Aerospace Technic and Technology

The subject of this study is the process of engineering and geodetic surveys for developing road projects. The purpose of this article is to improve the efficiency of the process of engineering and geodetic research in road design by implementing remote data from various sources and their systematization and algorithmization of use. The task is to analyze the preparatory and field stages of the process to determine possible ways of increasing its efficiency. Focusing on information flows, to develop an information model of the process of engineering and geodetic surveys and the corresponding scientific and methodological support for road design to introduce advanced technologies for collecting data about the terrain, which reduce the time of surveys and increase the accuracy of the results obtained. For this, the following methods are used: system and structural analysis, set theory, and DFD modeling. Scientific results have been obtained. The requirements of the current legislation regarding searches and the best experience of their conduct have been systematized. A set-theoretic model of information flows of the process of engineering and geodetic surveys is proposed, with the involvement of structural modeling approaches that make it possible to combine remote data from different sources and consider the dynamics of their changes and the logic of interaction. The IDEF0 model, which considers remote sensing data as a source of accurate and up-to-date information, has been developed, and the data flow diagram algorithmizes the mechanism of their combination to obtain the necessary topographical and geodetic materials. The developed scientific and methodical support for information support of road design creates a structure of information technology for engineering and geodetic surveys. Its experimental use has confirmed the reduction of the time for performing geodetic works while simultaneously increasing the accuracy of the obtained geometric and geodetic parameters, which are necessary for the formation of objective conclusions when forming the estimate of the road project, determining the scope of works, etc. Conclusions. The results of the bibliographic search confirmed that the effectiveness of the topographic-geodetic survey procedure in road design is complicated by the large size of the geographical areas to be surveyed, complex engineering and geological conditions, or the presence of restrictions on the duration of work and financial resources. This leads to the need to practically implement into the project-research organizations new approaches based on highly productive methods of collecting information about the area. The scientific and methodological provision of information support for road design has been developed, in particular, the structure of the information technology of engineering and geodetic surveys. Its experimental use has confirmed the reduction of the time required to perform searches and the improvement of the accuracy of the obtained geometric and geodetic parameters of the area where the implementation of the road project is planned.

Remote sensing as effective road project tool

Song, Y., Wu, P., Hampson, K., Anumba, Ch. Assessing block-level sustainable transport infrastructure development using a spatial trade-off relation model. International Journal of Applied Earth Observation and Geoinformation, 2021, vol. 105, article no. 102585. DOI: 10.1016/j.jag.2021.102585.

Danshyna, S. Yu. Metody otsiniuvannia stanu transportnoi infrastruktury v proiektakh rozvytku rehionu [Methods for assessing the state of transport infrastructure in regional development projects]. Intelektualni informatsiini systemy v upravlinni proiektamy ta ekonomitsi v umovakh voiennoho stanu : materialy Mizhnar. nauk.-prakt. konf. [Proc. Int. Conf. “Innovative integrated computer systems in strategic project management”], Kharkiv, 2022, pp. 64-67. (In Ukrainian).

Sobko, Yu. M., Sidun, Yu. V., Karasova, L. O. Proektuvannia avtomobilnykh dorih [Highways design]. Lviv, Vyd-vo Lvivskoi politekhniky Publ., 2019. 228 p. (In Ukrainian).

Zvit Derzhavnoho ahentstva avtomobilnykh dorih Ukrainy [Report of the State Automobile Roads Agency of Ukraine]. Available at: http://ukravtodor.gov.ua/4489/zvity/54474/54475.pdf (Accessed 27.11.2022).

Ilchenko, M., Narytnik, T., Rassаmakin, B., Prisyazhny, V., Kapshtik, S. Sozdaniye arkhitektury «raspredelennogo sputnika» dlya nizkoorbital'nykh informatsionno-telekommunikatsionnykh sistem na osnove gruppirovki mikro- i nanosputnikov [Creation of the architecture of "distributed satellite" for low-orbital information-telecommunication systems based on the grouping of micro and nano satellites]. Aviacijno-kosmicna tehnika i tehnologia – Aerospace technic and technology, 2018, no. 2 (146), pp. 33 - 43. doi: 10.32620/aktt.2018.2.05 (In Russian).

Chen, Z., Deng, L., Luo, Yu., Li, D., Junior, J. M., Gonсalves, W. N., Nurunnabi, A. A., Li, J., Wang, Ch. Road extraction in remote sensing data: A survey. International Journal of Applied Earth Observation and Geoinformation, 2022, vol. 112, article no. 102833. DOI: 10.1016/j.jag.2022.102833.

Danshyna, S. Yu., Nechausov, A. S., Andrieiev, S. M. Information technology of transport infrastructure monitoring based on remote sensing data. Radio Electronics, Computer Science, Control, 2022, no. 4, pp. 86-97. DOI: 10.15588/1607-3274-2022-4-7.

DBN V.2.3-4-2015. Avtomobilʹni dorohy. Chastyna I. Proektuvannya. Chastyna II. Budivnytstvo [Building Code В.2.3-4-2015. Highways. Part I. Design. Part II. Building]. Kyiv, Ministry of the Region of Ukraine Publ., 2015. 102 p. (In Ukrainian).

DBN A.2.1-1-2008. Vyshukuvannya. Inzhenerni vyshukuvannya dlya budivnytstva [Building Code A.2.1-1-2008. Survey. Engineering survey is in building]. Kyiv, Ministry of Regional Construction of Ukraine Publ., 2008. 76 p. (In Ukrainian).

Eker, R. Comparative use of PPK-integrated close-range terrestrial photogrammetry and a handheld mobile laser scanner in the measurement of forest road surface deformation. Measurement, 2023, vol. 206, article no. 112322. DOI: 10.1016/j.measurement.2022.112322.

Robson, E., Agosti, A., Utili, S., Milledge, D. A methodology for road cutting design guidelines based on field observations. Engineering Geology, 2022, vol. 307, article no. 106771. DOI: 10.1016/j.enggeo.2022.106771.

Banick, R., Heyns, A. M., Regmi, S. Evaluation of rural roads construction alternatives according to seasonal service accessibility improvement using a novel multi-modal cost-time model: A study in Nepal's remote and mountainous Karnali province. Journal of Transport Geography, 2021, vol. 93, article no. 103057. DOI: 10.1016/j.jtrangeo.2021.103057.

Guo, D., Yan, X., Zalewski, J., Villiers, C. Visualization of road geometries based on CADD design standards. Advances in Engineering Software, 2010, vol. 41, iss. 4, pp. 561-568. DOI: 10.1016/j.advengsoft.2009.11.003.

Zhang, H., Zhang, M., Zhang, Ch., Hou, L. Formulating a GIS-based geometric design quality assessment model for Mountain highways. Accident Analysis & Prevention, 2021, vol. 157, article no. 106172. DOI: 10.1016/j.aap.2021.106172.

Jacob, A., Dhanya, R., Anjaneyulu, M. V. L. Geometric Design Consistency of Multiple Horizontal Curves on Two-lane Rural Highways. Social and Behavioral Sciences Procedia, 2013, vol. 104, pp. 1068-1077. DOI: 10.1016/j.sbspro.2013.11.202.

D’Amico, F., Bertolini, L., Napolitano, A., Bianchini-Ciampoli, L., Manalo, J. R. D., Gagliardi, V., Calvi, A. A possible implementation of non-destructive data surveys in the definition of BIM-models for the analysis of road assets. Transportation Research Procedia, 2023, vol. 69, pp. 187-194. DOI: 10.1016/j.trpro.2023.02.161.

Pro topohrafoheodezychnu ta kartohrafichnu diyalʹnistʹ. Zakon Ukrayiny vid 26 sichnya 1999 r., No. 353-XIV [On Topographic, Geodesic and Cartographic Activity : Law of Ukraine of 26 January 1999, no. 353-ХІV]. Ofitsiinyi visnyk Ukrainy, 1999, no. 3, Art. 91, pp. 2. (In Ukrainian).

Lukas, V., Eldridge, D. F., Jason, A. L., Saghy, D. L., Steigerwald, P. R., Stoker, J. M., Sugarbaker, L. J., and Thunen, D. R. Status Report for the 3D Elevation Program, 2013-2014. Open-File Report 2015–1161. U.S. Geological Surveyy, Reston, Virginia, 2015. 17 p. DOI: 10.3133/ofr20151161.

Yadav, M. A multi-constraint combined method for road extraction from airborne laser scanning data. Measurement, 2021, vol. 186, article no. 110077. DOI: 10.1016/j.measurement.2021.110077.

Danshyna, S., Cheranovskiy, V. Formalizing the land inventory process for information support of land projects management. Radioelektronni i komp'uterni sistemi – Radioelectronic and computer systems, 2022, no. 3, pp. 7-19. DOI: 10.32620/reks.2022.3.01.

Kokotina, V. V., Stepanenko S. M. Normokontrol' konstruktorskoy dokumentatsii v usloviyakh reformirovaniya sistemy tekhnicheskogo regulirovaniya [Design documentation review in the conditions of technical regulation system reforming]. Aviacijno-kosmicna tehnika i tehnologia – Aerospace technic and technology, 2019, no. 8 (160), pp. 158-162. DOI: 10.32620/aktt.2019.8.23 (In Russian).

Zhang, H., Liu, W., Xiong, H., Dong, X. Analyzing data flow diagrams by combination of formal methods and visualization techniques. Journal of King Saud University – Computer and Information Sciences, 2023, vol. 35, iss. 2, pp. 626-640. DOI: 10.1016/j.jksuci.2023.01.006.

Cheema, S. M., Tariq, S., Pires, I. M. A natural language interface for automatic generation of data flow diagram using web extraction techniques. Journal of Visual Languages & Computing, 2018, vol. 48, pp. 41-51. DOI: 10.1016/j.jvlc.2018.08.001.