Title :
Reduced-complexity RLS estimation for shallow-water channels
Author :
Kocic, Marko ; Brady, David ; Merriam, Steven
Author_Institution :
Dept. of Electr. & Comput. Eng., Northeastern Univ., Boston, MA, USA
Abstract :
An adjustable complexity, recursive least squares (RLS) estimation algorithm is presented, which is suitable for adaptive equalization and source localization in shallow-water acoustic channels. The algorithm adjusts its computational complexity, measured in FLOPS per update, in a decreasing fashion with the relative signal strength, by ignoring “insignificant” dimensions of the channel. The algorithm reverts to the well-known fast RLS algorithms when the signal quality is weak, and may be combined with reduced period updating techniques. Examples illustrate computational savings in excess of one order of magnitude, permitting a tripling of the maximum data rate through these complexity-limited communication channels
Keywords :
adaptive equalisers; computational complexity; least mean squares methods; recursive estimation; signal sources; telecommunication channels; telemetry; underwater sound; adaptive equalization; computational complexity; recursive least squares estimation; reduced period updating; relative signal strength; shallow-water acoustic channels; source localization; underwater acoustic telemetry; Acoustic measurements; Communication channels; Computational complexity; Decision feedback equalizers; Least squares approximation; Recursive estimation; Resonance light scattering; Sea measurements; Telemetry; Underwater acoustics;
Conference_Titel :
Autonomous Underwater Vehicle Technology, 1994. AUV '94., Proceedings of the 1994 Symposium on
Conference_Location :
Cambridge, MA
Print_ISBN :
0-7803-1808-0
DOI :
10.1109/AUV.1994.518621
