Cyber-Physical System for Energy-Efficient Stadium Operation

The environmental impacts of medium to large-scale buildings receive substantial attention in research, industry, and media. This article studies the energy savings potential of a commercial soccer stadium during day-to-day operation. Buildings of this kind are characterized by special purpose system installations like grass heating systems and by event-driven usage patterns. This work presents a methodology to holistically analyze the stadium’s characteristics and integrate its existing instrumentation into a Cyber-Physical System, enabling to deploy different control strategies flexibly. In total, seven different strategies for controlling the studied stadium’s grass heating system are developed and tested in operation. Experiments in winter season 2014/2015 validated the strategies’ impacts within the real operational setup of the Commerzbank Arena, Frankfurt, Germany. With 95% confidence, these experiments saved up to 66% of median daily weather-normalized energy consumption. Extrapolated to an average heating season, this corresponds to savings of 775MWh and 148t of CO2 emissions. In winter 2015/2016 an additional predictive nighttime heating experiment targeted lower temperatures, which increased the savings to up to 85%, equivalent to 1GWh (197t CO2) in an average winter. Beyond achieving significant energy savings, the different control strategies also met the target temperature levels to the satisfaction of the stadium’s operational staff. While the case study constitutes a significant part, the discussions dedicated to the transferability of this work to other stadiums and other building types show that the concepts and the approach are of general nature. Furthermore, this work demonstrates the first successful application of Deep Belief Networks to regress and predict the thermal evolution of building systems.

[1]  M. Thesis Green stadiums: as green as grass , 2012 .

[2]  Hossein Tabari,et al.  Comparison of artificial neural network and multivariate linear regression methods for estimation of daily soil temperature in an arid region , 2011 .

[3]  Yacine Rezgui,et al.  An ANN-GA Semantic Rule-Based System to Reduce the Gap Between Predicted and Actual Energy Consumption in Buildings , 2017, IEEE Transactions on Automation Science and Engineering.

[4]  Hermann Merz,et al.  Building Automation: Communication systems with EIB/KNX, LON and BACnet , 2009 .

[5]  Rogerio Cichota,et al.  ANALYTICAL SOIL–TEMPERATURE MODEL , 2004 .

[6]  P. Willems,et al.  Short‐term forecasting of soil temperature using artificial neural network , 2015 .

[7]  Ruslan Salakhutdinov,et al.  Learning Deep Generative Models , 2009 .

[8]  Mehmet Bilgili,et al.  Estimating soil temperature using neighboring station data via multi-nonlinear regression and artificial neural network models , 2012, Environmental Monitoring and Assessment.

[9]  Mischa Schmidt,et al.  Energy Efficiency Gains in Daily Grass Heating Operation of Sports Facilities through Supervisory Holistic Control , 2015, BuildSys@SenSys.

[10]  J. B. Beard Turfgrass Root Basics , 2012 .

[11]  Andrew Kusiak,et al.  Multi-objective optimization of the HVAC (heating, ventilation, and air conditioning) system performance , 2015 .

[12]  Mischa Schmidt,et al.  The energy efficiency problematics in sports facilities: identifying savings in daily grass heating operation , 2015, ICCPS.

[13]  Thomas R. H. Holmes,et al.  Estimating the soil temperature profile from a single depth observation: A simple empirical heatflow solution , 2008 .

[14]  M. Bilgili Prediction of soil temperature using regression and artificial neural network models , 2010 .

[15]  T. M. Leung,et al.  A review on Life Cycle Assessment, Life Cycle Energy Assessment and Life Cycle Carbon Emissions Assessment on buildings , 2015 .

[16]  Ozgur Kisi,et al.  Modeling soil temperatures at different depths by using three different neural computing techniques , 2015, Theoretical and Applied Climatology.

[17]  Razvan Pascanu,et al.  Theano: new features and speed improvements , 2012, ArXiv.

[18]  Vijay P. Singh,et al.  Modeling daily soil temperature using data-driven models and spatial distribution , 2014, Theoretical and Applied Climatology.

[19]  António E. Ruano,et al.  The IMBPC HVAC system: A complete MBPC solution for existing HVAC systems , 2016 .

[20]  Edward A. Lee Cyber Physical Systems: Design Challenges , 2008, 2008 11th IEEE International Symposium on Object and Component-Oriented Real-Time Distributed Computing (ISORC).

[21]  Dardo Oscar Guaraglia,et al.  Predicting Temperature and Heat Flow in a Sandy Soil by Electrical Modeling , 2001 .

[22]  Yee Whye Teh,et al.  A Fast Learning Algorithm for Deep Belief Nets , 2006, Neural Computation.

[23]  Nai-Jia Guo,et al.  Spatiotemporal modeling of monthly soil temperature using artificial neural networks , 2013, Theoretical and Applied Climatology.

[24]  Giuseppe Tommaso Costanzo,et al.  Experimental analysis of data-driven control for a building heating system , 2015, ArXiv.