employee from 01.01.2022 until now
Russian Federation
Russian Federation
UDC 528.23
CSCSTI 36.16
The goal of the work is to identify promising areas for the development of coordinate support as a basis for sustainable socio-economic development. From the standpoint of systems analysis, the technological aspects of establishing, maintaining, developing and distributing the global geocentric reference system (GGCRS) are studied. Various GGCRS realizations are considered, including primary realizations based on the ITRF network, alternative solutions obtained by leading foreign centers, realizations based on the International GNSS Service stations and realizations based on the orbital approach. The conducted analysis took into account the state of affairs in the field of domestic space geodesy and its use in the interests of coordinate support. Among the main achievements noted is the fact that during this time in the USSR and the Russian Federation, using the space geodetic complexes “Geoid” and “GEO-IK”, the GGCRS “Parametry Zemli 1977, 1985 and 1990” were created. Today, the prospects for the development of GGCRS are associated with the establishment of a qualitatively new global geodetic reference system, including geometric and physical reference frames; the GENESIS satellite launch, which will implement the principle of several measurements types colocation in space; the achievement of an unprecedented millimeter level of accuracy in determining the coordinates and velocities of reference points, which is specified in the GGOS project.
space geodetic complex, coordinate support, geocentric reference system, GNSS, IERS, GENESIS, GGOS, GGRF, ITRF, ITRS
1. Boucher C., Altamimi Z. ITRS, PZ-90 and WGS 84: current realizations and the related transformation parameters // Journal of Geodesy. 2001. Vol. 75. P. 613–619. DOIhttps://doi.org/10.1007/s001900100208.
2. Malys S., Solomon R., Drotar J., et al. Compatibility of Terrestrial Reference Frames used in GNSS broadcast messages during an 8 week period of 2019 // Advances in Space Research. 2020. Vol. 67. No. 2. P. 834–844. DOIhttps://doi.org/10.1016/j.asr.2020.11.029.
3. Gorobec V.P., Dem'yanov G.V., Mayorov A.N. i dr. Sovremennoe sostoyanie i napravleniya razvitiya geodezicheskogo obespecheniya RF. Sistemy koordinat // Geoprofi. 2013. № 6. S. 4–9.
4. Nepoklonov V.B., Gusev I.V., Vshivkova O.V. i dr. Perspektivy ispol'zovaniya rossiyskoy kosmicheskoy geodezicheskoy sistemy v nauchnoy i social'no-ekonomicheskoy sfere // Izvestiya vuzov «Geodeziya i aerofotos'emka». 2023. T. 67. № 4. S. 6–25. DOIhttps://doi.org/10.30533/GiA-2023-016.
5. Kuzin S.P. Stancii kolokacii v kosmicheskoy geodezii i trebovaniya k nim // Nauchnye trudy Instituta astronomii RAN. 2022. T. 7. № 4. S. 233–236. DOIhttps://doi.org/10.51194/INASAN.2022.7.4.002.
6. Kuzin S.P. Sovremennoe sostoyanie osnovnyh rossiyskih sputnikovyh geodezicheskih setey i perspektivy ih razvitiya // Nauchnye trudy Instituta astronomii RAN. 2022. T. 7. № 3. S. 208–211. DOIhttps://doi.org/10.51194/INASAN.2022.7.3.004.
7. Pearlman M., Brachet G., Lefebvre M., et al. The Smithsonian Astrophysical Observatory (SAO) and the Centre National d’Études Spatiales (CNES): contributions to the international laser ranging network // Journal of Geodesy. 2019. Vol. 93. P. 869–875. DOIhttps://doi.org/10.1007/s00190-018-1209-0.
8. Voronov L.V. Kosmicheskaya geodeziya na sluzhbe oborony strany // 70 let 29 Nauchno-issledovatel'skomu institutu Ministerstva oborony Rossiyskoy Federacii / pod red. N.I. Konona. M.: 29 NII MO RF, 2006. S. 41–44.
9. Zueva A.I., Rogozin V.P. Kosmicheskaya geodeziya na rubezhe tysyacheletiy // 70 let 29 Nauchno-issledovatel'skomu institutu Ministerstva oborony Rossiyskoy Federacii / pod red. N.I. Konona. M.: 29 NII MO RF, 2006. S. 127–133.
10. Kozlov S.V., Zueva A.N., Novikov E.V., Pleshakov D.I. Itogi modernizacii i perspektivy razvitiya sistemy geodezicheskih parametrov PZ-90 v celyah povysheniya tochnosti geodezicheskogo obespecheniya global'noy navigacionnoy sputnikovoy sistemy GLONASS // Trudy Instituta prikladnoy astronomii RAN. 2015. № 35. S. 11–16.
11. Barlier F., Lefebvre M. A new look at planet Earth: Satellite geodesy and geosciences // The Century of Space Science / Bleeker J.A.M., Geiss J., Huber M.C.E. (eds.). Dordrecht: Springer, 2001. P. 1623–1651.
12. Matveenko L.I. Istoriya RSDB — stanovlenie i razvitie // Soobscheniya Instituta prikladnoy astronomii RAN. SPb., 2007. № 176. 35 s.
13. Povalyaev E., Hutornoy S. Sistemy sputnikovoy navigacii GLONASS i GPS. Chast' 1 // Chip News. Inzhenernaya mikroelektronika. 2001. № 10. S. 48–55.
14. Wilkins G.A. Project MERIT and the formation of the International Earth Rotation Service // International Astronomical Union Colloquium. 2000. No. 178. P. 187–200. DOIhttps://doi.org/10.1017/S0252921100061339.
15. Boucher C. Geodetic Reference Frames: 40 Years of Technological Progress and of International Cooperation: 1970–2010 // Reference Frames for Applications in Geosciences. International Association of Geodesy Symposia. Altamimi Z., Collilieux X. (eds.). Heidelberg: Springer, 2013. Vol. 138. P. 1–4.
16. Bosy J. Global, regional and national geodetic reference frames for geodesy and geodynamics // Pure and Applied Geophysics. 2014. Vol. 171. No. 6. P. 783–808. DOIhttps://doi.org/10.1007/s00024-013-0676-8.
17. Pearlman M., Altamimi Z., Beck N., et al. Global Geodetic Observing System – considerations for the geodetic network infrastructure // Geomatica. 2006. Vol. 60. No. 2. P. 193–204.
18. Ozener H., Zerbini S., Bastos L., et al. WEGENER: World earthquake GEodesy network for environmental hazard research // Journal of Geodynamics. 2013. Vol. 67. P. 2–12. DOIhttps://doi.org/10.1016/j.jog.2012.12.005.
19. Moore A.W. The International GNSS Service: Any questions? // GPS World. 2007. No. 1. P. 58–64.
20. Altamimi Z., Rebischung P., Métivier L., et al. ITRF2014: A new release of the International Terrestrial Reference Frame modeling non-linear station motions: ITRF2014 // Journal of Geophysical Research: Solid Earth. 2016. Vol. 121. P. 6109–6131. DOIhttps://doi.org/10.1002/2016JB013098.
21. Altamimi Z., Rebischung P., Collilieux X., et al. ITRF2020: an augmented reference frame refining the modeling of nonlinear station motions // Journal of Geodesy. 2023. Vol. 97. P. 47. DOIhttps://doi.org/10.1007/s00190-023-01738-w.
22. Abbondanza C., Chin T.M., Gross R.S., et al. JTRF2014, the JPL Kalman filter and smoother realization of the International Terrestrial Reference System // Journal of Geophysical Research: Solid Earth. 2017. Vol. 122. No. 10. P. 8474–8510. DOIhttps://doi.org/10.1002/2017JB014360.
23. Ray J., Dong D., Altamimi Z. IGS reference frames: status and future improvements // GPS Solutions. 2004. Vol. 8. P. 251–266. DOIhttps://doi.org/10.1007/s10291-004-0110-x.
24. Gusev I.V., Golubickiy A.M. Ocenka soglasovannosti orbital'nyh realizaciy sistem koordinat, rasprostranyaemyh global'nymi navigacionnymi sputnikovymi sistemami, s Mezhdunarodnoy zemnoy sistemoy koordinat ITRF za 2020–2023 gg. // Geodeziya i kartografiya. 2024. № 2. S. 51–64. DOIhttps://doi.org/10.22389/0016-7126-2024-1004-2-51-64.
25. Herring T.A. Overview // Treatise on Geophysics. Vol. 3: Geodesy / Schubert G., Herring T.A. (eds.). Cambridge: Elsevier, 2007. P. 1–10.
26. Plag H.P., Pearlman M. Global Geodetic Observing System. Meeting the Requirements of a Global Society on a Changing Planet in 2020. Berlin: Springer, 2009. 367 p.
27. Delva P., Altamimi Z., Blazquez A., et al. GENESIS: co-location of geodetic techniques in space // Earth, Planets and Space. 2023. Vol. 75. P. 5. DOIhttps://doi.org/10.1186/s40623-022-01752-w.
