SATELLITE ALTIMETRY FROM A SHORT-ARC ORBIT TECHNIQUE: APPLICATION TO THE MEDITERRANEAN

P. BONNEFOND , P. EXERTIER, P. SCHAEFFER, S. BRUINSMA AND F. BARLIER

Observatoire de la Côte d'Azur, CERGA/GRGS, Grasse, France

---

Abstract. A short-arc orbit technique was developed and a very precise and efficient tool for regional orbit determination with a rigorous error budget is proposed for analysing the TOPEX/Poseidon (T/P) and ERS-1 missions. The purpose is to be able to determine very accurately on some conditions the local orbit with a very small error in the radial direction, using Satellite Laser Ranging (SLR data). A precision at the level of 2 cm is obtained. With this, it was possible to cross validate all the different orbit determination techniques as well as the results of the altimeter calibration, showing the great progress made with the TOPEX/Poseidon mission. After that, the T/P mean sea profiles were computed and improved with high accuracy thanks also to the short-arc orbit technique. As a result, a combined mean sea surface using TOPEX/Poseidon and ERS-1 data has been computed with crossover differences techniques, the T/P mean sea profiles serving as reference. Fine structures of the mean sea surface have been evidenced. Using this combined mean sea surface, the ERS-1 altimeter calibration was performed, over the Mediterranean, again using the short-arc orbit technique. The result is in good agreement with the previous ones (-41.6 cm ± 7 cm). Finally, the T/P mean sea profiles were computed for different seasons and compared to a yearly averaged mean sea surface. Variations of about 15 cm are evidenced associated notably to the thermal expansion between fall and winter. The short-arc orbit technique appears to be very well suited to monitor very accurately the temporal variability of the Mediterranean sea at a sub-centimetric level.