Development of universal transport shceme for road traffic optimization in urban conditions.

Introduction. This article addresses the issue of optimizing the movement of road users in an urban environment. The need to resolve this issue arose due to the suboptimal design of the city’s street-road network, consisting in an increase in traffic intensity to limit values and the inability of traffic lights to solve the problems of global demand for vehicle movement. It is also important to address the issue of the movement of ever-increasing pedestrian flows.Optimization of traffic conditions is assumed by the device of integrated transport schemes. The main disadvantage of solving this issue is the limited regulatory documentation that would be applicable in urban environments.

Materials and methods. In the article, the authors used, as a fundamental method of analogy, a comparison of the categories of streets and urban roads with suburban highways. Also, the advantages of individual road junctions and their systems and the level of convenience of the streets of Tiumen were analyzed.

Results. The results are variants of complex traffic intersections that satisfy the requirements defined in advance regarding various types of intersections with the following indicators: distance between minor streets, number of lanes on the streets, radii of circular curves.

Conclusion. Based on the results of this article, it is advisable to consider the third variant of the complex intersection, which is the most promising in terms of the considered parameters.

1. Ahmed B., Hounsell N., Shrestha B. Investigating Bus Priority Parameters for Isolated Vehicle Actuated Junctions. Transportation Planning and Technology. 2016; 39(1): 45-58.

2. Ghods A.H., Fu L. Real-Time Estimation of Turning Movement Counts at Signalized Intersections Using Signal Phase Information. Transportation Research Part C: Emerging Technologies. 2014; 47: 128-138.

3. Cesme, B., Furth P.G. Self-Organizing Traffic Signals Using Secondary Extension and Dynamic Coordination, Transportation Research Part C: Emerging Technologies. 2014; 48: 1-15.

4. Busiello M., Ratkeviciute K., Zilioniene D., Russo F., Biancardo S.A., Dell’Acqua G. Preliminary Canter of the Accident Rate in Italian and Lithuanian Road Networks. In Environmental Engineering. Proceedings of the International Conference on Environmental Engineering. ICEE Vilnius Gediminas Technical University. Department of Construction Economics & Property. 2014; 9: 1 p.

5. Dobranskyte-Niskota A., Perujo A., Pregl M. Indicators to assess sustainability of transport activities. European Comission, Joint Research Centre. 2007.

6. Lim I., Kweon Y. Identifying High-Crash-Risk Intersections Comparison of Traditional Methods with the Empirical Bayes–Safety Performance Function Method. Transportation Research Record: Journal of the Transportations Research Board 2364. 2013. 44-50.

7. Gillis D., Semanjski I., Lauwers D. How to control sustainable mobility in cities? Literature review in the framework of creating a set of indicators of sustainable mobility. Sustainability. 2016. № 8, 29.

8. Peltola H., Rajamaki R., Luoma J. Tools Needed for Enhancing Transferability of Cost-Effective Road Safety Measures. In Procedia – Social and Behavioral Science. 2012; 48: 1234-1243.

9. Russo F., Biancardo S.A., Dell’acqua G. Road Safety from the Perspective of Driver Gender and Age as Related to the Injury Crash Frequency and Road Scenario. Traffic Injury Prevention. 2014; 15(1): 25-33.

10. Kartopol’cev V.M., Kiryakov E.I., Bychkov N.O., Privedennaya T.S. Sovremennye tendencii proektirovanija transportnyh razvjazok s uchjotom arhitekturno-kompozicionnyh reshenij [Modern trends in the design of transport interchanges taking into account architectural and compositional solutions]. Vestnik TGASU. №1. 2011. 109-115 (In Russian)

11. Sannikov S.P., Timohovec V.D., Kuzuek A.Yu. Transportnaja infrastruktura v modeljah uplotnenija gorodov [Transport infrastructure in urban densification models]. Transportnoe stroitel’stvo. 2019. 2-5 (In Russian)

12. Sannikov S., Timokhovetz V., Martuchenko A. Optimization of traffic at intersection of streets of Republic and Melnikayte in city Tyumen. IOP Conf. Ser.:Vater. Sci. Eng. 2018.

13. Sannikov S., Timokhovetz V., Ostapchuk E., Kuzuek A. A procedure for individual design of an interchange. Transportation Research Procedia 36. 2018. 682-688.

14. Isakov K., Stasenko L.N., Altybaev A.SH., Turdubek uulu A. Povyshenie propusknoj sposobnosti reguliruemyh peresechenij posredstvom izmeneniya cikla svetofornogo regulirovaniya [Increase in capacity of adjustable traverses by means of change of the traffi light regulation cycle]. Vestnik KGUSTA. 2016; 1: 313-320. (in Russian)

15. Isakov K., Stasenko L.N., Altybaev A.S., Daiyrbekova D. Influence of parameters of the trafficlight regulation cycle on the road capacity of regulated intersections. The Russian Automobile and Highway Industry Journal. 2019;16(2):146-155. (In Russian) DOI: 10.26518/2071-7296-2019-2-146-155.

16. Novikov A.N., Eremin S.V., Shevtsova A.G. Programoflight-formatregulationonthebasisofcontrolled networks and the saturations’ flow: basic principles of calculation. The Russian Automobile and Highway Industry Journal. 2019;16(6):680-691. (In Russian) DOI: 10.26518/2071-7296-2019-6-680-691.

17. Koekemoer K., Van Gesselleen M., Van Niekerk A., Govender R., Van As A. B. Child Pedestrian Safety Knowledge, Behaviour and Road Injury in Cape Town, South Africa. Accident Analysis and Prevention. 2017; 99 (A): 202-209.

18. Fu L., Zou N. The Influence of Pedestrian Countdown Signals on Children’s Crossing Behaviour at School Intersections. Accident Analysis and Prevention. 2016; 94: 73-79.

19. El’kin B.P., Karnauhov V.N., Andronov R.V. Programma «antiprobki», pervoocherednye jetapy realizacii [Anti-traffic jam program, priority stages of implementation]. Problemy funkcionirovaniya sistem transporta. 2010. 110-112. (In Russian)

20. Andronov R.V. Raschet jekonomicheskih poter’ pol’zovatelej ulichno-dorozhnoj seti na reguliruemyh peresechenijah dlja obosnovanija meroprijatij po rekonstrukcii i uluchsheniju organizacii dvizhenija [Calculation of economic losses of users of the road network at regulated intersections to justify measures for the reconstruction and improvement of traffic management]. Nauchno-tekhnicheskij vestnik Povolzh’ya. 2014. 38-40. (In Russian)

21. Andronov R.V., Leverenc E.E. Raschet metodom Monte-Karlo zaderzhek transportnyh sredstv na izolirovannom reguliruemom peresechenii pri ego rabote na vysokih urovnjah zagruzki [Monte Carlo calculation of vehicle delays at an isolated controlled intersection when it is operating at high load levels]. Vestnik grazhdanskih inzhenerov. 2017. 221-226. (In Russian)

22. Andronov R.V. Pereustrojstvo reguliruemyh peresechenij ulichno-dorozhnoj seti krupnogo goroda na osnove issledovanij zatorov transportnyh potokov [Reconstruction of regulated intersections of the road network of a large city based on studies of traffic congestion]. Omsk, SibADI, 2012. 35-37. (In Russian)

23. Novikov A.N., Novikov I.A., Shevtsova A.G., Burlutskaya A.G. USE OF THE RAMP METERING SYSTEM AT TWO-LEVEL JUNCTIONS. The Russian Automobile and Highway Industry Journal. 2019;16(2):166-180. (In Russian) DOI: 10.26518/2071-7296-2019-2-166-180.

24. Agureev I.E., Yurchenko D.A. Functioning of the car parking places near houses: formulation of the problem of the road city network. The Russian Automobile and Highway Industry Journal. 2019;16 (6):670-679. (In Russian) DOI: 10.26518/20717296-2019-6-670-679.

25. Shvecov V.I. Algoritmy raspredelenija transportnyh potokov [Algorithms for the distribution of traffi flows]. Avtomatika i Telemehanika. 2009; 10: 148-157 (in Russian).