textsuperscript{\texttrademark} for distribution system control centers. The Hierarchical Engine for Large-Scale Infrastructure Co-simulation (HELICS) environment is used to federate these individual simulators. It allows for different PCSs to be integrated with distribution systems and analyzed in different scenarios. This underlines the importance of correctly identifying network topologies and technologies and their impact on the system control strategies. Though this work uses specific tools development and implementation, the PCS models can be used in other simulation environments.

Abstract Image

配电系统分析的原型通信系统:设计基础和联合仿真实例
本文建立了典型的通信系统模型,以支持配电系统对通信依赖的分析。虽然存在代表性和原型的配电测试系统,即IEEE测试馈线和原型馈线的分类法,但没有适合研究系统相互依赖性的通信系统的标准定义。为了准确地描述通信系统对配电系统运行的影响,本文介绍了开发PCS模型的设计依据,突出了通信系统架构和常用技术的关键特征。接下来是功能定义、实现,以及如何将pcs用于系统分析的示例。该方法利用了现有的开源建模和仿真工具。采用ns-3用于pc, GridLAB-D\textsuperscript{\texttrademark}用于配电系统,Python\textsuperscript{\texttrademark}用于配电系统控制中心实现联合仿真。使用分层引擎进行大规模基础设施联合仿真(HELICS)环境来联合这些单独的模拟器。它允许不同的pcs与分配系统集成,并在不同的场景下进行分析。这强调了正确识别网络拓扑和技术及其对系统控制策略的影响的重要性。虽然这项工作使用特定的工具开发和实现,PCS模型可以在其他仿真环境中使用。
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
IET Smart Grid
IET Smart Grid Computer Science-Computer Networks and Communications
CiteScore
6.70
自引率
4.30%
发文量
41
审稿时长
29 weeks
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