Demand response management through appliance scheduling can effectively decrease electricity bills. Similarly, it can decrease the peak demand of both consumers and the utility grid. However, prior knowledge of the load profile of the consumer is required for effective appliance scheduling. This work developed a novel time-series forecasting model within the shallow neural network framework to predict the load curve for optimal planning of demand response by a nonlinear autoregressive network with exogenous input network. The algorithms such as Levenberg-Marquard, scaled conjugate gradient, and Bayesian regularization was applied to train the model. The results were compared with conventional seasonal autoregressive integrated moving average statistical model and long short-term memory network. The results indicated that the optimum methodology is a nonlinear autoregressive network with exogenous inputs using the Bayesian regularisation algorithm, which has the lowest MSE value in the training and testing phases of 0.0031 and 0.0029, respectively. It is practical to continue designing artificial neural networks to analyze hourly load consumption in the context of the positive outcomes acquired.

Demand forecasting; Artificial neural networks; Predictive models; Power demand; Recurrent neural networks

L. Peng, S.X. Lv, L. Wang, and Z. Y. Wang, “Effective electricity load forecasting using enhanced double-reservoir echo state network,” Engineering Applications of Artificial Intelligence, vol. 99, p.104132, 2021.

N. Son, S.Yang, and J. Na, “Deep neural network and long short-term memory for electric power load forecasting, ” Applied Sciences, vol. 10, no. 18, p. 6489, 2020.

G. Zhang and J. Guo, “A novel ensemble method for hourly residential electricity consumption forecasting by imaging time series, ” Energy, vol. 203, p.117858, 2020.

R. Lu, S. H. Hong, and M. Yu, 2019, “Demand response for home energy management using reinforcement learning and artificial neural network, ” IEEE Transactions on Smart Grid, vol. 10, no. 6, pp. 6629–6639, 2019.

S. Ungureanu, V. Topa, and A. C. Cziker, “Deep Learning for Short-Term Load Forecasting—Industrial Consumer Case Study,” Applied Sciences, vol. 11, no. 21, pp. 10126, 2021.

M. Alhussein , K. Aurangzeb, and S. I. Haider, “Hybrid CNN-LSTM model for short-term individual household load forecasting, ,” IEEE Access, vol. 8, pp. 180544–57, 2020.

T. Bashir, C. Haoyong, MF. Tahir, and Z. Liqiang, “Short term electricity load forecasting using hybrid prophet-LSTM model optimized by BPNN, ” Energy Reports, vol. 8, pp. 1678–86, 2022.

F. Saeed, A. Paul, and H. Seo, H., 2022, “A Hybrid Channel-Communication-Enabled CNN-LSTM Model for Electricity Load Forecasting, ” Energies, vol. 15, no.6, p.2263,2022.

N. Mughees, S. A. Mohsin, A. Mughees, and A. Mughees, “ Deep sequence to sequence Bi-LSTM neural networks for day-ahead peak load forecasting,” Expert Systems with Applications, vol. 175, p.114844, 2021.

W. He, “ Load forecasting via deep neural networks,” Procedia Computer Science, vol. 122, pp. 308–314,2017.

R. Mubashar, M. J. Awan, M. Ahsan, A. Yasin, and V. P. Singh, “Efficient residential load forecasting using deep learning approach, ” International Journal of Computer Applications in Technology, vol. 68, no. 3, pp.205-214, 2022.

I. Ozer, S. B. Efe, and H. Ozbay, “A combined deep learning application for short term load forecasting;” Alexandria Engineering Journal, vol. 60, no. 4, pp.3807-3818, 2021.

W. S. McCulloch, and W. Pitts, “A logical calculus of the ideas immanent in nervous activity.” The bulletin of mathematical biophysics, vol.5, no. 4, pp.115-133, 1943.

C. Martinez-Castillo, G. Astray, and J.C. Mejuto, “Modelling and prediction of monthly global irradiation using different prediction models,” Energies, vol. 14, no.8, p.2332, 2022.

S. B. Priyatno, T. Prakoso, and M. A. Riyadi,“ Classification of motor imagery brain wave for bionic hand movement using multilayer perceptron,” Sinergi, vol. 26, no.1, pp.57–64, 2022.

S. H. Rafi, S. R. Deeba, and E. Hossain, “A short-term load forecasting method using integrated CNN and LSTM network,” IEEE Access, vol. 9, 32436–32448, 2021.

O. A. Karabiber, and G. Xydis, “Electricity price forecasting in the Danish day-ahead market using the TBATS, ANN and ARIMA methods,” Energies, vol. 12, no. 5, p.928, 2019.

G. E. Box, Time series analysis: forecasting and control, John Wiley & Sons, 2015.

S. Chaturvedi, E. Rajasekar, S. Natarajan, and N. McCullen, “A comparative assessment of SARIMA, LSTM RNN and Fb Prophet models to forecast total and peak monthly energy demand for India,” Energy Policy, vol. 168, p.113097,2022.

T. A. Nakabi, and P. Toivanen, “An ANN-based model for learning individual customer behavior in response to electricity prices,” Sustainable Energy, Grids and Networks, vol. 18, p.100212, 2019.

U. Ugurlu, I. Oksuz and O. Tas, “ . Electricity price forecasting using recurrent neural networks,” Energies, vol. 11, no. 5, p.1255, 2018.

Y. Raptodimos, and I. Lazakis, “Application of NARX neural network for predicting marine engine performance parameters,” Ships and Offshore Structures, vol. 15, no. 4, pp.443-452, 2020.

D. Selvamuthu, V. Kumar, and A. Mishra, “Indian stock market prediction using artificial neural networks on tick data,” Financial Innovation, vol. 5, no. 1, pp.1-12, 2019.

S. Namasudra, S. Dhamodharavadhani, and R. Rathipriya, “Nonlinear neural network based forecasting model for predicting COVID-19 cases,” Neural processing letters, pp.1-21, 2021.

S. Atef, K. Nakata, K. and A. B. Eltawil, “A deep bi-directional long-short term memory neural network-based methodology to enhance short-term electricity load forecasting for residential applications,” Computers & Industrial Engineering, vol. 170, p.108364, 2022.

A.Chinnathambi, Radhakrishnan, A. Mukherjee, M. Campion, H. Salehfar, T.M. Hansen, J. Lin, and P. Ranganathan, “A Multi-Stage Price Forecasting Model for Day-Ahead Electricity Markets,” Forecasting, vol. 1, pp.26-46, 2018.

S. M. Jung, S. Park, S.W. Jung, and E. Hwang, “Monthly Electric Load Forecasting Using Transfer Learning for Smart Cities,” Sustainability, vol. 12, p.6364, 2020.

N. Sultana, S.Z. Hossain, S.H. Almuhaini, and D. Düştegör, “A Multi-Stage Price Forecasting Model for Day-Ahead Electricity Markets,” Energies, vol. 15, p.3425, 2022.

E.C. Ashigwuike, A. R.A. Aluya, J.E.C. Emechebe, and S. A. Benson, “Medium term electrical load forecast of Abuja Municipal Area council using artificial neural network method,” Nigerian Journal of Technology, vol. 39, pp.860-870, 2020.

I. Zapirain, G. Etxegarai, J. Hernández, Z. Boussaada, N. Aginako, and H. Camblong, “Short-term electricity consumption forecasting with NARX, LSTM, and SVR for a single building: small data set approach,” Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, vol. 44, pp.6898-6908, 2022.