DETERMINATION OF FACTORS OF TERRITORIAL CONNECTION OF THE COUNTRY FOR DEVELOPMENT OF MULTIMODAL AIR TRANSPORT SYSTEM
Abstract
In modern economic realities, scientific and technical programs and innovative projects of a full cycle should become the dominant tools necessary for the effective implementation of the strategy of scientific and technological development of the Russian Federation. Specially created сouncils, the scope of which is related to the determination of priorities in the development of national science, should carry out the procedures for the formation and expert selection of innovative programs / projects of the full cycle. A list of complex scientific and technological projects proposed in the formation of the list of measures for 2020-2022 within the framework of the subprogram "Aviation Science and Technology" of the State Program of the Russian Federation "Development of Aviation Industry for 2013-2025" was compiled. A list of general goals of scientific and technological development of aircraft construction is presented. The most priority directions of scientific and technological development of modern civil aircraft construction have been determined. The authors considered the main goals, objectives and composition of the components included in the integrated air transport system. As a practical example, the formation of the appearance of a promising air transport system in terms of creating innovative technologies for existing and future aircraft, taking into account its integration into the multimodal transport system of the Russian Federation, is considered. The authors of the article propose a new approach to the development of a program / project of a complete innovation cycle based on the use of "gate" approach. The tasks of interaction with the Ministry of Transport of the Russian Federation on the creation of air transport system are considered.
References
Brueckner, J.K. (2003). Airline traffic and urban economic development. Urban Studies, vol. 40, vo. 8, 1455-1469.
Tikhonov, A., Novikov, S. (2020). Modern organization effective functioning evaluation. Quality - Access to Success, vol. 21, no. 178, 3-6.
Tikhonov, A.I., Sazonov, A.A., Novikov, S.V. (2019). Digital aviation industry in Russia. Russian Engineering Research, vol. 39, no. 4, 349-353.
Rodrigue, J.P. (2020). The Geography of Transport Systems. Routledge, New York, USA.
Kraev, J.P., Siluyanova, M.V., Tikhonov, A.I. (2020). Creation of supersonic civil aviation in Russia. Russian Engineering Research, vol. 40, no. 9, 755-758.
Van der Waal, J. W., Thijssens, T. (2020). Corporate involvement in sustainable development goals: Exploring the territory. Journal of Cleaner Production, no. 252, 119625.
Prentice, B.E. (2016). The Role of the Airship in the New Low-Carbon Era. The Shipper Advocate, 16-19.
Fuellhart, K., O’Connor, K. (2019). A supply-side categorization of airports across global multiple-airport cities and regions. GeoJournal, vol. 84, no. 1, 15-30.
Baykasoğlu, A., Subulan, K., Taşan, A.S., Dudaklı, N. (2019). A review of fleet planning problems in single and multimodal transportation systems. Transportmetrica A: Transport Science, vol. 15, no. 2, 631-697.
Dick, R., Patterson, D. (2003). Aviation Century: The Early Years. Boston Mills Press, Erin, Canada.
Vasilev, V.L., Gapsalamov, A.R., Akhmetshin, E.M., Bochkareva, T.N., Yumashev, A.V., Anisimova, T.I. (2020). Digitalization peculiarities of organizations: a case study. Entrepreneurship and Sustainability Issues, vol. 7, no. 4, 3173-3190.
Aparicio, J. T., Arsenio, E., Henriques, R. (2022). Assessing robustness in multimodal transportation systems: a case study in Lisbon. European Transport Research Review, vol. 14, no. 1, 1-18.
Graham, B. (1995). Geography and air transport. John Wiley & Sons, Chichester, UK.
Macleod, G., Jones, M. (2007). Territorial, scalar, networked, connected: In what sense a ‘regional world’?, Regional Studies, vol. 41, no. 9, 1177-1191.
Engler, E., Gewies, S., Banyś, P., Grunewald, E. (2018). Trajectory-based multimodal transport management for resilient transportation. Transport Problems, vol. 13, no. 1, 81-96.
Yergin, D.R., Vietor, P.C. (2000). Fettered Flight: Globalization and the Airline Industry. Cambridge Energy Research Associates, Cambridge, UK.
Pogosyan, M.A., Strelets, D.Y., Vladimirova, V.G. (2019). Territorial connectivity of the Russian Federation: from the statement of complex problems to drawing up integrated scientific and technical projects. Herald of the Russian Academy of Sciences, vol. 89, no. 2, 179-184.
Algaba, E., Fragnelli, V., Llorca, N., Sánchez-Soriano, J. (2019). Horizontal cooperation in a multimodal public transport system: The profit allocation problem. European Journal of Operational Research, vol. 275, no. 2, 659-665.
Han, B., Wan, M., Zhou, Y., Su, Y. (2020). Evaluation of multimodal transport in China based on hesitation fuzzy multiattribute decision-making. Mathematical problems in engineering, 2020, 1-9.
Ding, L. (2020). Multimodal transport information sharing platform with mixed time window constraints based on big data. Journal of Cloud Computing, vol. 9, no. 1, 1-11.
Agusdinata, B., De Klein, W. (2002). The dynamics of airline alliances. Journal of Air Transport Management, vol. 8, no. 4, 201-211.
Bowen, J. (2010). The Economic Geography of Air Transportation. Space, Time, and the Freedom of the Sky. Routledge, London, UK.
Adey, P., Budd, L., Hubbard, P. (2007). Flying Lessons: Exploring the Social and Cultural Geographies of Global Air Travel. Progress in Human Geography, vol. 31, no. 6, 773-791.
Budd, L., Goetz, A.R. (2014). The geographies of air transport. Ashgate Publishing Ltd, Farnham, UK.
Davies, R.E. (1964). A History of the World’s Airlines. Oxford University Press, London, UK.
O'Connell, J.F., Williams, G. (2011). Air transport in the 21st century: key strategic developments. Ashgate Publishing, Ltd, Farnham, UK.