Automated Model-based Localization of Marine Mammals Near Hawaii

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Automated Model-based Localization of Marine Mammals Near Hawaii

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Humpback whale calls .2-4 kHz. 2 sec duration. Sperm whale clicks. Hydrophone array. San Clemente ... Whale Tracking. Ambiguity surface peaks from consecutive ... – PowerPoint PPT presentation

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Title: Automated Model-based Localization of Marine Mammals Near Hawaii

1
Automated Model-Based Localization of Marine
Mammals
Christopher O. Tiemann Michael B. Porter Science
Applications International Corporation John A.
Hildebrand Scripps Institution of Oceanography

2
Traditional Passive Acoustic Localization Methods

Hyperbolic fixing Assumption of direct acoustic
path
and
constant soundspeed
Matched-field processing Sensitive to
environment

Advantages of Model-Based
Localization Technique
Acoustic propagation model provides accuracy
Robust against environmental and acoustic
variability
Graphical display with inherent confidence
metrics
Applicable to sparse arrays
Fast for real-time processing without user
interaction

3
Algorithm has been tested with real acoustic data
from two locations
Robust against differences in environment and
species
PMRF Deep water Humpback whale calls .2-4
kHz 2 sec duration Sperm whale
clicks Hydrophone array
San Clemente Shallow water Blue whale calls
10-20 Hz 20 sec duration Seismometer array
4
Array Geometries
Pacific Missile Range Facility Hydrophone
Positions
San Clemente Seismometer Positions
5
Spectrograms from PMRF Channels 2 and 4
3/22/01 201630
dB
Time-Lag
dB
6
San Clemente Seismometer Spectrograms
Seismometer 1 08/28/01 1136
Sensors measured 3-axis velocity plus pressure
Blue whale type A and B calls observed
4 receivers 11 days of data 128 Hz sample rate
7
Algorithm Overview
1) Predict direct and reflected acoustic
path travel times and time-lags
2) Pair-wise cross- correlation measures
time-lag
3) Compare predicted vs measured time-lags
for likelihood scores
4) Summed scores form ambiguity surface
indicating mammal position and confidence
8
Ch. 2, 3/22/01 201630
Spectrogram Correlation

Pixilate spectrograms
to binary intensity
(black white)

Ch. 4, 3/22/01 201630
2) Correlate via logical AND and
count of overlapping pixels
9
Spectral correlations provide more consistent
time-lag estimates than do waveform correlations

Time-lag between PMRF Ch. 2 4, 3/22/01 201600
Time-lag between PMRF Ch. 2 4, 3/22/01 201600
10
Phase-Only Correlation

Measures time-lag between receiver pairs
Product of two whitened spectra
Frequency-band specific
Advantages over waveform or spectrogram
correlation
Over time, see change in bearing to persistent
sources

Pair-wise Time-lag between Seismometers 1 and
4 08/28/01 08/30/01
11
Ambiguity Surface Construction
PMRF 3/22/01 2016
1) Discard low-score time-lags 2) Compare
predicted vs measured time-lags for all
candidate source positions 3) Sum
likelihood contributions from all hydrophone
pairs
12
Whale Tracking
Ambiguity surface peaks from consecutive
localizations follow movement of source
San Clemente
13
Tracking Examples

Sources can be localized far outside array
Tracks give clues to animal behavior

08/28/01 0252-0452
08/28/01 0933-1350
08/29/01 0255-0450
14
Tracking Examples
Whale movement can be followed with time-lapse
movies. Click on a figure to play.
San Clemente 08/28/01 0252 0443
San Clemente 08/28/01 0933 1350
15
Depth Estimation
Repeat modeling and surface construction for
several depths Surface peak defocuses at
incorrect depths
Sperm whale localization at PMRF 03/10/02 1153
200 m depth
800 m depth
UTM North (km)
UTM East (km)
UTM East (km)
16
Multiple Sources