Share:


Performance analysis of Latvian zenith camera

    Ansis Zariņš Affiliation
    ; Augusts Rubans Affiliation
    ; Gunārs Silabriedis Affiliation

Abstract

Since finalizing of design in 2016, the digital zenith camera of the University of Latvia was involved in a number of test observations as well as field observations at about 70 different sites. The paper presents analysis of observation results, estimation of instrument’s performance and accuracy. Random and systematic error sources are outlined. Impact of anomalous refraction on vertical deflection determination is discussed. Results of adaptation of GAIA reference star catalog for astrometric data reduction are reported.

Keyword : digital zenith camera, geodetic astronomy, vertical deflections, geoid, anomalous refraction

How to Cite
Zariņš, A., Rubans, A., & Silabriedis, G. (2018). Performance analysis of Latvian zenith camera. Geodesy and Cartography, 44(1), 1-5. https://doi.org/10.3846/gac.2018.876
Published in Issue
Apr 30, 2018
Abstract Views
962
PDF Downloads
567
Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

References

Hirt, C. (2006). Monitoring and analysis of anomalous refraction using a digital zenith camera system. Astronomy and Astrophysics, 459, 283-290. https://doi.org/10.1051/0004-6361:20065485

Hirt, C., Bürki, B., Somieski, A., & Seeber, G. (2010). Modern determination of vertical deflections using digital zenith cameras. Journal of Surveying Engineering, 136(1), 1-12. https://doi.org/10.1061/(ASCE)SU.1943-5428.0000009

Hirt, C., & Seeber, G. (2008). Accuracy analysis of vertical deflection data observed with the Hannover digital zenith camera system TZK2-D. Journal of Geodesy, 82(6), 347-356. https://doi.org/10.1007/s00190-007-0184-7

Lindegren, L., Lammers, U., Bastian, U., Hernández, J., Klioner, S., Hobbs, D., Bombrun, A., Michalik, D., Ramos-Lerate, M., Butkevich, A., Comoretto, G., Joliet, E., Holl, B., Hutton, A., Parsons, P., Steidelmüller, H., Abbas, U., Altmann, M., Andrei, A., Anton, S., Bach, N., Barache, C., Becciani, U., Berthier, J., Bianchi, L., Biermann, M., Bouquillon, S., Bourda, G., Brüsemeister, T., Bucciarelli, B., Busonero, D., Carlucci, T., Castañeda, J., Charlot, P., Clotet, M., Crosta, M., Davidson, M., de Felice, F., Drimmel, R., Fabricius, C., Fienga, A., Figueras, F., Fraile, E., Gai, M., Garralda, N., Geyer, R., González-Vidal, J. J., Guerra, R., Hambly, N. C., Hauser, M., Jordan, S., Lattanzi, M. G., Lenhardt, H., Liao, S., Löffler, W., McMillan, P. J., Mignard, F., Mora, A., Morbidelli, R., Portell, J., Riva, A., Sarasso, M., Serraller, I., Siddiqui, H., Smart, R., Spagna, A., Stampa, U., Steele, I., Taris, F., Torra, J., van Reeven, W., Vecchiato, A., Zschocke, S., de Bruijne, J., Gracia, G., Raison, F., Lister, T., Marchant, J., Messineo, R., Soffel, M., Osorio, J., de Torres, A., O’Mullane, W. (2016). Gaia Data Release 1 – Astrometry: one billion positions, two million proper motions and parallaxes. Astronomy & Astrophysics, 595, A4. https://doi.org/10.1051/0004-6361/201628714

Zariņš, A., Rubans, A., & Silabriedis, G. (2016). Digital zenith camera of the University of Latvia. Geodesy and Cartography, 42, 129-135. https://doi.org/10.3846/20296991.2016.1268434