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Tellus A: Dynamic Meteorology and Oceanography Volume 59, 2007 - Issue 5
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Original Articles

Water vapour tomography using GPS phase observations: Results from the ESCOMPTE experiment

T. NilssonDepartment of Radio and Space Science, Chalmers University of Technology, Onsala Space Observatory,Onsala, SwedenCorrespondence[email protected]
&
G. ElgeredDepartment of Radio and Space Science, Chalmers University of Technology, Onsala Space Observatory,Onsala, Sweden
Pages 674-682 | Received 21 Nov 2006, Accepted 22 Feb 2007, Published online: 15 Dec 2016

References

  • Atmospheric Research. 2005. Special issue on the ESCOMPTE field experiment. 74.
  • Beutler, G., Rothacher, M., Schaer, S., Springer, T. A., Kouba, J. and co-authors. 1999. The International GPS Service (IGS): An interdis-ciplinary service in support of Earth sciences.Adv. Space Res, 23, 631-635.
  • Bevis, M., Businger, S., Herring, T. A., Rocken, C., Anthes, R. A. and co-authors. 1992. GPS meteorology: remote sensing of atmospheric water vapour using the global positioning system.J. Geophys. Res. 97(D14), 15 787–15 801.
  • Bock, O., Doerflinger, E., Masson, F., Walpersdorf, A., Van-Baelen, J. and co-authors. 2004. GPS water vapour project associated to the ESCOMPTE programme: description and first results of the field experiment. Phy. Chem. Earth 29, 149-157.
  • Brown, R. G. and Hwang, P. Y. C. 1997.Introduction to Random Signals and Applied Kalman Filtering. John Wiley & Sons, 3rd edition.
  • Champollion, C., Mason, F., Bouin, M.-N., Walpersdorf, A., Doerflinger, E. and co-authors. 2005. GPS water vapour tomography: preliminary results from the ESCOMPTE field experiment. Atmospheric Research, 74, 253-274.
  • Cros, B., Durand, P., Cachier, H., Drobinslci, Ph., Frejafon, E. and co-authors. 2004. The ESCOMPTE program: an overview. Atmospheric Research, 69, 241-279.
  • Elósegui, P. and Davis, J. 2003. Accuracy assessment of GPS slant-path determinations. InProc. International Workshop on GPS Meteorology, Tsukuba, Japan. URL http://dbx.cr.chibau.jp/Gps_Met/gpsmet/index.html.
  • Emardson, T. R., Elgered, G. and Johansson, J. M. 1998. Three months of continuous monitoring of atmospheric water vapour with a network of Global Positioning System receivers. J. Geophys. Res. 103(D2), 1807–1820.
  • Flores, A., de Arellano, J. V.-G., Gradinarsky, L. P. and Rius, A. 2001. Tomography of the lower troposphere using a small dense network of GPS receivers. IEEE Trans. Geosci. Remote Sensing 39, 439–447.
  • Gradinarsky, L. and Jarlemark, P. 2004. Ground-based GPS tomography of water vapour: Analysis of simulated and real data. J. MeteoroL Soc. Japan 82, 551–560.
  • Hofmann-Wellenhof, B., Lichtenegger, H. and Collins, J. 2001. GPS: Theory and Practice. Springer-Verlag, 5th edition.
  • King, R. W. 2002. Documentation for the GAMUT GPS analysis software. Technical report, MIT. URL http://www-gpsg.mitedu/simon/gtgk/GAMIT.pdf.
  • Lutz, S., Troller, M., Somieslci, A., Walpersdorf, A., Doerflinger, E. and co-authors. 2004. GPS tomography and remote sensing techniques for water vapor determination in the ESCOMPTE campaign. In Proceedings of the IGS Workshop & Symposium, Berne, Switzerland. URL http://igscb.jpInasa.gov/.
  • Miloshevich, L. M., Viimel, H., Whiteman, D. N., Lesht, B. M., Schmidlin, F. J. and co-authors. 2006. Absolute accuracy of water vapour measurements from six operational radiosonde types launched during AWEX-G and implications for AIRS validation. J. Geophys. Res. 111, D09510.
  • Nilsson, T. 2005. Assessment of tomographic methods for estimation of atmospheric water vpor using ground-based GPS. Technical Report 6L, Dept. Radio Space Sci., Chalmers Univ. Tech. Goteborg, Sweden.
  • Nilsson, T. and Gradinarsky, L. 2006. Water vapour tomography using GPS phase observations: Simulaton results. IEEE Trans. Geosci. Remote Sensing 6 (14), 2927–2941.
  • Nilsson, T., Gradinarsky, L. and Elgered, G. 2005. Estimating the 3-D structure of the atmospheric water vapor using GPS phase observations. In Proceedings of RadioVetenskap och Kommunikation, RVK 2005, 521-526, Linkoping, Sweden. URL http://www.es. isy.liu. se/rvk05/_fina1/00085UyliigccqA_PxHNvocCC.pdf.
  • Rocken, C., Hove, T. Van, Johnson, J., Solheim, F., Ware, R., Bevis, M. and co-authors. 1995. GPS/STORM - GPS sensing of atmospheric water vapor for meteorology. J. Atmos. Oceanic TechnoL 12, 468-478.
  • Shoji, Y., Nakamura, H., Iwabuchi, T., Aonashi, K., Seko, H. and co-authors. 2004. Tsukuba GPS dense net campaign observations: improving in GPS analysis of slant path delay by stacking one-way postfit residuals. J. MeteoroL Soc. Jpn. 82(1B), 301-314.
  • Tregoning, P., Boers, R., O’Brien, D. and Hendy, M. 1998. Accuracy of absolute precipitable water vapour estimates from GPS observations. J. Geophys. Res. 103, 28 701-28 710.
  • Treuhaft, R. N. and Lanyi, G. E. 1987. The effect of the dynamic wet troposphere on radio interferometric measurements. Radio Sc i. 22, 251–265.
  • Troller, M., Biirki, B., Cocard, M., Geiger, A. and Kahle, H.-G. 2002. 3-D refractivity field from GPS double difference tomography. Geophys. Res. Lett. 29, 2149.
  • Walpersdorf, A., Bock, O., Doerflinger, E., Masson, F., van Baelen, J. and co-authors. 2004. Data analysis of a dense GPS network operated during the escompte campaign: first results. Phys. Chem. Earth 29 (2-3), 201-211.
  • Wang, J., Cole, H. L., Carlson, D. J., Miller, E. R., Beierle, K. and co-authors. 2002. Corrections of humidity measurement errors from the Vaisala RS-80 radiosonde — Application to TOGA-COARE data. J. Atmos. Oceanic TechnoL 19, 981-1002.
  • Wang, Z., Wu, Y., Zhang, K. and Meng, Y. 2005. Triple-frequency method for high-order ionospheric refractive error modelling in GPS modernization. Journal of Global Positioning Systems 4, 291–295.
  • Webb, F. H. and Zumberge, J. E 1993. An introduction to the GIPSY/OASIS-II. JPL Publ. D-11088, Jet Propul. Lab., Pasadena, California.
  • Zumberge, J. F., Heflin, M. B., Jefferson, D. C., Watkins, M. M. and Webb, F. H. 1997. Precise point positioning for the efficient and robust analysis of GPS data from large networks. J. Geophys. Res. 102(B3), 5005–5017.

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