Submitted:
15 August 2025
Posted:
18 August 2025
You are already at the latest version
Abstract
Keywords:
1. Introduction
1. Creating the Data Set

2. Creating and Implementing Forecast Models
3. Pearson Correlation Method
- Creating the data set
- Creating the correlation mathematical model
- Calculating the correlation coefficient
- Determining the correlation coefficient and determining the effectiveness levels of their effects on the results
- The Pearson Correlation Mathematical Model is given in Equation x.
| Correlation Coefficient (r) | Relationship Type |
| +0.90 ~ +1.00 | Very strong positive relationship |
| +0.70 ~ +0.89 | Strong positive relationship |
| +0.50 ~ +0.69 | Moderate positive correlation |
| +0.30 ~ +0.49 | Weak positive correlation |
| 0 | No relationship |
| -0.30 ~ -1.00 | Negative (inverse) relationship |
Findings and Discussion
- The highest forecast value in all years was achieved by the Polynomial forecasting method.
- The forecasting methods that showed the lowest consumption in 2030 were SVR and Random Forest.
- When the results were evaluated, an increase was observed across years in all models. However, these increases occurred at different rates.
- The Random Forest model stands out as a more stable and lower-error method in both years. While the Lasso model improved in 2024, it still lags behind Random Forest. The equal MAE and RMSE values indicate that the errors are absolute and unidirectional, not directional. This demonstrates that the forecast model operates free of systematic bias.
- When the forecast method was rerun by combining the Lasso and Random Forest models in the hybrid model to achieve optimal results, the following energy consumption estimates were generated: 77028.59 GWH for 2025, 80672.22 GWH for 2026, 83315.51 GWH for 2027, 85598 GWH for 2028, 85958 GWH for 2029, and 93246.07 GWH for 2030. These values are demonstrated in Figure 3.

- When all results were compared with the hybrid model, Arima, Lasso, and Linear Regression models produced the closest results to the hybrid model. Polynomial and Exponential estimation methods produced the farthest estimates from the hybrid model. This situation is demonstrated in Table 4.



- The correlation between electricity consumption and gross domestic product was 0.995.
- The correlation between electricity consumption and the number of university graduates was 0.9971.
- The correlation between electricity consumption and population was 0.9827.
Conclusion
References
- Dudek, G. Hybrid Residual Dilated LSTM and Exponential Smoothing Method for Medium-Term Electricity Load Forecasting. 2020. [Google Scholar]
- Lee, J.; Cho, Y. National-Scale Electricity Peak Load Forecasting: Traditional, ML, or Hybrid Model? Energy 2022, 239. [Google Scholar] [CrossRef]
- Roy, K.; Maity, S.; Ghosh, P. 2021. Electricity Demand Forecasting in Smart Grid Using Long Short-Term Memory (LSTM).
- Jun, A. 2022. A Hybrid Forecasting Model Using LSTM and Prophet for Energy Consumption with Decomposition of Time Series Data. ResearchGate.
- Doğan, G.Y.; Kaya, F.; Öztürk, A. A Hybrid Deep Learning Model to Estimate the Future Electricity Demand of Sustainable Cities. Sustainability 2024, 16, 6503. [Google Scholar] [CrossRef]
- Li, X.; Zhang, Q.; Chen, M. A Hybrid Forecasting Model for Electricity Demand in Sustainable Power Systems Based on Support Vector Machines. Energies 2024, 17, 4377. [Google Scholar] [CrossRef]
- Ugbehe, P.O.; Dike, T.; Okoro, C.M. Electricity Demand Forecasting Methodologies and Applications: A Review. Sustain. Energy Res. 2025, 14, 1–23. [Google Scholar] [CrossRef]
- Javanmard, M.; Ghaderi, S.F. Energy Demand Forecasting in Seven Sectors in Iran Using ANN, ARIMA, SARIMA and LSTM Models. Energy Strategy Rev. 2023, 42, 101037. [Google Scholar]
- Ashtar, D.; van den Berg, N.; van Aken, M. May Hybrid Multi-Stage Forecasting for Sustainable Electricity Demand Planning in the Netherlands. Preprints.org. 2025.
- Khan, M.A.; Taj, N.R.; Smith, L.E. Short-Term Electricity Demand Forecasting in Smart Homes Using Hybrid CNN-LSTM and CNN-GRU Models. Front. Energy Res. 2024, 12, 1323357. [Google Scholar]
- Wang, T.; Yu, Z.; Zhang, H. Multi-Input LSTM-Based Model for Short-Term Electricity Demand Forecasting Using Weather and Mobility Data. Appl. Energy 2023, 347, 121408. [Google Scholar]
- Nguyen, H.T.; Mohanty, S.P.; Kougianos, E. Electricity Demand Forecasting Using GRU-SVR Hybrid Models. IEEE Internet Things J. 2022, 9, 17588–17597. [Google Scholar]
- Al-Qahtani; Elleithy, K. M.; Alotaibi, F. Optimized Support Vector Regression Using Genetic Algorithms for Power Load Forecasting. IEEE Access 2021, 9, 43322–43331. [Google Scholar]
- Kumar, S.; Ranjan, R.; Tiwari, A. Multi-Stage Demand Forecasting Using Prophet, LSTM, XGBoost. Energies 2023, 16, 1852. [Google Scholar]
- Kim, H.; Jang, S.; Lee, D. Application of Transformer Neural Network in Electricity Load Forecasting. IEEE Trans. Smart Grid 2024, 15, 990–1001. [Google Scholar]
- Arafat, *!!! REPLACE !!!*; Haque, M.I.; Rahman, N. Arafat; Haque, M.I.; Rahman, N. Short-Term Load Forecasting in Industrial Zones Using LSTM. IEEE PES ISGT Conference.
- Sarkar; Roy, R. ; Das, P. Comparative Study of Random Forest and LSTM for Energy Demand Prediction in Smart Cities. J. Clean. Prod. 2022, 356, 131915. [Google Scholar]
- Ahmed, F.S.; Ali, M.M. 2024. Electrical Energy Demand Forecasting Using Time Series in LSTM and CNN-LSTM Models in Deep Learning Applications. ResearchGate.
- Arif, M.; Hussain, M. Energy Demand Forecasting and Optimizing Electric Systems for Developing Countries. Int. J. Energy Econ. Policy 2023, 13, 28–35. [Google Scholar]
- Sharma, F.; Verma, A. Performance Comparison of ARIMA, LSTM, SVM in Electricity Demand Forecasting. PreDatecs J. 2023, 7, 42–49. [Google Scholar]
- Zhang, L.; Zhou, Q. Forecasting Peak Energy Demand in Smart Buildings Using ANN and ARIMA Models. J. Supercomput. 2020, 76, 5894–5912. [Google Scholar]
- Park, S.H.; Kim, J. Energy Forecasting in Smart Grid Systems: A Review. arXiv arXiv:2011.12598, 2020. [CrossRef]
- Doğan, G.Y. Electricity Demand Forecasting Using Hybrid CNN-LSTM for City-Level Smart Grid Applications. Energies 2024, 16, 6503. [Google Scholar]
- Bashir, S.; Hussain, A. 2024. Energy Demand Forecasting Using Time Series in LSTM and CNN-LSTM Models. ResearchGate.
- Chen, L.; Han, M.; Xu, Y. Electricity Demand Forecasting in Smart Grid Using SVM and LSTM Models. IEEE Trans. Ind. Inform. 2022, 18, 6934–6942. [Google Scholar]
- Mehmood, R.; Iqbal, U. Deep Learning Based Short-Term Load Forecasting: A Hybrid LSTM-CNN Model. J. Electr. Syst. Inf. Technol. 2022, 9, 10. [Google Scholar]
- Yılmaz, H. Comparison of Artificial Neural Networks and ARIMA Methods in Electricity Demand Forecasting in Turkey. Gazi Univ. J. Sci. 2023, 37, 101–112. [Google Scholar]
- Akçay, N.; Altuğ, F. Performance Comparison of LSTM and Prophet Models in Electricity Demand Forecasting. J. Eng. Sci. 2024, 31, 65–73. [Google Scholar]
- Kaya, T.; Kocak, M. A Hybrid Method Application for Energy Demand Forecasting: The Case of Turkey. Journal of Electrical, Electronics and Computer Sciences 2023, 11, 101–109. [Google Scholar]
- Demirtaş, E.; Şahin, R. Comparative Electricity Demand Forecasting Performance of LSTM and RF Methods. Yıldız Tech. Univ. J. Energy Syst. 2024, 5, 45–54. [Google Scholar]
- Wang, Z.; Li, D. Short-term load forecasting based on ARIMA model. Energy Rep. 2020, 6, 101–106. [Google Scholar]
- Alwee, R.; Yusof, S.; Ismail, N. Electricity consumption forecasting using exponential smoothing methods. Energy Procedia 2014, 62, 512–521. [Google Scholar]
- Mohamed, S.; Kamel, S. Comparison of artificial neural network and linear regression model in electricity demand forecasting. Int. J. Electr. Power Energy Syst. 2015, 67, 562–568. [Google Scholar]
- Şahin, M.; Karabacak, B. Forecasting energy consumption using polynomial regression: A case study for Turkey. Renew. Sustain. Energy Rev. 2018, 82, 2587–2599. [Google Scholar]
- Zhang, X.; Zhou, Y.; Chen, S. Comparative study of Lasso and Ridge Regression in energy consumption modeling. Appl. Energy 2020, 259, 114–122. [Google Scholar]
- Khosravi, H.; Ghadimi, M.; Dehghanian, M.Z. Short-term electricity demand forecasting using random forest. Energy 2019, 182, 543–552. [Google Scholar]
- Ahmad, T.; Chen, H. Short and medium-term forecasting using SVR model for power system load. Appl. Energy 2017, 195, 693–704. [Google Scholar]
- Liu, L.; Wang, K.; Zhang, Y. A novel XGBoost-based model for electricity consumption prediction. Energy 2019, 189, Art. [Google Scholar]
- Deb; Zhang, F. ; Lee, S.E. A review on time series forecasting techniques for building energy consumption. Renew. Sustain. Energy Rev. 2017, 74, 902–924. [Google Scholar] [CrossRef]
- Zarandi, M.H.F.; Hosseini, S.S.; Turksen, H. Electricity load forecasting using hybrid ARIMA and XGBoost model. Energy Build. 2020, 210, Art. [Google Scholar]


| Parameter | Estimated Value | Description |
|---|---|---|
| ϕ1 | 0.88 | AR coefficient with 1st lag |
| ϕ2 | -0.15 | AR coefficient with 2nd lag |
| θ1 | 0.43 | MA coefficient |
| c | 320 | Constant Value |
| σ2 | 16,1 | Error Variance |
| Year | ARIMA | Exponential | Linear | Polynomal | Lasso | Random Forest | Ridge | SVR | XGBoost |
|---|---|---|---|---|---|---|---|---|---|
| 2025 | 78235,05193 | 80269,10169 | 77034,62224 | 81618,93856 | 77028,595 | 70197,18496 | 75947,7147 | 62951,9221 | 72240,49 |
| 2026 | 81516,97493 | 86310,55737 | 80684,37813 | 88399,96759 | 80672,229 | 70197,18496 | 78493,3948 | 62951,9794 | 72240,49 |
| 2027 | 84151,61485 | 92352,01304 | 83328,26009 | 95184,34444 | 83315,516 | 69077,68442 | 81030,0512 | 62952,0367 | 72240,49 |
| 2028 | 86266,63325 | 98393,46872 | 85972,14206 | 101972,0691 | 85958,804 | 68095,7602 | 83566,7076 | 62952,0939 | 71598,09 |
| 2029 | 87964,51341 | 104434,9244 | 89621,89794 | 108763,1416 | 89602,437 | 66820,35855 | 86112,3877 | 62952,151 | 71598,09 |
| 2030 | 89327,52615 | 110476,3801 | 93271,65382 | 115557,562 | 93246,071 | 66321,99547 | 88658,0678 | 62952,208 | 71598,09 |
| Model | Year | MAE (GWh) | RMSE (GWh) |
|---|---|---|---|
| Lasso | 2023 | 19,69 | 19,69 |
| Random Forest | 2023 | 4,705 | 4,705 |
| Lasso | 2024 | 6,49 | 6,49 |
| Random Forest | 2024 | 5,698 | 5,698 |
| Year | Arima | Exponential | Linear | Polynomal | Lasso | Random Forest | Ridge | SVR | XGBoost | Hybrid |
|---|---|---|---|---|---|---|---|---|---|---|
| 2025 | 78235,05193 | 80269,10169 | 77034,62224 | 81618,93856 | 77028,595 | 70197,18496 | 75947,7147 | 62951,9221 | 72240,49 | 77028,6 |
| 2026 | 81516,97493 | 86310,55737 | 80684,37813 | 88399,96759 | 80672,229 | 70197,18496 | 78493,3948 | 62951,9794 | 73740,49 | 80672,23 |
| 2027 | 84151,61485 | 92352,01304 | 83328,26009 | 95184,34444 | 83315,516 | 69077,68442 | 81030,0512 | 62952,0367 | 76220,49 | 83315,52 |
| 2028 | 86266,63325 | 98393,46872 | 85972,14206 | 101972,0691 | 85958,804 | 68095,7602 | 83566,7076 | 62952,0939 | 79678,09 | 85958,8 |
| 2029 | 87964,51341 | 104434,9244 | 89621,89794 | 108763,1416 | 89602,437 | 66820,35855 | 86112,3877 | 62952,151 | 81598,09 | 89602,44 |
| 2030 | 89327,52615 | 110476,3801 | 93271,65382 | 115557,562 | 93246,071 | 66321,99547 | 88658,0678 | 62952,208 | 83798,09 | 93246,07 |
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