Title :
Single hydrophone source localization
Author :
Jesus, Sérgio M. ; Porter, Michael B. ; Stéphan, Yann ; Démoulin, Xavier ; Rodriguez, Olga C. ; Coelho, Emanuel M M Ferreira
Author_Institution :
Univ. do Algarve, Faro, Portugal
fDate :
7/1/2000 12:00:00 AM
Abstract :
The method presented in this paper assumes that the received signal is a linear combination of delayed and attenuated uncorrelated replicas of the source emitted waveform. The set of delays and attenuations, together with the channel environmental conditions, provide sufficient information for determining the source location. If the transmission channel is assumed known, the source location can be estimated by matching the data with the acoustic field predicted by the model conditioned on the estimated delay set. This paper presents alternative techniques that do not directly attempt to estimate time delays from the data but, instead, estimate the subspace spanned by the delayed source signal paths. Source Localization is then done using a family of measures of the distance between that subspace and the subspace spanned by the replicas provided by the model. Results obtained on the INTIMATE´96 data set, in a shallow-water acoustic channel off the coast of Portugal, show that a sound source emitting a 300-800-Hz LFM sweep could effectively be localized in range or depth over an entire day.
Keywords :
acoustic field; acoustic signal processing; delay estimation; hydrophones; 300 to 800 Hz; 300-800-Hz LFM sweep; INTIMATE´96 data set; Portugal; acoustic field; attenuations; data analysis; delays; hydrophone; matching; random amplitudes; simulation; sound source; source emitted waveform; source localization; subspace; uncorrelated replicas; Acoustic emission; Acoustic measurements; Attenuation; Delay effects; Delay estimation; Delay lines; Position measurement; Predictive models; Propagation delay; Sonar equipment;
Journal_Title :
Oceanic Engineering, IEEE Journal of
