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Genetic algorithm-based non-linear auto-regressive with exogenous inputs neural network short-term and medium-term uncertainty modelling and prediction for electrical load and wind speed

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dc.contributor.author Jawad, Muhammad
dc.contributor.author Ali, Sahibzada M.
dc.contributor.author Khan, Bilal
dc.contributor.author Mehmood, Chaudry A.
dc.contributor.author Farid, Umar
dc.contributor.author Zahid Ullah
dc.contributor.author Usman, Saeeda
dc.contributor.author Fayyaz, Ahmad
dc.contributor.author Jadoon, Jabran
dc.contributor.author Tareen, Nauman
dc.contributor.author Basit, Abdul
dc.contributor.author Rustam, Muhammad A.
dc.contributor.author Sami, Irfan
dc.date.accessioned 2019-11-15T09:53:07Z
dc.date.available 2019-11-15T09:53:07Z
dc.date.issued 2018-08-23
dc.identifier.issn 2051-3305
dc.identifier.uri http://142.54.178.187:9060/xmlui/handle/123456789/1363
dc.description.abstract Electrical load and wind power forecasting are a demanding task for modern electrical power systems because both are closely linked with the weather parameters, such as temperature, humidity, and air pressure. The conventional methods of electrical load and wind power forecasting are useful to handle dynamic and uncertainties in un-regulated energy markets. However, there is still need of relative improvement by incorporating weather parameter dependencies. Considering above, a genetic algorithm-based non-linear auto-regressive neural network (GA-NARX-NN) model for short- and medium-term electrical load forecasting is presented with relative degree of accuracy. Causality, a new modelling technique, is employed for monthly and yearly wind speed patterns predictions and long-term wind speed forecasting. Real-time historical electrical load and weather parametric data are used to critically observe the performance of the proposed models compared to various state-of-the-art forecasting schemes. Numerical simulations are conducted that validates the proposed models based on various error calculation methods, such as mean absolute percentage error, root mean-square error, and variance ( $\sigma ^2$σ2 ). The quantitative comparison with five traditional techniques for electrical load and wind speed forecasting reveals that the GA-NARX-NN method is more accurate and reliable. en_US
dc.language.iso en_US en_US
dc.publisher IEEE The Journal of Engineering en_US
dc.subject Engineering and Technology en_US
dc.subject Autoregressive processes en_US
dc.subject Mean square error methods en_US
dc.subject Weather forecasting en_US
dc.subject Load forecasting en_US
dc.subject Neural nets en_US
dc.subject Regression analysis en_US
dc.subject Atmospheric techniques en_US
dc.subject Genetic algorithms en_US
dc.subject Power engineering computing en_US
dc.title Genetic algorithm-based non-linear auto-regressive with exogenous inputs neural network short-term and medium-term uncertainty modelling and prediction for electrical load and wind speed en_US
dc.type Proceedings en_US


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