Abstract
In the smart grid, one of the most important research areas is load forecasting; it spans from traditional time series analyses to recent machine learning approaches and mostly focuses on forecasting aggregated electricity consumption. However, the importance of demand side energy management, including individual load forecasting, is becoming critical. In this paper, we propose deep neural network (DNN)-based load forecasting models and apply them to a demand side empirical load database. DNNs are trained in two different ways: a pre-training restricted Boltzmann machine and using the rectified linear unit without pre-training. DNN forecasting models are trained by individual customer’s electricity consumption data and regional meteorological elements. To verify the performance of DNNs, forecasting results are compared with a shallow neural network (SNN), a double seasonal Holt–Winters (DSHW) model and the autoregressive integrated moving average (ARIMA). The mean absolute percentage error (MAPE) and relative root mean square error (RRMSE) are used for verification. Our results show that DNNs exhibit accurate and robust predictions compared to other forecasting models, e.g., MAPE and RRMSE are reduced by up to 17% and 22% compared to SNN and 9% and 29% compared to DSHW.
Highlights
Load forecasting is one of the main research areas in the smart grid and can be classified depending on its target forecasting ranges from minutes to years
Bidirectional communications can be realized with the deployment of advanced metering infrastructure (AMI), which is a prerequisite of many smart grid services, such as demand response (DR), targeted dynamic tariffs, load monitoring, outage detection and restoration, the customer information system, etc. [1,2]
Forecasting results of deep neural network (DNN) are compared with shallow neural network (SNN), seasonal autoregressive integrated moving average (ARIMA)
Summary
Load forecasting is one of the main research areas in the smart grid and can be classified depending on its target forecasting ranges from minutes to years. One of the main characteristics of the smart grid is bidirectional communications, which breaks down the border between electricity generation and consumption. Bidirectional communications can be realized with the deployment of advanced metering infrastructure (AMI), which is a prerequisite of many smart grid services, such as demand response (DR), targeted dynamic tariffs, load monitoring, outage detection and restoration, the customer information system, etc. By using an energy storage system (ESS), consumers can actively shape their power demand. In addition to these changes, deregulation and privatization
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