Operation Strategy of Smart Thermostats That Self-Learn User Preferences

Smart thermostats can automatically adjust indoor temperature based on user preferences to save electricity bills without significantly comprising comfort. However, current smart thermostats usually require users to master programming or require a significant amount of user behavior observations to enable automatic control, which is demanding and adverse to their popularization. In this paper, we propose a practical method that enables a smart thermostat to track user preferences and derive the optimal temperature setting schedule. We assume that users are rational and aim to minimize their overall costs. First, we propose a Bayesian-inference-based method that can quickly learn user preferences with a limited number of user behavior observations. We then generate the optimal temperature setting schedule via a stochastic expected value model. Finally, we propose an operation strategy under which a thermostat can work automatically and continuously. The “virtual user” case study indicates that the proposed method can quickly yield a satisfying probabilistic estimate of user preferences based on even only 10 observations. The “real user” case study demonstrates that the method can dynamically track user preferences and continuously generate optimal temperature setting schedules to reduce overall costs an average of 12 percent. Based on the proposed method, users can conveniently enjoy a customized temperature zone with a lower overall cost.

[1]  Dimitrios Soudris,et al.  A Flexible Decision-Making Mechanism Targeting Smart Thermostats , 2017, IEEE Embedded Systems Letters.

[2]  Zijun Zhang,et al.  Short-Term Electricity Price Forecasting With Stacked Denoising Autoencoders , 2017, IEEE Transactions on Power Systems.

[3]  Peter Boait,et al.  A method for fully automatic operation of domestic heating. , 2010 .

[4]  Cajo J. F. ter Braak,et al.  Selection properties of type II maximum likelihood (empirical Bayes) in linear models with individual variance components for predictors , 2012, Pattern Recognit. Lett..

[5]  Antonio Muñoz San Roque,et al.  Forecasting Functional Time Series with a New Hilbertian ARMAX Model: Application to Electricity Price Forecasting , 2018, IEEE Transactions on Power Systems.

[6]  Therese Peffer,et al.  Original research articleEnergy efficiency and the misuse of programmable thermostats: The effectiveness of crowdsourcing for understanding household behavior , 2015 .

[7]  James O. Berger,et al.  Ockham's Razor and Bayesian Analysis , 1992 .

[8]  S. A. Al-Sanea,et al.  Optimized monthly-fixed thermostat-setting scheme for maximum energy-savings and thermal comfort in air-conditioned spaces , 2008 .

[9]  Kamin Whitehouse,et al.  The smart thermostat: using occupancy sensors to save energy in homes , 2010, SenSys '10.

[10]  Matthew M. Peet,et al.  Optimal Thermostat Programming for Time-of-Use and Demand Charges With Thermal Energy Storage and Optimal Pricing for Regulated Utilities , 2017, IEEE Transactions on Power Systems.

[11]  D. Menniti,et al.  Purchase-Bidding Strategies of an Energy Coalition With Demand-Response Capabilities , 2009, IEEE Transactions on Power Systems.

[12]  Keith F. Brill,et al.  Precipitation and Temperature Forecast Performance at the Weather Prediction Center , 2014 .

[13]  Bo Zhao,et al.  Stochastic Optimal Operation of Microgrid Based on Chaotic Binary Particle Swarm Optimization , 2016, IEEE Transactions on Smart Grid.

[14]  Lance M. Leslie,et al.  A Single-Station Approach to Model Output Statistics Temperature Forecast Error Assessment , 2005 .

[15]  K. A. Antonopoulos,et al.  Numerical simulation of cooling energy consumption in connection with thermostat operation mode and comfort requirements for the Athens buildings , 2011 .

[16]  Mark W. Newman,et al.  Learning from a learning thermostat: lessons for intelligent systems for the home , 2013, UbiComp.

[17]  Nadeem Javaid,et al.  Energy Management With a World-Wide Adaptive Thermostat Using Fuzzy Inference System , 2018, IEEE Access.

[18]  Jong-Jin Kim,et al.  ANN-based thermal control models for residential buildings , 2010 .

[19]  K. Davis,et al.  A multi-site analysis of random error in tower-based measurements of carbon and energy fluxes , 2006 .

[20]  Elias B. Kosmatopoulos,et al.  A low-complexity control mechanism targeting smart thermostats , 2017 .

[21]  Yin Xu,et al.  Strategic Bidding and Compensation Mechanism for a Load Aggregator With Direct Thermostat Control Capabilities , 2018, IEEE Transactions on Smart Grid.

[22]  Liangzhong Yao,et al.  Forming Bidding Curves for a Distribution System Operator , 2018, IEEE Transactions on Power Systems.

[23]  Therese Peffer,et al.  Usability of residential thermostats: Preliminary investigations , 2011 .

[24]  Geoff Green,et al.  Living in cold homes after heating improvements: Evidence from Warm-Front, England’s Home Energy Efficiency Scheme , 2007 .

[25]  Therese Peffer,et al.  How people use thermostats in homes: A review , 2011, Building and Environment.

[26]  Yanhong Li,et al.  Expected value model for optimizing the multiple bus headways , 2013, Appl. Math. Comput..

[27]  Ned Djilali,et al.  Transactive control of fast-acting demand response based on thermostatic loads in real-time retail electricity markets , 2018 .