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.
Revised: April 24, 2019 |
Published: December 17, 2018
Citation
Chakraborty I., S. Nandanoori, and S. Kundu. 2018.Virtual Battery Parameter Identification using Transfer Learning based Stacked Autoencoder. In 17th IEEE International Conference on Machine Learning and Applications (ICMLA 2018), December 17-20, 2018, Orlando, Florida. Piscataway, New Jersey:IEEE.PNNL-SA-137721.doi:10.1109/ICMLA.2018.00206