Maximum likelihood estimation of geodesic subspace trajectories using approximate methods and stochastic optimization

Author

Lake, Douglas E. ; Keenan, Daniel M.

Author_Institution

Army Res. Lab., AMSRL-SE-SA, Adelphi, MD, USA

fYear

1998

fDate

14-16 Sep 1998

Firstpage

148

Lastpage

151

Abstract

Signal subspace methods are widely used in array processing and other applications. Traditionally, these methods require that the subspace is stationary (i.e., fixed) over the time window being analyzed. For many applications, the subspace is significantly time-varying because of, for example, the dynamics of the array and/or target motion. Recently, a geometric-based model of subspace trajectories based on geodesics on the Grassmann manifold has been developed for these nonstationary cases. Some approximate methods for the maximum likelihood estimation of geodesic subspace trajectories are presented as part of a global stochastic optimization approach. These methods are demonstrated on real USA Army battlefield acoustic sensor data with some promising preliminary results

Keywords

acoustic signal detection; approximation theory; array signal processing; differential geometry; maximum likelihood estimation; military computing; optimisation; time-varying systems; Grassmann manifold; approximate methods; array processing; battlefield acoustic sensor data; geodesic subspace trajectories; geometric-based model; maximum likelihood estimation; signal subspace methods; stochastic optimization; time-varying subspace; Acoustic sensors; Frequency estimation; Lakes; Matrix decomposition; Maximum likelihood estimation; Optimization methods; Parametric statistics; Sensor arrays; Solid modeling; Stochastic processes;

fLanguage

English

Publisher

ieee

Conference_Titel

Statistical Signal and Array Processing, 1998. Proceedings., Ninth IEEE SP Workshop on

Conference_Location

Portland, OR

Print_ISBN

0-7803-5010-3

Type

conf

DOI

10.1109/SSAP.1998.739356

Filename

739356