UDC: 656.02
https://doi.org/10.25198/2077-7175-2024-3-64
EDN: JIPRZJ

ISSUES OF TRANSPORT SECTOR IMPROVEMENT IN THE CONTEXT OF CONNECTED VEHICLES DEVELOPMENT

D. V. Kapski
Higher Attestation Commission of the Republic of Belarus, Minsk, Republic of Belarus
e-mail: d.kapsky@gmail.com

S. V. Bogdanovich
Belarusian National University of Technology, Minsk, Republic of Belarus
e-mail: bsw001@gmail.com

P. V. Kurenkov
Samara State Transport University, Moscow, Russia
e-mail: petrkurenkov@mail.ru

N. A. Filippova
Moscow Automobile and Road Construction State Technical University (MADI), Moscow, Russia
e-mail: umen@bk.ru

Abstract. The article examines topical issues of improving the transportation industry in the context of the active development and implementation of connected vehicles (CVs). The relevance of the topic is driven by the rapid growth in the number of CVs, their increasing impact on the transportation system, and the need for a comprehensive optimization of the industry to fully realize the potential of new technologies.

The main objective of the work is to identify key ways and specific measures to improve the transportation industry that will allow maximizing the benefits of CVs. To achieve this goal, a systems approach is used, which involves a comprehensive consideration of the complex interrelationships between vehicles, infrastructure, and transportation services. The implementation of Intelligent Transportation Systems (ITS) plays a crucial role in optimizing the interaction of these components.

The article identifies the main opportunities and challenges associated with the development of CVs. New opportunities include improving road safety, reducing emissions, optimizing logistics and transportation, and enhancing mobility. At the same time, new challenges are emerging, including the need to ensure cybersecurity of CVs, standardization of heterogeneous systems and technologies, and their seamless interaction.

The impact of CVs on key aspects of the transportation industry – safety, environment, economy, and social sphere – is analyzed in detail. Specific ways to improve safety are shown through accident prevention systems and driver monitoring systems. The potential of CVs to reduce emissions through traffic optimization and development of alternative modes of transportation is considered. Ways to increase efficiency through logistics optimization, vehicle maintenance, and driver routing are identified. Social effects in the form of increased mobility and new services for passengers are highlighted. The scientific novelty lies in the comprehensive systems consideration of a wide range of problems and ways to improve the transportation industry, taking into account the rapid development of CVs. The practical significance is the specific recommendations on applying a systems approach and implementing ITS to achieve maximum effect.

Further research directions include a detailed elaboration of the proposed specific measures to maximize the benefits and minimize the risks associated with the proliferation of CVs. In particular, it is recommended to further optimize logistics processes, vehicle fleets and driver activities, accelerate the development of alternative modes of transportation and services to improve passenger comfort and safety, and establish close cooperation among all stakeholders.

Key words: autonomous vehicles, transport industry improvement, connected transport systems, systemic approach, intelligent transport systems, road safety.

Cite as: Kapski, D. V., Bogdanovich, S. V., Kurenkov, P. V., Filippova, N. A. (2024) [Issues of transport sector improvement in the context of connected vehicles development]. Intellekt. Innovacii. Investicii [Intellect. Innovations. Investments]. Vol. 3, pp. 64–73. – https://doi.org/10.25198/2077-7175-2024-3-64.


References

  1. Kapsky, D. V., Bogdanovich, S. V. (2021) [Sustainable logistics of smart symbiotic cities]. Problemy bezopasnosti na transporte : MATERIALY KHI MEZHDUNARODNOY NAUCHNO-PRAKTICHESKOY KONFERENTSII. V 2 chastyakh, Gomel’, 25–26 noyabrya 2021 goda [Problems of transport safety: MATERIALS OF THE XI INTERNATIONAL SCIENTIFIC AND PRACTICAL CONFERENCE. In 2 parts, Gomel, November 25–26, 2021]. Part 1. Gomel: Educational Institution «Belarusian State University of Transport», pp. 22–24. – EDN: AOLWKD. (In Russ.).
  2. Kapsky, D. V., Bogdanovich, S. V., Burtyl, Yu. V. (2022) Metodologiya otsenki vozdeystviya izmeneniya klimata, uyazvimosti i klimaticheskikh riskov v transportnoy sisteme Respubliki Belarus’ [Methodology for assessing the impact of climate change, vulnerability and climate risks in the transport system of the Republic of Belarus]. Minsk: BNTU, 256 p.
  3. Kapsky, D. V., Bogdanovich, S. V., Skirkovsky, S. V. (2022) [Prospects for the development of urban logistics and transport systems]. Problemy bezopasnosti na transporte: materialy KHII Mezhdunar. nauch.-prakt. konf., posvyashch. 160-letiyu Bel. zh. d. (Gomel’, 24–25 noyabrya 2022 g.) : v 2 ch. [ Problems of s afety i n t ransport: materials of the XII International. scientific-practical conf., dedicated 160th anniversary of Bel. and. (Gomel, November 24–25, 2022): at 2 p.m]. Part 2. Generally ed. Yu. I. Kulazhenko. Gomel: BelSUT, pp. 119–121. – EDN: MAPKRC. (In Russ.).
  4. Kapsky, D. V., Navoy, D. V., Bogdanovich, S. V. (2021) [Algorithms for detecting road incidents]. X forum vuzov inzhenerno-tekhnologicheskogo profilya Soyuznogo gosudarstva. 6-10 dekabrya 2021 g. [X Forum of Universities of Engineering and Technology of the Union State. December 6–10], ]. Minsk: BNTU, pp. 74–75. (In Russ.).
  5. Pugachev, I. N., et al. (2023) Planirovaniye ustoychivoy gorodskoy mobil’nosti [Planning for sustainable urban mobility]. Khabarovsk: Publishing house DVGUPS, 147 p. – EDN: DOUXSG.
  6. 5 Ways Any Vehicle Benefits from a Driver Monitoring System (DMS). Available at: https://www.smarteye.se/blog/5-ways-any-vehicle-benefits-from-a-driver-monitoring-system-dms/ (accessed: 28.02.2024) (In Eng.).
  7. Autonomous driving’s future: Convenient and connected. Available at: https://www.mckinsey.com/industries/automotive-and-assembly/our-insights/autonomous-drivings-future-convenient-and-connected (accessed: 28.02.2024) (In Eng.).
  8. Carey, Ch. (2022) Study shows smart traffic systems could cut CO2 emissions. Available at: https://cities-today.com/study-shows-smart-traffic-systems-could-cut-co2-emissions/ (accessed: 28.02.2024) (In Eng.).
  9. Connected cars worldwide – statistics & facts. Available at: https://www.statista.com/topics/1918/connected-cars/#topicOverview (accessed: 28.02.2024) (In Eng.).
  10. Coppola, R., Morisio, M. (2016) Connected Car: technologies, issues, future trends. Available at: https://core.ac.uk/download/pdf/76532623.pdf (accessed: 28.02.2024) (In Eng.).
  11. Fiat Chrysler recalls 1.4 million cars after Jeep hack. Available at: https://www.bbc.com/news/technology-33650491 (accessed: 28.02.2024) (In Eng.).
  12. Future Intelligent Transport Systems Strategy. Available at: https://www.transport.gov.scot/media/40406/its-strategy-2017-final.pdf (accessed: 28.02.2024) (In Eng.).
  13. Greenberg, A. Securing Driverless Cars From Hackers Is Hard. Ask the Ex-Uber Guy Who Protects Them. Available at: https://www.wired.com/2017/04/ubers-former-top-hacker-securing-autonomous-cars-really-hard-problem/ (accessed: 28.02.2024) (In Eng.).
  14. Hacker, Selling Data Allegedly Stolen From Volvo Cars Following Ransomware Attack. Available at: https:// www.securityweek.com/hacker-selling-data-allegedly-stolen-volvo-cars-following-ransomware-attack/ (accessed: 28.02.2024) (In Eng.).
  15. Khandelwal, S. Hackers take Remote Control of Tesla’s Brakes and Door locks from 12 Miles Away. Available at: https://thehackernews.com/2016/09/hack-tesla-autopilot.html (accessed: 28.02.2024) (In Eng.).
  16. Livingston, H., Monroe, J., Washtenaw, L. (2017) Planning for Connected and Automated Vehicles. Available at: https://www.cargroup.org/wp-content/uploads/2017/03/Planning-for-Connected-and-Automated-Vehicles-Report.pdf (accessed: 28.02.2024) (In Eng.).