Virtual Battery Parameter Identification Using Transfer Learning Based Stacked Autoencoder

Recent studies have shown that the aggregated dynamic flexibility of an ensemble of thermostatic loads can be modeled in the form of a virtual battery. The existing methods for computing the virtual battery parameters require the knowledge of the first-principle models and parameter values of the loads in the ensemble. In real-world applications, however, it is likely that the only available information are end-use measurements such as power consumption, room temperature, device on/off status, etc., while very little about the individual load models and parameters are known. We propose a transfer learning based deep network framework for calculating virtual battery state of a given ensemble of flexible thermostatic loads, from the available end-use measurements. This proposed framework extracts first order virtual battery model parameters for the given ensemble. We illustrate the effectiveness of this novel framework on different ensembles of ACs and WHs.

[1]  Duncan S. Callaway,et al.  Arbitraging Intraday Wholesale Energy Market Prices With Aggregations of Thermostatic Loads , 2015, IEEE Transactions on Power Systems.

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

[3]  Pierre Baldi,et al.  Autoencoders, Unsupervised Learning, and Deep Architectures , 2011, ICML Unsupervised and Transfer Learning.

[4]  Thomas Hofmann,et al.  Greedy Layer-Wise Training of Deep Networks , 2007 .

[5]  Tyrone L. Vincent,et al.  Aggregate Flexibility of Thermostatically Controlled Loads , 2015, IEEE Transactions on Power Systems.

[6]  Hosam K. Fathy,et al.  Modeling and control insights into demand-side energy management through setpoint control of thermostatic loads , 2011, Proceedings of the 2011 American Control Conference.

[7]  Wei Zhang,et al.  Aggregated Modeling and Control of Air Conditioning Loads for Demand Response , 2013, IEEE Transactions on Power Systems.

[8]  Ernesto Kofman,et al.  Load management: Model-based control of aggregate power for populations of thermostatically controlled loads , 2012 .

[9]  Yoshua Bengio,et al.  Editorial introduction to the Neural Networks special issue on Deep Learning of Representations , 2015, Neural Networks.

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

[11]  Hyun Ah Song,et al.  Hierarchical Representation Using NMF , 2013, ICONIP.

[12]  Ian A. Hiskens,et al.  Achieving Controllability of Electric Loads , 2011, Proceedings of the IEEE.

[13]  Pietro Perona,et al.  Automatic recognition of biological particles in microscopic images , 2007, Pattern Recognit. Lett..

[14]  Scott Backhaus,et al.  Modeling and control of thermostatically controlled loads , 2011 .

[15]  Yoshua Bengio,et al.  Exploring Strategies for Training Deep Neural Networks , 2009, J. Mach. Learn. Res..

[16]  Léon Bottou,et al.  Large-Scale Machine Learning with Stochastic Gradient Descent , 2010, COMPSTAT.

[17]  Kameshwar Poolla,et al.  Identification of Virtual Battery Models for Flexible Loads , 2016, IEEE Transactions on Power Systems.

[18]  Tianqi Chen,et al.  Net2Net: Accelerating Learning via Knowledge Transfer , 2015, ICLR.

[19]  François Bouffard,et al.  Decentralized Demand-Side Contribution to Primary Frequency Control , 2011, IEEE Transactions on Power Systems.

[20]  Geoffrey E. Hinton,et al.  Reducing the Dimensionality of Data with Neural Networks , 2006, Science.

[21]  Kameshwar Poolla,et al.  Virtual Battery Models for Load Flexibility from Commercial Buildings , 2015, 2015 48th Hawaii International Conference on System Sciences.

[22]  Ji Wu,et al.  Denoising deep neural networks based voice activity detection , 2013, 2013 IEEE International Conference on Acoustics, Speech and Signal Processing.

[23]  Johanna L. Mathieu,et al.  Modeling and Control of Aggregated Heterogeneous Thermostatically Controlled Loads for Ancillary Services , 2011 .

[24]  Albert Ali Salah,et al.  Efficient large-scale action recognition in videos using extreme learning machines , 2015, Expert Syst. Appl..

[25]  Tao Yang,et al.  Optimal Coordination of Building Loads and Energy Storage for Power Grid and End User Services , 2018, IEEE Transactions on Smart Grid.

[26]  Yoshua Bengio,et al.  FitNets: Hints for Thin Deep Nets , 2014, ICLR.

[27]  Ruisheng Diao,et al.  Electric water heater modeling and control strategies for demand response , 2012, 2012 IEEE Power and Energy Society General Meeting.

[28]  Draguna Vrabie,et al.  Prioritized Threshold Allocation for Distributed Frequency Response , 2018, 2018 IEEE Conference on Control Technology and Applications (CCTA).

[29]  Guigang Zhang,et al.  Deep Learning , 2016, Int. J. Semantic Comput..