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Research Articles

Validating Geoid Models with Marine GNSS Measurements, Sea Surface Models, and Additional Gravity Observations in the Gulf of Finland

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Pages 196-214 | Received 15 Jul 2020, Accepted 09 Feb 2021, Published online: 11 Mar 2021

References

  • Ågren, J., G. Strykowski, M. Bilker-Koivula, O. Omang, S. Märdla, R. Forsberg, A. Ellmann, et al. 2016. The NKG2015 gravimetric geoid model for the Nordic-Baltic region. Presented at the Gravity, Geoid and Height Systems (GGHS), September 19–23, Thessaloniki, Greece.
  • Baltic Sea Hydrographic Commission. 2020. Working Groups, BSHC Chart Datum Working Group. Accessed 5.2.2021. http://www.bshc.pro/working-groups/cdwg/.
  • Barrass, C. B. 2004. Ship design and performance for masters and mates. London: Elsevier Butterworth-Heinemann.
  • Bilker-Koivula, M. 2010. Development of the Finnish height conversion surface FIN2005N00. Nordic Journal of Surveying and Real Estate Research 7 (1):76–88.
  • CMEMS (Copernicus Marine Environment Monitoring Service). 2016. Product user manual for Baltic Sea physical analysis and forecasting product: BALTICSEA_ANALYSIS_FORECAST_PHYS_003_006. http://cmems-resources.cls.fr/documents/PUM/CMEMS-BAL-PUM-003-006.pdf.
  • FAMOS (Finalising Surveys for the Baltic Motorways of the Seas). 2020. FAMOS project, Home. http://www.famosproject.eu/.
  • Geotrim. 2020. Palvelut, Trimnet VRS. https://geotrim.fi/palvelut/trimnet-vrs/.
  • Häkli, P., M. Lidberg, L. Jivall, T. Nørbech, O. Tangen, M. Weber, P. Pihlak, I. Aleksejenko, and E. Paršeliūnas. 2016. The NKG2008 GPS campaign – final transformation results and a new common Nordic reference frame. Journal of Geodetic Science 6:1–33.
  • Ince, E. S., C. Förste, F. Barthelmes, H. Pflug, M. Li, J. Kaminskis, K.-H. Neumayer, and G. Michalak. 2020. Gravity measurements along commercial ferry lines in the Baltic Sea and their use for geodetic purposes. Marine Geodesy 43 (6):573–602.
  • Koivula, H., J. Kuokkanen, S. Marila, T. Tenhunen, P. Häkli, U. Kallio, S. Nyberg, and M. Poutanen. 2012. Finnish permanent GNSS network: From dual-frequency GPS to multi-satellite GNSS. 2012 Ubiquitous Positioning, Indoor Navigation, and Location Based Service (UPINLBS), 1–5.
  • Lahtinen, S., H. Pasi, L. Jivall, C. Kempe, K. Kollo, K. Kosenko, P. Pihlak, D. Prizginiene, O. Tangen, M. Weber, et al. 2018. First results of the Nordic and Baltic GNSS analysis centre. Journal of Geodetic Science 8 (1):34–42.
  • Lavrov, D., G. Even-Tzur, and J. Reinking. 2017. Expansion and improvement of the Israeli geoid model by shipborne GNSS measurements. Journal of Surveying Engineering 143 (2):04016022.
  • Metsar, J., K. Kollo, and A. Ellmann. 2018. Modernization of the Estonian national GNSS reference station network. Geodesy and Cartography 44 (2):55–62.
  • Nordman, M., J. Kuokkanen, M. Bilker-Koivula, H. Koivula, P. Häkli, and S. Lahtinen. 2018. Geoid validation on the Baltic Sea using ship-borne GNSS data. Marine Geodesy 41 (5):457–76.
  • NovAtel. 2014. Inertial Explorer User Guide. Waypoint Products Group. https://hexagondownloads.blob.core.windows.net/public/Novatel/assets/Documents/Waypoint/Downloads/InertialExplorer860_Manual/InertialExplorer860_Manual.pdf.
  • Saari, T., and M. Bilker-Koivula. 2018. Applying the GOCE-based GGMs for the quasi-geoid modelling of Finland. Journal of Applied Geodesy 12 (1):15–27.
  • Varbla, S., A. Ellmann, S. Märdla, and A. Gruno. 2017. Assessment of marine geoid models by ship-borne GNSS profiles. Geodesy and Cartography 43 (2):41–9.
  • Varbla, S., A. Ellmann, and N. Delpeche-Ellmann. 2020. Validation of marine geoid models by utilizing hydrodynamic model and shipborne GNSS profiles. Marine Geodesy 43 (2):134–62.