智能互联建筑设计自动化:基础与趋势

Mehdi Maasoumy, A. Sangiovanni-Vincentelli
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引用次数: 28

摘要

建筑物是多物理场子系统复杂集成的结果。除了明显的土木工程基础设施外,热力、电气、机械、控制、通信和计算子系统必须共存并运行,以使整体运行平稳高效。这对商业建筑尤其重要,但对住宅建筑尤其是公寓建筑也非常相关。不幸的是,这些子系统的设计和部署很少是同步的:照明、安全、供暖、通风和空调系统通常是独立设计的。然而,简单地将子系统集合在一起,尽管经过优化,却导致了今天的低效建筑。在世界范围内,建筑物消耗了42%的电力,比任何其他资产都要多,而且可以证明,如果采用整体的设计、部署和运营方法,可以减少大部分电力消耗。政府机构、学术机构、建筑承包商和业主已经意识到建筑对全球环境、电网和他们组织的使命的重大影响。然而,对所有选区的经济影响仍难以评估。政府法规可以发挥根本作用,就像交通运输行业的情况一样,排放和燃料消耗法规一直是汽车设计创新的最重要因素。我们相信,通过利用技术和系统级方法来设计建筑,它们将提供舒适、安全和功能,同时最大限度地降低能源成本,支持强大的电网并减轻对环境的影响。实现这一愿景需要从设计阶段开始,到部署,从调试到运行,一直到建筑生命周期结束,都要增加智能。在本期中,我们试图提供一个尽可能完整的智能互联建筑设计自动化领域的活动概述,试图使愿景成为现实。这些活动的总体范围包括开发用于建筑物建模和设计的仿真工具,以及因此提出的使建筑物更智能和更高效的控制算法。此外,我们将检讨在现实世界和实体建筑物上大规模实施这种控制策略。然后,我们提出了一种正式的协同设计方法来设计建筑物,认为建筑物是网络物理系统的主要例子,其中虚拟世界和物理世界相遇,因为恒温器等更传统的产品能够在线连接并执行复杂的计算任务来有效地控制建筑物温度。我们完成了描述建筑在智能电网运行中日益增长的作用的演讲,在智能电网中,建筑不仅是能源的消费者,而且本身也是电网服务和能源的提供者。这本专著的读者是在智能建筑、智能城市和智能电网领域工作的行业专业人士和研究人员,重点是能源效率、仿真工具、最优控制和新兴电力市场的网络物理系统。
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Smart Connected Buildings Design Automation: Foundations and Trends
Buildings are the result of a complex integration of multi-physics subsystems. Besides the obvious civil engineering infrastructure, thermal, electrical, mechanical, control, communication and computing subsystems must co-exist and be operated so that the overall operation is smooth and efficient. This is particularly important for commercial buildings but is also very relevant for residential buildings especially apartment buildings. Unfortunately, the design and deployment of these subsystems is rarely synchronized: lighting, security, heating, ventilation and air conditioning systems are often designed independently. However, simply putting together a collection of sub-systems, albeit optimized, has led to the inefficient buildings of today. Worldwide, buildings consume 42% of all electrical power - more than any other asset - and it can be proven that much of this can be reduced if a holistic approach to design, deployment, and operation is taken. Government agencies, academic institutions, building contractors and owners have realized the significant impact of buildings on the global environment, the electrical grid, and the mission of their organizations. However, the economic impact for all constituencies is still difficult to assess. Government regulations can play a fundamental role, as it has been the case for the transportation industry where regulations on emission and fuel consumption have been the single most important factor of innovation in automotive design. We are convinced that by leveraging technology and utilizing a system-level approach to buildings, they will provide comfort, safety and functionality while minimizing energy cost, supporting a robust electric grid and mitigating environmental impact. Realizing this vision requires adding intelligence from the beginning of the design phase, to deployment, from commissioning to operation, all the way to the end of the building's life cycle. In this issue, we attempt to provide an as-complete-as-possible overview of the activities in the field of smart connected building design automation that attempts to make the vision a reality. The overarching range of such activities includes developing simulation tools for modeling and the design of buildings, and consequently control algorithms proposed to make buildings smarter and more efficient. Furthermore, we will review real-world and large-scale implementation of such control strategies on physical buildings. We then present a formal co-design methodology to design buildings, taking the view that buildings are prime examples of cyber-physical systems where the virtual and physical worlds meet as more traditional products such as thermostats are able to connect online and perform complicated computational tasks to control building temperature effectively. We complete the presentation describing the growing role of buildings in the operation of the smart grid where buildings are not only consumers of energy, but are themselves also providers of services and energy to the grid. The audiences for this monograph are industry professionals and researchers who work in the area of smart buildings, smart cities, and smart grid, with emphasis on energy efficiency, simulation tools, optimal control, and cyber-physical systems for the emerging power markets.
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Foundations and Trends in Electronic Design Automation
Foundations and Trends in Electronic Design Automation ENGINEERING, ELECTRICAL & ELECTRONIC-
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期刊介绍: Foundations and Trends® in Electronic Design Automation publishes survey and tutorial articles in the following topics: - System Level Design - Behavioral Synthesis - Logic Design - Verification - Test - Physical Design - Circuit Level Design - Reconfigurable Systems - Analog Design Each issue of Foundations and Trends® in Electronic Design Automation comprises a 50-100 page monograph written by research leaders in the field.
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