A Hybrid Method for the Run-Of-The-River Hydroelectric Power Plant Energy Forecast: HYPE Hydrological Model and Neural Network

A Hybrid Method for the Run-Of-The-River Hydroelectric Power Plant Energy Forecast: HYPE Hydrological Model and Neural Network

The increasing penetration of non-programmable renewable energy sources (RES) is enforcing the need for accurate power production forecasts. In the category of hydroelectric plants, Run of the River (RoR) plants belong to the class of non-programmable RES. Data-driven models are nowadays the most wi...

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Main Authors: Emanuele Ogliari, Alfredo Nespoli, Marco Mussetta, Silvia Pretto, Andrea Zimbardo, Nicholas Bonfanti, Manuele Aufiero
Format: Article
Language:English
Published: MDPI AG 2020-10-01
Series:Forecasting
Subjects:
hydropower production forecast
Artificial Neural Networks
run of the river hydroelectric plants
seasonal decomposition
HYPE model
RES generation
Online Access:https://www.mdpi.com/2571-9394/2/4/22
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spelling doaj-eec7e303be094ea7ad04d5757f450ec62020-11-25T02:26:25ZengMDPI AGForecasting2571-93942020-10-0122241042810.3390/forecast2040022A Hybrid Method for the Run-Of-The-River Hydroelectric Power Plant Energy Forecast: HYPE Hydrological Model and Neural NetworkEmanuele Ogliari0Alfredo Nespoli1Marco Mussetta2Silvia Pretto3Andrea Zimbardo4Nicholas Bonfanti5Manuele Aufiero6Dipartimento di Energia, Politecnico di Milano, via La Masa 34, 20156 Milano, ItalyDipartimento di Energia, Politecnico di Milano, via La Masa 34, 20156 Milano, ItalyDipartimento di Energia, Politecnico di Milano, via La Masa 34, 20156 Milano, ItalyDipartimento di Energia, Politecnico di Milano, via La Masa 34, 20156 Milano, ItalyDipartimento di Energia, Politecnico di Milano, via La Masa 34, 20156 Milano, ItalyMilano Multiphysics S.r.l.s, Polihub, via Durando 39, 20158 Milano, ItalyMilano Multiphysics S.r.l.s, Polihub, via Durando 39, 20158 Milano, ItalyThe increasing penetration of non-programmable renewable energy sources (RES) is enforcing the need for accurate power production forecasts. In the category of hydroelectric plants, Run of the River (RoR) plants belong to the class of non-programmable RES. Data-driven models are nowadays the most widely adopted methodologies in hydropower forecast. Among all, the Artificial Neural Network (ANN) proved to be highly successful in production forecast. Widely adopted and equally important for hydropower generation forecast is the HYdrological Predictions for the Environment (HYPE), a semi-distributed hydrological Rainfall–Runoff model. A novel hybrid method, providing HYPE sub-basins flow computation as input to an ANN, is here introduced and tested both with and without the adoption of a decomposition approach. In the former case, two ANNs are trained to forecast the trend and the residual of the production, respectively, to be then summed up to the previously extracted seasonality component and get the power forecast. These results have been compared to those obtained from the adoption of a ANN with rainfalls in input, again with and without decomposition approach. The methods have been assessed by forecasting the Run-of-the-River hydroelectric power plant energy for the year 2017. Besides, the forecasts of 15 power plants output have been fairly compared in order to identify the most accurate forecasting technique. The here proposed hybrid method (HYPE and ANN) has shown to be the most accurate in all the considered study cases.https://www.mdpi.com/2571-9394/2/4/22hydropower production forecastArtificial Neural Networksrun of the river hydroelectric plantsseasonal decompositionHYPE modelRES generation
collection DOAJ
language English
format Article
sources DOAJ
author Emanuele Ogliari
Alfredo Nespoli
Marco Mussetta
Silvia Pretto
Andrea Zimbardo
Nicholas Bonfanti
Manuele Aufiero
spellingShingle Emanuele Ogliari
Alfredo Nespoli
Marco Mussetta
Silvia Pretto
Andrea Zimbardo
Nicholas Bonfanti
Manuele Aufiero
A Hybrid Method for the Run-Of-The-River Hydroelectric Power Plant Energy Forecast: HYPE Hydrological Model and Neural Network
Forecasting
hydropower production forecast
Artificial Neural Networks
run of the river hydroelectric plants
seasonal decomposition
HYPE model
RES generation
author_facet Emanuele Ogliari
Alfredo Nespoli
Marco Mussetta
Silvia Pretto
Andrea Zimbardo
Nicholas Bonfanti
Manuele Aufiero
author_sort Emanuele Ogliari
title A Hybrid Method for the Run-Of-The-River Hydroelectric Power Plant Energy Forecast: HYPE Hydrological Model and Neural Network
title_short A Hybrid Method for the Run-Of-The-River Hydroelectric Power Plant Energy Forecast: HYPE Hydrological Model and Neural Network
title_full A Hybrid Method for the Run-Of-The-River Hydroelectric Power Plant Energy Forecast: HYPE Hydrological Model and Neural Network
title_fullStr A Hybrid Method for the Run-Of-The-River Hydroelectric Power Plant Energy Forecast: HYPE Hydrological Model and Neural Network
title_full_unstemmed A Hybrid Method for the Run-Of-The-River Hydroelectric Power Plant Energy Forecast: HYPE Hydrological Model and Neural Network
title_sort hybrid method for the run-of-the-river hydroelectric power plant energy forecast: hype hydrological model and neural network
publisher MDPI AG
series Forecasting
issn 2571-9394
publishDate 2020-10-01
description The increasing penetration of non-programmable renewable energy sources (RES) is enforcing the need for accurate power production forecasts. In the category of hydroelectric plants, Run of the River (RoR) plants belong to the class of non-programmable RES. Data-driven models are nowadays the most widely adopted methodologies in hydropower forecast. Among all, the Artificial Neural Network (ANN) proved to be highly successful in production forecast. Widely adopted and equally important for hydropower generation forecast is the HYdrological Predictions for the Environment (HYPE), a semi-distributed hydrological Rainfall–Runoff model. A novel hybrid method, providing HYPE sub-basins flow computation as input to an ANN, is here introduced and tested both with and without the adoption of a decomposition approach. In the former case, two ANNs are trained to forecast the trend and the residual of the production, respectively, to be then summed up to the previously extracted seasonality component and get the power forecast. These results have been compared to those obtained from the adoption of a ANN with rainfalls in input, again with and without decomposition approach. The methods have been assessed by forecasting the Run-of-the-River hydroelectric power plant energy for the year 2017. Besides, the forecasts of 15 power plants output have been fairly compared in order to identify the most accurate forecasting technique. The here proposed hybrid method (HYPE and ANN) has shown to be the most accurate in all the considered study cases.
topic hydropower production forecast
Artificial Neural Networks
run of the river hydroelectric plants
seasonal decomposition
HYPE model
RES generation
url https://www.mdpi.com/2571-9394/2/4/22
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