Multi-region electricity demand prediction with ensemble deep neural networks

Irfan, Muhammad; Shaf, Ahmad; Ali, Tariq; Zafar, M.; Rahman, Saifur; Mursal, Salim Nasar Faraj; Althobiani, Faisal; Almas, Majid A.; Attar, Hamid Movahedian; Abdussamie, Nagi

doi:10.1371/journal.pone.0285456

Cited by 4 publications

(2 citation statements)

References 37 publications

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“…For example, since physical RC systems can naturally approximate complex dynamical systems, they may provide a unified analogue-computer-like modelling framework for the simulation, control and optimisation of time-critical operations in complex multi-component and multi-scaled electric networks [148][149][150][151]. RC systems in general and physical RC systems in particular have also been efficient in modelling highly nonlinear processes often encountered in energy research [62][63][64][65][66][67][68][69]152] and the predictive control of industrial processes [153]. However, as mentioned previously, RC systems can be readily hybridised with deep learning methods, resulting in a combined approach that benefits from the strengths of deep learning, of ESN and LSM and of the hardware implementation of these algorithms [30].…”

Section: Discussionmentioning

confidence: 99%

“…We also note the remarkable versatility of RC systems, independently of their implementation as a computer program or hardware physical system. In particular, the standard ESN algorithm and its modifications have been used to predict energy consumption and power generation [62][63][64][65][66][67][68][69], thereby extending more traditional modelling approaches such as vector regression models [70]. Thus, the discussion presented below will be of interest to readers with a background in power engineering and adjacent areas, also giving comprehensive information for those seeking to better understand the field of physical reservoir computing and the opportunities that it can bring.…”

Section: Introductionmentioning

confidence: 99%

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Analogue and Physical Reservoir Computing Using Water Waves: Applications in Power Engineering and Beyond

Maksymov

2023

Energies

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More than 3.5 billion people live in rural areas, where water and water energy resources play an important role in ensuring sustainable and productive rural economies. This article reviews and critically analyses the recent advances in the field of analogue and reservoir computing that have been driven by the unique physical properties and energy of water waves. It also demonstrates that analogue and physical reservoir computing, taken as an independent research field, holds the potential to bring artificial intelligence closer to people living outside large cities, thus enabling them to enjoy the benefits of novel technologies that are already in place in large cities but are not readily available or suitable for regional communities. In particular, although the physical reservoir computing systems discussed in the main text are universal in terms of processing input data and making forecasts, they can be used to design and optimise power grid networks and forecast energy consumption, both at local and global scales. Thus, this review article will be of interest to a broad readership interested in novel concepts of artificial intelligence and machine learning and their innovative practical applications in diverse areas of science and technology.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Analogue and Physical Reservoir Computing Using Water Waves: Applications in Power Engineering and Beyond

Maksymov

2023

Energies

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Outlier-Aware Demand Prediction Using Recurrent Neural Network-Based Models and Statistical Approach

Kim,

Park

2023

IEEE Access

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The paint industry comprises an elaborate supply chain involving various activities such as raw material procurement, manufacturing, and distribution. In addition, the accuracy of demand prediction significantly impacts supply chain management. A recurrent neural network (RNN) is a powerful method that learns intricate patterns through vast amounts of historical data and provides a prediction, demonstrating excellent performance in demand prediction. However, standard RNN-based demand predictions are limited by many outliers that occur due to the characteristics of the paint industry. Unexpected events such as a factory fire cause rapid fluctuations in paint demand and are difficult to pre-observe. To overcome these limitations, we propose a novel approach that employs clustering to identify demand time series data with similar characteristics and applies statistical outlier adjustment to allow the prediction model to learn the complex patterns of actual demand. The prediction target is the sum of sales for 15 days in the future, and sales data for four paint products are used to evaluate the proposed approach. Experimental results demonstrate a satisfactory prediction accuracy improvement ranging from 101% to 143%. In addition, unlike the RNNbased models used for comparison, the proposed method is more robust against actual demand fluctuations.INDEX TERMS Demand prediction, outlier, recurrent neural network, clustering, paint industry I. INTRODUCTION

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Predictive Maintenance of Power Grid Infrastructure using Long Short-Term Memory Networks

Mittal,

Alsalami,

Kumar

et al. 2024

2024 International Conference on Communication, Computer Sciences and Engineering (IC3SE)

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Multi-region electricity demand prediction with ensemble deep neural networks

Cited by 4 publications

References 37 publications

Analogue and Physical Reservoir Computing Using Water Waves: Applications in Power Engineering and Beyond

Analogue and Physical Reservoir Computing Using Water Waves: Applications in Power Engineering and Beyond

Outlier-Aware Demand Prediction Using Recurrent Neural Network-Based Models and Statistical Approach

Predictive Maintenance of Power Grid Infrastructure using Long Short-Term Memory Networks

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