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Readers of this book will be shown how, with the adoption of ubiquituous sensing, extensive data-gathering and forecasting, and building-embedded advanced actuation, intelligent building systems with the ability to respond to occupant preferences in a safe and energy-efficient manner are becoming a reality. The articles collected present a holistic perspective on the state of the art and current research directions in building automation, advanced sensing and control, including:
model-based and model-free control design for temperature control;smart lighting systems;smart sensors and
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Produktbeschreibung
Readers of this book will be shown how, with the adoption of ubiquituous sensing, extensive data-gathering and forecasting, and building-embedded advanced actuation, intelligent building systems with the ability to respond to occupant preferences in a safe and energy-efficient manner are becoming a reality. The articles collected present a holistic perspective on the state of the art and current research directions in building automation, advanced sensing and control, including:

model-based and model-free control design for temperature control;smart lighting systems;smart sensors and actuators (such as smart thermostats, lighting fixtures and HVAC equipment with embedded intelligence); andenergy management, including consideration of grid connectivity and distributed intelligence.

These articles are both educational for practitioners and graduate students interested in design and implementation, and foundational for researchers interested in understanding the state of the art and the challenges that must be overcome in realizing the potential benefits of smart building systems. This edited volume also includes case studies from implementation of these algorithms/sensing strategies in to-scale building systems. These demonstrate the benefits and pitfalls of using smart sensing and control for enhanced occupant comfort and energy efficiency.
Autorenporträt
John T. Wen has extensive industrial and academic experience in control systems. He received his B.Eng. from McGill University, M.S. from University of Illinois, Ph.D. from Rensselaer Polytechnic Institute, all in Electrical Engineering. He worked at Fisher Controls and Jet Propulsion Laboratory before joining Rensselaer Polytechnic Institute in 1988. He is now a Professor in the Electrical, Computer, and Systems Engineering. He was the Director of the Center for Automation Technologies and Systems (CATS) from 2005-2013, and has been the Head of the Industrial and Systems Engineering since 2013. He was awarded the 2013 IEEE Control Systems Society Transition to Practice Award based on the co-invention of the Adaptive Scanning Optical Microscope (ASOM), which was licensed to Thorlabs. His research interest lies in the modeling and control of dynamical systems with applications to motion control, robot manipulation, opto-mechatronics, thermal management, and active flow control. He isa Fellow of the IEEE. Sandipan Mishra received his B.Tech. in Mechanical Engineering from the Indian Institute of Technology Madras in 2002 and his Ph.D. in Mechanical Engineering from the University of California at Berkeley in 2008. Dr. Mishra joined Rensselaer Polytechnic Institute as a faculty in the Mechanical, Aerospace, and Nuclear Engineering Department in Fall 2010. He is the recipient of the NSF Early CAREER award in 2013 on additive manufacturing and was a member of the 2010 Japan NXT-NSF Young investigator exchange program for nanomanufacturing. His research interests are in the area of systems and control theory, learning control, nonlinear estimation, and precision mechatronics, as applied to smart building systems, additive manufacturing, and adaptive optics.