Improving Nonparametric Estimates of the Sea State Bias in Radar Altimeter Measurements of Sea Level

Abstract

A fully nonparametric (NP) version of the sea state bias (SSB) estimation problem in radar altimetry was first presented and solved by Gaspar and Florens (GF) using the statistical technique of kernel smoothing. This solution requires solving a large linear system and thus comes with a significant computational burden. In addition, examination of GF SSB estimates reveals a marked bias close to the boundaries of the estimation domain. This paper presents efforts to improve both the skill and the computational efficiency of the GF SSB estimation method. Computational efficiency is rather easily improved by an appropriate kernel choice that transforms the linear system to be solved into a very sparse system for which fast solution algorithms exist. The estimation bias proves to be due to the GF choice of a rudimentary NP estimator for conditional expectations. Use of a more elaborate estimator appears to be possible after a slight adaptation of the method. This solves the bias problem. Further impro... Abstract A fully nonparametric (NP) version of the sea state bias (SSB) estimation problem in radar altimetry was first presented and solved by Gaspar and Florens (GF) using the statistical technique of kernel smoothing. This solution requires solving a large linear system and thus comes with a significant computational burden. In addition, examination of GF SSB estimates reveals a marked bias close to the boundaries of the estimation domain. This paper presents efforts to improve both the skill and the computational efficiency of the GF SSB estimation method. Computational efficiency is rather easily improved by an appropriate kernel choice that transforms the linear system to be solved into a very sparse system for which fast solution algorithms exist. The estimation bias proves to be due to the GF choice of a rudimentary NP estimator for conditional expectations. Use of a more elaborate estimator appears to be possible after a slight adaptation of the method. This solves the bias problem. Further impro...