Components, Run-time Substrates, and Systems: Medium: Holonic Multi-Agent Control of Intelligent Power Distribution Systems

组件、运行时基板和系统：中：智能配电系统的完整多智能体控制

• 批准号: 1136040
• 负责人: Anil Pahwa
• 金额: $ 110万
• 依托单位: Kansas State University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-09-01 至 2016-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1136040&HistoricalAwards=false
• 关键词: Components; Run; time; Substrates; Systems

Holonic Multi-Agent Control of Intelligent Power Distribution Systems This project will demonstrate a Holonic Multiagent System Architecture capable of adaptively controlling future electrical power distribution systems (PDS), which are expected to include a large number of renewable power generators, energy storage devices, and advanced metering and control devices. The project will produce a general, extensible, and secure cyber architecture based on holonic multiagent principles to support adaptive PDS. It will produce new analytical insights to quantify the impact of information delay, quality and flow on the design and analysis of the PDS architecture. Finally, it will develop a novel approach to automating PDS with high penetration of distributed renewable resources for higher efficiency, reliability, security, and resiliency.The complex nature of future PDS will require them to adapt reactively and proactively to normal and anomalous modes of operation. The architecture produced by this project will be capable of optimizing performance and maintaining the system within operating limits during normal and minor events, such as cloud cover that reduces solar panels output. The architecture will also allow the operation of a distribution system as an island in emergencies, such as hurricanes/earthquakes, grid failures, or terrorist acts. The project will inspire future engineers via a simulation that will allow students to inject faults, failures, and weather events to see how an intelligent PDS will respond. These activities will combine cyber- and physical expertise, thus creating a workforce prepared for tomorrow?s cyber-physical system challenges. Existing university programs will be used to involve under-represented minorities and U.S. veterans in the project.

智能配电系统的全息多智能体控制该项目将展示一种全息多智能体系统架构，能够自适应控制未来的电力配电系统（PDS），该系统预计将包括大量可再生能源发电机、能量存储设备和先进的计量和控制设备。该项目将产生一个通用的、可扩展的、安全的基于整体多代理原则的网络架构，以支持自适应PDS。它将产生新的分析见解，以量化信息延迟、质量和流对PDS体系结构设计和分析的影响。最后，它将开发一种新的方法来自动化PDS，分布式可再生资源的高渗透，以提高效率、可靠性、安全性和弹性。未来PDS的复杂性将要求它们积极主动地适应正常和异常的操作模式。该项目产生的建筑将能够优化性能，并在正常和轻微事件（如云层减少太阳能电池板输出）的情况下保持系统在运行范围内。该架构还将允许配电系统在紧急情况下作为孤岛运行，例如飓风/地震、电网故障或恐怖主义行为。该项目将通过模拟来启发未来的工程师，该模拟将允许学生注入故障、故障和天气事件，以了解智能PDS如何响应。这些活动将结合网络和物理专业知识，从而创造一支为明天做好准备的劳动力队伍。S网络物理系统挑战。现有的大学课程将被用来让少数族裔和美国退伍军人参与该项目。