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Accurate and Reliable Long-range Dynamic Radiolocation using GPS and DGPS—Geoloc Hybridization

Published online by Cambridge University Press:  21 October 2009

Georges Nard
Affiliation:
(Sercel)

Extract

Present and future marine navigation requirements have been analysed recently for different categories of users. This paper relates to those navigation applications which need very high real-time accuracy, high availability and reliability of navigation information. This domain is mainly influenced by marine surveying and navigation community needs such as oil and mineral prospecting, hydrography and future prospecting of maritime economic zones, which are usually of high strategic or economic importance. The majority of identified needs for this limited community of users call for real-time accuracy and repeatability of instantaneous positioning ranging from 2 to 10 m, distances from shore up to 1500 km (water depth 300–1000 m), update rate of position information of a few seconds, and availability and reliability of position information data of 99 per cent or more. To reach such stringent requirements none of the existing means and even new satellites or Earth-based acoustic or radio aids individually can solve the problem. This leads to the necessity of combination or hybridization of several means which together may approach the solution.

Type
Research Article
Copyright
Copyright © The Royal Institute of Navigation 1987

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References

REFERENCES

1RTCM. Differential GPS recommendations, statement of requirements, Report 200–85/SC 104–58, pp. A1–A19.Google Scholar
2US DoT. Federal Radionavigation Plan, DOT-TSC-RSPA-84.8, chap. 11. 3.Google Scholar
3Nard, G. (1984). Spread spectrum concept applied in new accurate medium—long range radiopositioning system. Proceedings of Oceanology International, Brighton; (1985). International Hydrographic Review, Monaco, LXII(I).Google Scholar
4CCIR. Maritime radiolocation using spread spectrum techniques in MF bands. CCIR 8/335.Google Scholar
5CCIR. Application of spread spectrum techniques to radiolocation. Discretion and radio compatibility. CCIR 1/196.Google Scholar
6Nard, G. (1984—5). Geoloc — résultats d’essais en mer (campagnes 84 et 85). Rapport Sercel RS 53–85.Google Scholar
7 Geoteam Norway (1985). GEOLOC system test on board M/V Kraknesson. Report no. 23.Google Scholar
8 Institute of Navigation (1983). Global positioning system, 0936406–00–3–1980–1983.Google Scholar
9 Service hydrographique et Océanographique de la Marine, Section Géodésie Géophysique (1986). Rapport no. 214, Résultats de lévaluation d’un récepteur GPS TR5S.Google Scholar
10Gounon, R. (1986). GPS trials on the Perthuis Dredger, RN 27–86. Sercel Report.Google Scholar
11Bonin, G. (1985). Un Récepteur francais de NAVSTAR. Navigation, special GPS number.Google Scholar
12Boucher, C. and Nard, G. (1985). Capabilities of the TR5S Sercel GPS receiver for precise positioning. First International GPS Symposium on Precise Positioning, Rockville.Google Scholar