Al Ani, M.Q.A.G. (2022). The role of urban preservation to achieve sustainable urban development – preserving erbil citadel as case study. Acta Scientiarum Polonorum. Administratio Locorum, 21(1), 15–24. https://doi.org/10.31648/ASPAL.7037.
Crossref
Google Scholar

Albalate, D., & Bel, G. (2010). Tourism and urban public transport: Holding demand pressure under supply constraints. Tourism Management, 31(3), 425–433.
Crossref
Google Scholar

Altuntaş Vural, C., & Aktepe, C. (2021). Why do some sustainable urban logistics innovations fail? The case of collection and delivery points. Research in Transportation Business & Management, 3. https://doi.org/10.1016/j.rtbm.2021.100690.
Crossref
Google Scholar

Bo, W., Grygorak, M., Voitsehovskiy, V., Lytvynenko, S., Gabrielova, T., Bugayko, D., Ivanov, Y., & Vidovic, A. (2019). Cargo flows management model of network air carrier. Economic Studies Journal, 4, 118–124.
Crossref
Google Scholar

Crisis Logistics Center. (2022). Retrieved from: https://pomich.org/shippers.
Google Scholar

Daganzo, C.F. (2007). Urban gridlock: macroscopic modeling and mitigation approaches. Transportation Research Part B: Methodological, 41(1), 49–62.
Crossref
Google Scholar

Galkin, A., Popova, Y., Kyselov, V., Kniazieva, T., Kutsenko, M., & Sokolova, N. (2020, December 14–17). Comparison of Urban Conventional Delivery and Green Logistics Solutions [Paper presentation]. 13th International Conference on Developments in eSystems Engineering (DeSE), Liverpool, United Kingdom.
Crossref
Google Scholar

Galkin, A., Popova, Yu., Chuprina, E., & Shapovalenko, D. (2019, April 10–11). Interaction of logistics 4.0 and Consumer Oriented Marketing Using [Paper presentation]. 33rd Int. Business Information Management Association Conference, Granada, Spain.
Google Scholar

Gardrat, M. (2021). Urban growth and freight transport: From sprawl to distension. Journal of Transport Geography, 91, 102–979.
Crossref
Google Scholar

Geroliminis, N., & Boyacı, B. (2012). The effect of variability of urban systems characteristics in the network capacity. Transportation Research Part B: Methodological, 46(10), 1607–1623.
Crossref
Google Scholar

Geroliminis, N., & Daganzo, C.F. (2008). Existence of urban-scale macroscopic fundamental diagrams: some experimental findings. Transportation Research Part B: Methodological, 42(9), 759–770.
Crossref
Google Scholar

Guo, X.L., & Lu, Z.M. (2016). Urban road network and taxi network modeling based on complex network theory. Journal of Information Hiding and Multimedia Signal Processing, 7(3), 558–568.
Google Scholar

Gutierrez, A., & Miravet, D. (2016). The determinants of tourist use of public transport at the destination. Sustainability, 8, 908.
Crossref
Google Scholar

Hącia, E. (2019). The role of tourism in the development of the city. Transportation Research Procedia, 39, 104–111.
Crossref
Google Scholar

Horobets, N., Lytvyn, N., Starynskyi, M., Karpushova, E., & Kamenska, N. (2021). Settlement of administrative disputes with the participation of a judge: Foreign experience and implementation in Ukraine. Journal of Legal, Ethical and Regulatory Issues, 24(1), 1–7.
Google Scholar

İmre, Ş., Celebi, D., & Koca, F. (2021). Understanding barriers and enablers of electric vehicles in urban freight transport: Addressing stakeholder needs in Turkey. Sustainable Cities and Society, 68, 102–794.
Crossref
Google Scholar

ITF. (2019). Electrifying postal delivery vehicles in Korea. Paris: OECD Publishing.
Google Scholar

ITF. (2020). The ITF urban freight transport model – Insights and example outputs. Retrieved from: https://ec.europa.eu/research/participants/documents/downloadPublic?documentIds=080166e5cc3f0e15&appId=PPGMS.
Google Scholar

ITF. (2021). ITF Transport Outlook 2021. Retrieved from: https://www.oecd-ilibrary.org/sites/16826a30-en/1/3/5/index.html?itemId=/content/publication/16826a30-en&_csp_=190cc6434d2fccf11e2098c 12744cdb5&itemIGO=oecd&itemContentType=book.
Google Scholar

Kostyuchenko, O.E., Kolesnik, T.V., Bilous, Z.V., & Tavolzhanskyi, O.V. (2019). Robotization of manufacturing process: economic and social problems and legal ways of their solution. Financial and Credit Activity: Problems of Theory and Practice, 3(30), 454–462.
Crossref
Google Scholar

Lu, F., Liu, K., Duan, Y., Cheng, S., & Du, F. (2018). Modeling the heterogeneous traffic correlations in urban road systems using traffic-enhanced community detection approach. Physica A: Statistical Mechanics and its Applications, 501, 227–237.
Crossref
Google Scholar

Lu, Z.M., Wu, Z., Guo, S.Z., Zhe, C., & Guang-Hua, S. (2014). A New Dynamic Community Model for Social Networks. International Journal of Modern Physics C, 25(2), 215–244.
Crossref
Google Scholar

Martyn, A., Koshel, A., Hunko, L., & Kolosa, L. (2022). Land consolidation in ukraine after land reform: voluntary and forced mechanisms. Acta Scientiarum Polonorum. Administratio Locorum, 21(2), 223–229. https://doi.org/10.31648/aspal.6702.
Crossref
Google Scholar

Martynovych, N., Boichenko, E., Vivchar, O., Myskova, N., Popovych, O., & Kasianenko, O. (2019). Formation of educational level of the population of Ukraine in the conditions of formation of information society. International Journal of Engineering and Advanced Technology, 9(1), 6406–6410.
Crossref
Google Scholar

Porta, S., Crucitti, P., & Latora, V. (2006). The network analysis of urban streets: a dual approach. Physica A, 369(2), 853–866.
Crossref
Google Scholar

Russo, S.M., Voegl, J., & Hirsch, P. (2021). A multi-method approach to design urban logistics hubs for cooperative use. Sustainable Cities and Society, 69, 102–847.
Crossref
Google Scholar

Sarana, S., Fast, O., Sydorenko, V., Oliinyk, O., & Lytvyn, N. (2019). Specific features of taxation in Ukraine for operations on the supply of health care services. Georgian Medical News, 296, 160–165.
Google Scholar

Šourek, D. (2021). Software Support of City Logistics’ Processes. Transportation Research Procedia, 55, 172–179.
Crossref
Google Scholar

State Agency for Tourism Development of Ukraine (2022). Retrieved from: https://www.tourism.gov.ua.
Google Scholar

VzayemoDiya. (2022). Retrieved from: https://viyna.net.
Google Scholar

Wang, S., Yu, D., Ma, X., & Xing, X. (2018). Analyzing urban traffic demand distribution and the correlation between traffic flow and the built environment based on detector data and POIs. European Transport Research Review, 10(50), 1–17.
Crossref
Google Scholar

Yang, Y., Li, D., & Li, X. (2019). Public Transport Connectivity and Intercity Tourist Flows. Journal of Travel Research, 58(1), 25–41.
Crossref
Google Scholar

Zambrano-Martinez, J.L., Calafate, C.T., Soler, D., & Cano, J.C. (2017). Towards realistic urban traffic experiments using DFROUTER: Heuristic, validation and extensions. Sensors, 17(12), 29–21.
Crossref
Google Scholar

Zambrano-Martinez, J.L., Calafate, C.T., Soler, D., Cano, J.C., & Manzoni, P. (2018). Modeling and characterization of traffic flows in urban environments. Sensors, 18(7), 2020.
Crossref
Google Scholar

Zhang, Y., Zheng, X., Chen, M., Li, Y., Yan, Y., & Wang, P. (2021). Urban Fine-Grained Spatial Structure Detection Based on a New Traffic Flow Interaction Analysis Framework. ISPRS International Journal of Geo-Information, 10(4), 227.
Crossref
Google Scholar

Zhao, S., Zhao, P., & Cui, Y. (2017). A network centrality measure framework for analyzing urban traffic flow: a case study of Wuhan, China. Physica A, 478, 143–157.
Crossref
Google Scholar

Zhiriy, K. (2022). The main losses are still ahead: Ukrainians were told how the war hit tourism. Retrieved from: https://www.unian.ua/economics/finance/osnovni-vtrati-shche-poperedu-ukrajincyamrozpovili-yak-viyna-vdarila-po-turizmu-noviniukrajina-11866203.html.
Google Scholar