CPS: Synergy: Collaborative Research: SMARTER - Smart Manager for Adaptive and Real-Time Decisions in Building ClustERs

CPS：协同：协作研究：SMARTER - 构建集群中自适应和实时决策的智能管理器

• 批准号: 1239093
• 负责人: Kemper Lewis
• 金额: $ 20万
• 依托单位: SUNY at Buffalo
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-10-01 至 2017-03-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1239093&HistoricalAwards=false
• 关键词: CPS; Synergy; Collaborative; Research; SMARTER

1239257 (Wu). Traditionally, buildings have been viewed as mere energy consumers; however, with the new power grid infrastructure and distributed energy resources, buildings can not only consume energy, but they can also output energy. As a result, this project removes traditional boundaries between buildings in the same cluster or between the cluster and power grids, transforming individual smart buildings into NetZero building clusters enabled by cyber-support tools. In this research, a synergistic decision framework is established for temporally, spatially distributed building clusters to work as an adaptive and robust system within a smart grid. The framework includes innovative algorithms and tools for building energy modeling, intelligent data fusion, decentralized decisions and adaptive decisions to address theoretical and practical challenges in next-generation building systems. The research develops cyber-physical engineering tools for demand side load management which has been identified as a major challenge by energy industries. It fundamentally transforms the current centralized and uni-directional power distribution business model to a decentralized and multi-directional power sharing and distribution business model, reducing overall energy consumption and allowing for optimal decisions in changing operation environments. Education and outreach efforts include developing novel educational modules disseminated at the K-12 levels and through the ASEE eGFI repository. Further educational impact occurs through integration with multiple undergraduate and graduate courses at each institution, and with community service groups. Impact is also expanded to the broader energy industry and the operation of healthcare delivery and urban transportation systems through our industry collaborations. http://swag.engineering.asu.edu/ 1239247 (Wen). Traditionally, buildings have been viewed as mere energy consumers; however, with the new power grid infrastructure and distributed energy resources, buildings can not only consume energy, but they can also output energy. As a result, this project removes traditional boundaries between buildings in the same cluster or between the cluster and power grids, transforming individual smart buildings into NetZero building clusters enabled by cyber-support tools. In this research, a synergistic decision framework is established for temporally, spatially distributed building clusters to work as an adaptive and robust system within a smart grid. The framework includes innovative algorithms and tools for building energy modeling, intelligent data fusion, decentralized decisions and adaptive decisions to address theoretical and practical challenges in next-generation building systems. The research develops cyber-physical engineering tools for demand side load management which has been identified as a major challenge by energy industries. It fundamentally transforms the current centralized and uni-directional power distribution business model to a decentralized and multi-directional power sharing and distribution business model, reducing overall energy consumption and allowing for optimal decisions in changing operation environments. Education and outreach efforts include developing novel educational modules disseminated at the K-12 levels and through the ASEE eGFI repository. Further educational impact occurs through integration with multiple undergraduate and graduate courses at each institution, and with community service groups. Impact is also expanded to the broader energy industry and the operation of healthcare delivery and urban transportation systems through our industry collaborations. http://swag.engineering.asu.edu/ 1239093 (Lewis). Traditionally, buildings have been viewed as mere energy consumers; however, with the new power grid infrastructure and distributed energy resources, buildings can not only consume energy, but they can also output energy. As a result, this project removes traditional boundaries between buildings in the same cluster or between the cluster and power grids, transforming individual smart buildings into NetZero building clusters enabled by cyber-support tools. In this research, a synergistic decision framework is established for temporally, spatially distributed building clusters to work as an adaptive and robust system within a smart grid. The framework includes innovative algorithms and tools for building energy modeling, intelligent data fusion, decentralized decisions and adaptive decisions to address theoretical and practical challenges in next-generation building systems. The research develops cyber-physical engineering tools for demand side load management which has been identified as a major challenge by energy industries. It fundamentally transforms the current centralized and uni-directional power distribution business model to a decentralized and multi-directional power sharing and distribution business model, reducing overall energy consumption and allowing for optimal decisions in changing operation environments. Education and outreach efforts include developing novel educational modules disseminated at the K-12 levels and through the ASEE eGFI repository. Further educational impact occurs through integration with multiple undergraduate and graduate courses at each institution, and with community service groups. Impact is also expanded to the broader energy industry and the operation of healthcare delivery and urban transportation systems through our industry collaborations.

1239257（吴）。 传统上，建筑物仅被视为能源消耗者。然而，随着新的电网基础设施和分布式能源的出现，建筑物不仅可以消耗能源，还可以输出能源。因此，该项目消除了同一集群中建筑物之间或集群与电网之间的传统界限，将单个智能建筑转变为由网络支持工具支持的 NetZero 建筑集群。在这项研究中，为时间、空间分布的建筑集群建立了一个协同决策框架，使其作为智能电网中的自适应和鲁棒系统。 该框架包括用于建筑能源建模、智能数据融合、分散决策和自适应决策的创新算法和工具，以解决下一代建筑系统的理论和实践挑战。 该研究开发了用于需求侧负荷管理的网络物理工程工具，这已被能源行业视为一项重大挑战。它从根本上改变了当前集中式、单向的电力分配业务模式，向分散式、多向的电力共享和分配业务模式转变，降低了整体能源消耗，并允许在不断变化的运营环境中做出最佳决策。教育和推广工作包括开发新颖的教育模块，并通过 ASEE eGFI 存储库在 K-12 级别进行传播。通过与每个机构的多个本科生和研究生课程以及社区服务团体的整合，可以产生进一步的教育影响。通过我们的行业合作，影响力还扩展到更广泛的能源行业以及医疗保健服务和城市交通系统的运营。 http://swag.engineering.asu.edu/1239247（文）。 传统上，建筑物仅被视为能源消耗者。然而，随着新的电网基础设施和分布式能源的出现，建筑物不仅可以消耗能源，还可以输出能源。因此，该项目消除了同一集群中建筑物之间或集群与电网之间的传统界限，将单个智能建筑转变为由网络支持工具支持的 NetZero 建筑集群。在这项研究中，为时间、空间分布的建筑集群建立了一个协同决策框架，使其作为智能电网中的自适应和鲁棒系统。该框架包括用于建筑能源建模、智能数据融合、分散决策和自适应决策的创新算法和工具，以解决下一代建筑系统的理论和实践挑战。该研究开发了用于需求侧负荷管理的网络物理工程工具，这已被能源行业视为一项重大挑战。它从根本上改变了当前集中式、单向的电力分配业务模式，向分散式、多向的电力共享和分配业务模式转变，降低了整体能源消耗，并允许在不断变化的运营环境中做出最佳决策。教育和推广工作包括开发新颖的教育模块，并通过 ASEE eGFI 存储库在 K-12 级别进行传播。通过与每个机构的多个本科生和研究生课程以及社区服务团体的整合，可以产生进一步的教育影响。通过我们的行业合作，影响力还扩展到更广泛的能源行业以及医疗保健服务和城市交通系统的运营。 http://swag.engineering.asu.edu/1239093（刘易斯）。 传统上，建筑物仅被视为能源消耗者。然而，随着新的电网基础设施和分布式能源的出现，建筑物不仅可以消耗能源，还可以输出能源。因此，该项目消除了同一集群中建筑物之间或集群与电网之间的传统界限，将单个智能建筑转变为由网络支持工具支持的 NetZero 建筑集群。在这项研究中，为时间、空间分布的建筑集群建立了一个协同决策框架，使其作为智能电网中的自适应和鲁棒系统。该框架包括用于建筑能源建模、智能数据融合、分散决策和自适应决策的创新算法和工具，以解决下一代建筑系统的理论和实践挑战。该研究开发了用于需求侧负荷管理的网络物理工程工具，这已被能源行业视为一项重大挑战。它从根本上改变了当前集中式、单向的电力分配业务模式，向分散式、多向的电力共享和分配业务模式转变，降低了整体能源消耗，并允许在不断变化的运营环境中做出最佳决策。教育和推广工作包括开发新颖的教育模块，并通过 ASEE eGFI 存储库在 K-12 级别进行传播。通过与每个机构的多个本科生和研究生课程以及社区服务团体的整合，可以产生进一步的教育影响。通过我们的行业合作，影响力还扩展到更广泛的能源行业以及医疗保健服务和城市交通系统的运营。