Development Model for the Charging Infrastructure in the City of Moscow

The article analyzes the current state and development trends of charging infrastructure for electric vehicles. The object of study is the need for charging infrastructure in Moscow, expressed in the number of electric charging stations (ECS) and the zonal distribution of installed capacities. A forecast model of the charging infrastructure requirements in Moscow for the period from 2025 to 2035 has been developed. The formulated model enables forecasting of the total required number and distribution of fast and slow ECS across city districts. The total required number of ECS in Moscow will reach 55,900 units by 2035 according to the baseline forecast scenario, with slow ECS being the   predominant type. The model represents a significant tool for strategic planning and development of infrastructure for electric vehicles. The obtained forecast data contribute to long-term planning of electrical capacity requirements in Moscow districts.

1. Metais, M. O., Jouini, O., Perez, Y., Berrada, J., & Suomalainen, E. (2022). Too much or not enough? Planning electric vehicle charging infrastructure: A review of modeling options. Renewable and Sustainable Energy Reviews, 153, 111719.

2. Unterluggauer, T., Alonso-Mora, J., & Papaefthymiou, G. (2022). Electric vehicle charging infrastructure planning for integrated transportation and power distribution networks: A review. ETransportation, 12, 100163.

3. Al-Hanahi, B., Ahmad, I., Habibi, D., & Masoum, M. A. S. (2021). Charging infrastructure for commercial electric vehicles: Challenges and future works. IEEE Access, 9, 121476-121492.

4. London’s Electric Vehicle Infrastructure Plan. (2025). URL: https://lruc.content.tfl.gov.uk/tfl-london-electric-vehicle-infrastructure-delivery-plan. pdf (accessed: 28.01.2025).

5. Yi, Z., Smart, J., & Shirk, M. (2022). Electric vehicle charging demand forecasting using deep learning model. Journal of Intelligent Transportation Systems, 26(6), 690-703.

6. Soldan, F., Cesana, M., & Redondi, A. E. C. (2021). Short-term forecast of EV charging stations occupancy probability using big data streaming analysis. arXiv preprint arXiv:2104.12503.

7. Castro, J. F. C., Lopes, J. A. P., & Soares, F. J. (2022). Energy and demand forecasting based on logistic growth method for electric vehicle fast charging station planning with PV solar system. Energies, 15(17), 6106.

8. Rho, S., Chae, M., & Won, D. (2024). Forecast-based Optimal Operation of EV Charging Station with PV Considering Charging Demand and Distributed System. In 2024 IEEE Power & Energy Society Innovative Smart Grid Technologies Conference (ISGT) (pp. 1-5). IEEE.

9. London’s 2030 electric vehicle infrastructure strategy. (2021). URL: https://lruc.content.tfl.gov.uk/ london-2030-electric-vehicle-infrastructure-strategy-executive-summary-december-2021.pdf (accessed: 28.01.2025).

10. A prediction model for the demand of charging stations for electric vehicles in the municipality of Amsterdam. (2025). URL: https://www.researchgate.net/publication/305034047_A_prediction_model_for_the_demand_of_charging_stations_for_electric_vehicles_in_the_municipality_of_Amsterdam (accessed: 28.01.2025).

11. Hall, D., & Lutsey, N. (2020). Charging infrastructure in cities: Metrics for evaluating future needs. Europe, 6(7), 8.

12. Chen, T., Zhang, X.-P., Wang, J., Li, J., Wu, C., Hu, M., & Bian, H. (2020). A review on electric vehicle charging infrastructure development in the UK. Journal of Modern Power Systems and Clean Energy, 8(2), 193-205.

13. Sanatov, D.V., Abakumov, A.M., Aydemirov, A.Yu., et al. (2021). Perspektivy razvitiya rynka elektrotransporta i zaryadnoy infrastruktury v Rossii: Ekspertno-analiticheskiy doklad [Prospects for the development of the electric transport market and charging infrastructure in Russia: Expert analytical report]. Saint Petersburg: POLYTEX-PRESS, 44 p.

14. Dkhakal, T., & Min, K.S. (2021). Makroanaliz i prognoz perspektiv rasprostraneniya elektromobiley [Macro-analysis and forecast of electric vehicle adoption prospects]. Forsayt [Foresight], 15(1), 67-73.

15. Yusupova, O.A. (2021). Tekushchee sostoyanie i trendy rynka elektromobiley v Rossii i mire [Current state and trends of the electric vehicle market in Russia and the world]. ETAP: ekonomicheskaya teoriya, analiz, praktika [STAGE: Economic Theory, Analysis, Practice], 6, 131-143.

16. Chervova, N. V. (2023). Rynok elektromobiley: etapy, tendentsii i perspektivy razvitiya [Electric vehicle market: stages, trends and development prospects]. Gumanitarnye, sotsial’no-ekonomicheskie i obshchestvennye nauki [Humanities, Socio-Economic and Social Sciences], 7, 252-255.

17. Rynok legkovykh avtomobiley s probegom v Rossii v 2024 godu i v dekabre [The used car market in Russia in 2024 and in December]. URL: https://www.autostat.ru/press-releases/59289/ (accessed: 28.01.2025).

18. Charging up China’s transition to electric vehicles. (2024). URL: https://theicct.org/wp-content/uploads/2024/01/ID-93-%E2%80%93-China-charging-Report-A4-70131-v6.pdf (accessed: 28.01.2025).

19. Key factors influencing Electric Vehicles adoption. (2025). Informational portal Diva. URL: https://www.diva-portal.org/smash/get/diva2:1604160/FULLTEXT02 (accessed: 28.01.2025).

20. Visaria, A. A., Boyle, L. N., Choudhary, T., Stavrinos, D., & Fagnant-Speier, D. J. (2022). User preferences for EV charging, pricing schemes, and charging infrastructure. Transportation Research Part A: Policy and Practice, 165, 120-143.

21. Bhat, F. A., Verma, M., & Verma, A. (2022). Measuring and modelling electric vehicle adoption of Indian consumers. Transportation in Developing Economies, 8(1), 6.