Short Term Residential Load Forecasting: An Improved Optimal Nonlinear Auto Regressive (NARX) Method with Exponential Weight Decay Function

Short Term Residential Load Forecasting: An Improved Optimal Nonlinear Auto Regressive (NARX) Method with Exponential Weight Decay Function

The advancement in electrical load forecasting techniques with new algorithms offers reliable solutions to operators for operational cost reduction, optimum use of available resources, effective power management, and a reliable planning process. The focus is to develop a comprehensive understanding...

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Main Authors: Farukh Abbas, Donghan Feng, Salman Habib, Usama Rahman, Aazim Rasool, Zheng Yan
Format: Article
Language:English
Published: MDPI AG 2018-12-01
Series:Electronics
Subjects:
short-term load forecasting (SLTF)
non-linear auto-regressive neural network with external input (NARX)
mean absolute percentage error (MAPE)
lightning search algorithm (LSA)
exponential weight decay (EWD)
Online Access:https://www.mdpi.com/2079-9292/7/12/432
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spelling doaj-82208ac88170432d809458f36ed68fd42020-11-25T00:22:26ZengMDPI AGElectronics2079-92922018-12-0171243210.3390/electronics7120432electronics7120432Short Term Residential Load Forecasting: An Improved Optimal Nonlinear Auto Regressive (NARX) Method with Exponential Weight Decay FunctionFarukh Abbas0Donghan Feng1Salman Habib2Usama Rahman3Aazim Rasool4Zheng Yan5School of Electronic, Information and Electrical Engineering, Shanghai Jiao Tong University, 800 dongchuan road, Shanghai 200240, ChinaSchool of Electronic, Information and Electrical Engineering, Shanghai Jiao Tong University, 800 dongchuan road, Shanghai 200240, ChinaSchool of Electronic, Information and Electrical Engineering, Shanghai Jiao Tong University, 800 dongchuan road, Shanghai 200240, ChinaSchool of Electronic, Information and Electrical Engineering, Shanghai Jiao Tong University, 800 dongchuan road, Shanghai 200240, ChinaDepartment of Electrical Engineering, North China Electric Power University, Beijing 102206, ChinaSchool of Electronic, Information and Electrical Engineering, Shanghai Jiao Tong University, 800 dongchuan road, Shanghai 200240, ChinaThe advancement in electrical load forecasting techniques with new algorithms offers reliable solutions to operators for operational cost reduction, optimum use of available resources, effective power management, and a reliable planning process. The focus is to develop a comprehensive understanding regarding the forecast accuracy generated by employing a state of the art optimal autoregressive neural network (NARX) for multiple, nonlinear, dynamic, and exogenous time varying input vectors. Other classical computational methods such as a bagged regression tree (BRT), an autoregressive and moving average with external inputs (ARMAX), and a conventional feedforward artificial neural network are implemented for comparative error assessment. The training of the applied method is realized in a closed loop by feeding back the predicted results obtained from the open loop model, which made the implemented model more robust when compared with conventional forecasting approaches. The recurrent nature of the applied model reduces its dependency on the external data and a produced mean absolute percentage error (MAPE) below 1%. Subsequently, more precision in handling daily grid operations with an average improvement of 16%⁻20% in comparison with existing computational techniques is achieved. The network is further improved by proposing a lightning search algorithm (LSA) for optimized NARX network parameters and an exponential weight decay (EWD) technique to control the input error weights.https://www.mdpi.com/2079-9292/7/12/432short-term load forecasting (SLTF)non-linear auto-regressive neural network with external input (NARX)mean absolute percentage error (MAPE)lightning search algorithm (LSA)exponential weight decay (EWD)
collection DOAJ
language English
format Article
sources DOAJ
author Farukh Abbas
Donghan Feng
Salman Habib
Usama Rahman
Aazim Rasool
Zheng Yan
spellingShingle Farukh Abbas
Donghan Feng
Salman Habib
Usama Rahman
Aazim Rasool
Zheng Yan
Short Term Residential Load Forecasting: An Improved Optimal Nonlinear Auto Regressive (NARX) Method with Exponential Weight Decay Function
Electronics
short-term load forecasting (SLTF)
non-linear auto-regressive neural network with external input (NARX)
mean absolute percentage error (MAPE)
lightning search algorithm (LSA)
exponential weight decay (EWD)
author_facet Farukh Abbas
Donghan Feng
Salman Habib
Usama Rahman
Aazim Rasool
Zheng Yan
author_sort Farukh Abbas
title Short Term Residential Load Forecasting: An Improved Optimal Nonlinear Auto Regressive (NARX) Method with Exponential Weight Decay Function
title_short Short Term Residential Load Forecasting: An Improved Optimal Nonlinear Auto Regressive (NARX) Method with Exponential Weight Decay Function
title_full Short Term Residential Load Forecasting: An Improved Optimal Nonlinear Auto Regressive (NARX) Method with Exponential Weight Decay Function
title_fullStr Short Term Residential Load Forecasting: An Improved Optimal Nonlinear Auto Regressive (NARX) Method with Exponential Weight Decay Function
title_full_unstemmed Short Term Residential Load Forecasting: An Improved Optimal Nonlinear Auto Regressive (NARX) Method with Exponential Weight Decay Function
title_sort short term residential load forecasting: an improved optimal nonlinear auto regressive (narx) method with exponential weight decay function
publisher MDPI AG
series Electronics
issn 2079-9292
publishDate 2018-12-01
description The advancement in electrical load forecasting techniques with new algorithms offers reliable solutions to operators for operational cost reduction, optimum use of available resources, effective power management, and a reliable planning process. The focus is to develop a comprehensive understanding regarding the forecast accuracy generated by employing a state of the art optimal autoregressive neural network (NARX) for multiple, nonlinear, dynamic, and exogenous time varying input vectors. Other classical computational methods such as a bagged regression tree (BRT), an autoregressive and moving average with external inputs (ARMAX), and a conventional feedforward artificial neural network are implemented for comparative error assessment. The training of the applied method is realized in a closed loop by feeding back the predicted results obtained from the open loop model, which made the implemented model more robust when compared with conventional forecasting approaches. The recurrent nature of the applied model reduces its dependency on the external data and a produced mean absolute percentage error (MAPE) below 1%. Subsequently, more precision in handling daily grid operations with an average improvement of 16%⁻20% in comparison with existing computational techniques is achieved. The network is further improved by proposing a lightning search algorithm (LSA) for optimized NARX network parameters and an exponential weight decay (EWD) technique to control the input error weights.
topic short-term load forecasting (SLTF)
non-linear auto-regressive neural network with external input (NARX)
mean absolute percentage error (MAPE)
lightning search algorithm (LSA)
exponential weight decay (EWD)
url https://www.mdpi.com/2079-9292/7/12/432
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