HeatFlex: Machine learning based data-driven flexibility prediction for individual heat pumps

With their rising adoption and integration into smart grids, heat pumps are becoming an increasingly important source of flexible energy. Heat pump flexibility can be utilized by using controllers to remotely manage their operation while maintaining the temperature within predefined user comfort bounds. Traditional indoor temperature modelling approaches require detailed information about the deployment site, device specific parameters and monitored data, making them inapplicable for the majority of heat pump deployments. This paper proposes a novel data-driven machine learning based method HeatFlex for indoor temperature forecasting and flexibility prediction using only 3 monitored variables: indoor and outdoor temperatures and heat pump power consumption. HeatFlex enables plug-and-play flexibility prediction from heat pumps without requiring exact device and building specifications or installation of additional sensors. This paper also introduces novel flexibility metrics enabling quantitative evaluation of heat pump flexibility prediction performance. HeatFlex is based on deep learning predictive models: Long Short-Term Memory (LSTM) and Gated Recurrent Unit (GRU) recurrent neural networks. Our experimental evaluation compared these networks with traditional multivariate linear regression and SARIMAX time series forecasting model baselines. HeatFlex performance was qualitatively and quantitatively evaluated using data from three real-world heat pump deployments with different building sizes, heat pump types and specifications. Experimental results indicate that HeatFlex is effective to accurately predict over 90% of available potential flexibility.

[1]  Paula Carroll,et al.  Air Source Heat Pumps field studies: A systematic literature review , 2020 .

[2]  Chen Yongjian,et al.  Predictive analysis of indoor temperature and humidity based on BP neural network single-step prediction method , 2020, 2020 IEEE 3rd International Conference on Information Systems and Computer Aided Education (ICISCAE).

[3]  Ralf Mikut,et al.  Forecasting energy time series with profile neural networks , 2020, e-Energy.

[4]  Ming Li,et al.  Practice and Application of LSTM in Temperature Prediction of HVAC System , 2020, 2020 IEEE 5th Information Technology and Mechatronics Engineering Conference (ITOEC).

[5]  Yan Zhao,et al.  Heating Load Forecasting for Combined Heat and Power Plants Via Strand-Based LSTM , 2020, IEEE Access.

[6]  Yunpeng Ma,et al.  Hourly Heat Load Prediction Model Based on Temporal Convolutional Neural Network , 2020, IEEE Access.

[7]  Torben Bach Pedersen,et al.  pgFMU: Integrating Data Management with Physical System Modelling , 2020, EDBT.

[8]  Mary E. Kaye,et al.  An Improved Temperature Prediction Technique for HVAC Units Using Intelligent Algorithms , 2019, 2019 IEEE Energy Conversion Congress and Exposition (ECCE).

[9]  Ping-Huan Kuo,et al.  Multiple-Input Deep Convolutional Neural Network Model for Short-Term Photovoltaic Power Forecasting , 2019, IEEE Access.

[10]  Torben Bach Pedersen,et al.  Modeling and Managing Energy Flexibility Using FlexOffers , 2018, 2018 IEEE International Conference on Communications, Control, and Computing Technologies for Smart Grids (SmartGridComm).

[11]  Marc-Andre Triebel,et al.  A Concept for Controlling Heat Pump Pools Using the Smart Grid Ready Interface , 2018, 2018 IEEE PES Innovative Smart Grid Technologies Conference Europe (ISGT-Europe).

[12]  Neil Hewitt,et al.  How heat pumps and thermal energy storage can be used to manage wind power: A study of Ireland , 2018, Energy.

[13]  Soumya Kanti Datta,et al.  IoT and Machine Learning Based Prediction of Smart Building Indoor Temperature , 2018, 2018 4th International Conference on Computer and Information Sciences (ICCOINS).

[14]  Torben Bach Pedersen,et al.  Day-ahead Trading of Aggregated Energy Flexibility , 2018, e-Energy.

[15]  Giansalvo Cirrincione,et al.  Indoor Air-Temperature Forecast for Energy-Efficient Management in Smart Buildings , 2018, 2018 IEEE International Conference on Environment and Electrical Engineering and 2018 IEEE Industrial and Commercial Power Systems Europe (EEEIC / I&CPS Europe).

[16]  Bo Thiesson,et al.  Utilizing Device-level Demand Forecasting for Flexibility Markets , 2018, e-Energy.

[17]  P. Domanski,et al.  Selecting HVAC Systems to Achieve Comfortable and Cost-effective Residential Net-Zero Energy Buildings. , 2018, Applied energy.

[18]  Guokun Lai,et al.  Modeling Long- and Short-Term Temporal Patterns with Deep Neural Networks , 2017, SIGIR.

[19]  George Edwards,et al.  A Review of Deep Learning Methods Applied on Load Forecasting , 2017, 2017 16th IEEE International Conference on Machine Learning and Applications (ICMLA).

[20]  Torben Bach Pedersen,et al.  Generation and Evaluation of Flex-Offers from Flexible Electrical Devices , 2017, e-Energy.

[21]  Risto Lahdelma,et al.  Evaluation of a multiple linear regression model and SARIMA model in forecasting heat demand for district heating system , 2016 .

[22]  C. K. Simoglou,et al.  Comparison of SARIMAX, SARIMA, modified SARIMA and ANN-based models for short-term PV generation forecasting , 2016, 2016 IEEE International Energy Conference (ENERGYCON).

[23]  Birgitte Bak-Jensen,et al.  Estimation of Residential Heat Pump Consumption for Flexibility Market Applications , 2015, IEEE Transactions on Smart Grid.

[24]  Torben Bach Pedersen,et al.  Aggregating and Disaggregating Flexibility Objects , 2012, IEEE Transactions on Knowledge and Data Engineering.

[25]  Torben Bach Pedersen,et al.  An Energy Flexibility Framework on The Internet of Things , 2015 .

[26]  Torben Bach Pedersen,et al.  Measuring and Comparing Energy Flexibilities , 2015, EDBT/ICDT Workshops.

[27]  Yoshua Bengio,et al.  Empirical Evaluation of Gated Recurrent Neural Networks on Sequence Modeling , 2014, ArXiv.

[28]  Yoshua Bengio,et al.  On the Properties of Neural Machine Translation: Encoder–Decoder Approaches , 2014, SSST@EMNLP.

[29]  T. Chai,et al.  Root mean square error (RMSE) or mean absolute error (MAE)? – Arguments against avoiding RMSE in the literature , 2014 .

[30]  P. Mancarella,et al.  Decentralized Participation of Flexible Demand in Electricity Markets—Part II: Application With Electric Vehicles and Heat Pump Systems , 2013, IEEE Transactions on Power Systems.

[31]  Manuel Domínguez,et al.  Machine learning methods to forecast temperature in buildings , 2013, Expert Syst. Appl..

[32]  Torben Bach Pedersen,et al.  Data management in the MIRABEL smart grid system , 2012, EDBT-ICDT '12.

[33]  Rob J Hyndman,et al.  Automatic Time Series Forecasting: The forecast Package for R , 2008 .

[34]  Jürgen Schmidhuber,et al.  Long Short-Term Memory , 1997, Neural Computation.

[35]  Yoshua Bengio,et al.  Learning long-term dependencies with gradient descent is difficult , 1994, IEEE Trans. Neural Networks.

[36]  P. Young,et al.  Time series analysis, forecasting and control , 1972, IEEE Transactions on Automatic Control.

[37]  Michael D. Geurts,et al.  Time Series Analysis: Forecasting and Control , 1977 .