Feasibility of Acoustic Remote Sensing of Large Herring Shoals and Seafloor by Baleen Whales

Yi, Dong Hoon; Makris, Nicholas C.

doi:10.3390/rs8090693

Cited by 12 publications

(21 citation statements)

References 43 publications

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“…The analysis is done for shoal segments that sub-divide the herring high-density area into a number of annular sectors ( Figure 2) such that the spatial variation in the herring groups' spatial structure is investigated in an efficient manner (Section 2.4). The measured frequency response of herring scattering at each horizontal position is obtained from the instantaneous multi-spectral OAWRS scattering strength images (Section 2.2), whereas the modeled frequency response is obtained from a swimbladder resonance model [17,18] as described in Section 2.5. …”

Section: Instantaneous 3d Imaging Via Multi-spectral Resonance Sensingmentioning

confidence: 99%

“…The expected scattering strength SS model of herring in a uniformly-distributed vertical layer with mean shoal depth z 0 , shoal thickness H, neutral buoyancy depth z nb , and areal population density n A at frequency f is determined [17,18] as…”

Section: Modeled Resonant Scattering From Herring In a Uniform Verticmentioning

confidence: 99%

“…where S is the far-field scatter function [20] of a single herring, k is the acoustic wavenumber, l is the fork length of herring, g(l) is the truncated Gaussian probability density function [18] to ensure positiveness of the parameter l, and z is the herring depth. Here, the backscattering cross section of herring is determined as…”

Section: Modeled Resonant Scattering From Herring In a Uniform Verticmentioning

confidence: 99%

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Instantaneous 3D Continental-Shelf Scale Imaging of Oceanic Fish by Multi-Spectral Resonance Sensing Reveals Group Behavior during Spawning Migration

Gong

Jech

et al. 2018

Remote Sensing

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Abstract:The migration of extensive social groups towards specific spawning grounds in vast and diverse ocean environments is an integral part of the regular spawning process of many oceanic fish species. Oceanic fish in such migrations typically seek locations with environmental parameters that maximize the probability of successful spawning and egg/larval survival. The 3D spatio-temporal dynamics of these behavioral processes are largely unknown due to technical difficulties in sensing the ocean environment over wide areas. Here, we use ocean acoustic waveguide remote sensing (OAWRS) to instantaneously image immense herring groups over continental-shelf-scale areas at the Georges Bank spawning ground. Via multi-spectral OAWRS measurements, we capture a shift in swimbladder resonance peak correlated with the herring groups' up-slope spawning migration, enabling 3D spatial behavioral dynamics to be instantaneously inferred over thousands of square kilometers. We show that herring groups maintain near-bottom vertical distributions with negative buoyancy throughout the migration. We find a spatial correlation greater than 0.9 between the average herring group depth and corresponding seafloor depth for migratory paths along the bathymetric gradient. This is consistent with herring groups maintaining near-seafloor paths to both search for optimal spawning conditions and reduce the risk of predator attacks during the migration to shallower waters where near-surface predators are more dangerous. This analysis shows that multi-spectral resonance sensing with OAWRS can be used as an effective tool to instantaneously image and continuously monitor the behavioral dynamics of swimbladder-bearing fish group behavior in three spatial dimensions over continental-shelf scales.

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Section: Instantaneous 3d Imaging Via Multi-spectral Resonance Sensingmentioning

confidence: 99%

Section: Modeled Resonant Scattering From Herring In a Uniform Verticmentioning

confidence: 99%

Section: Modeled Resonant Scattering From Herring In a Uniform Verticmentioning

confidence: 99%

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Instantaneous 3D Continental-Shelf Scale Imaging of Oceanic Fish by Multi-Spectral Resonance Sensing Reveals Group Behavior during Spawning Migration

Gong

Jech

et al. 2018

Remote Sensing

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“…Baleen whales are not known to produce sounds for echolocation or navigation, which is a capability in toothed whales. Some studies have suggested a potential for echolocation [25,83] or navigation [25,84] in some select baleen whale species, but is highly dependent on vocalization type [83], environmental and prey conditions [25], and they do not consider pulse compression gains since this ability is not known to be present in baleen whales. Here, the pulse compression gains are quantified for passive acoustic marine mammal sensing systems that use pulse compressions to enhance whale vocalization signal detection or bearing-time estimation for whale localization.…”

Section: Discussionmentioning

confidence: 99%

“…The whale locations for each species were previously determined using the moving array triangulation [2,22,23], the bearings-migration minimum mean square error and the array invariant techniques [2,[22][23][24] from the measured bearing versus time trajectories of sequences of vocalizations from that species [1]. The marine mammal species-dependent vocalization source level is an important parameter for estimating the marine mammal detection region for a given species in any passive underwater acoustic sensing system [1,2,25]. It is also employed in distance sampling estimates of marine mammal call density and abundance estimation [26][27][28][29][30].…”

Section: Introductionmentioning

confidence: 99%

Vocalization Source Level Distributions and Pulse Compression Gains of Diverse Baleen Whale Species in the Gulf of Maine

et al. 2016

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Abstract:The vocalization source level distributions and pulse compression gains are estimated for four distinct baleen whale species in the Gulf of Maine: fin, sei, minke and an unidentified baleen whale species. The vocalizations were received on a large-aperture densely-sampled coherent hydrophone array system useful for monitoring marine mammals over instantaneous wide areas via the passive ocean acoustic waveguide remote sensing technique. For each baleen whale species, between 125 and over 1400 measured vocalizations with significantly high Signal-to-Noise Ratios (SNR > 10 dB) after coherent beamforming and localized with high accuracies (<10% localization errors) over ranges spanning roughly 1 km-30 km are included in the analysis. The whale vocalization received pressure levels are corrected for broadband transmission losses modeled using a calibrated parabolic equation-based acoustic propagation model for a random range-dependent ocean waveguide. The whale vocalization source level distributions are characterized by the following means and standard deviations, in units of dB re 1 µPa at 1 m: 181.9 ± 5.2 for fin whale 20-Hz pulses, 173.5 ± 3.2 for sei whale downsweep chirps, 177.7 ± 5.4 for minke whale pulse trains and 169.6 ± 3.5 for the unidentified baleen whale species downsweep calls. The broadband vocalization equivalent pulse-compression gains are found to be 2.5 ± 1.1 for fin whale 20-Hz pulses, 24 ± 10 for the unidentified baleen whale species downsweep calls and 69 ± 23 for sei whale downsweep chirps. These pulse compression gains are found to be roughly proportional to the inter-pulse intervals of the vocalizations, which are 11 ± 5 s for fin whale 20-Hz pulses, 29 ± 18 for the unidentified baleen whale species downsweep calls and 52 ± 33 for sei whale downsweep chirps. The source level distributions and pulse compression gains are essential for determining signal-to-noise ratios and hence detection regions for baleen whale vocalizations received passively on underwater acoustic sensing systems, as well as for assessing communication ranges in baleen whales.

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Humpback whale (Megaptera novaeangliae) sonar: Ten predictions.

Mercado

2020

Journal of Comparative Psychology

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Bats and dolphins echolocate ultrasonically while foraging, an active mode of perception that is effective for intercepting small, fast-moving targets, but less so for tracking large targets from long distances. Unlike toothed whales, humpback whales and other baleen whales are widely assumed not to echolocate. Echoes generated by humpback whale vocalizations often have been viewed either as low-level background noise that minimally affects acoustic communication between whales or as indirect cues to large environmental features. An additional possibility is that vocalizing humpback whales (and perhaps other whales) produce sonic sounds to actively generate echoes that they localize and interpret. Animals attempting to echolocate using lower frequency sounds underwater face some of the same signal processing challenges faced by ultrasonic echolocators, as well as some unique challenges. The extent to which listening whales can meet these challenges largely determines what they can actively perceive by monitoring self-generated echoes. In the absence of psychophysical experiments with baleen whales, comparisons with auditory processing by echolocating species provide the best indications of what humpback whales may echoically perceive. Empirical tests of key predictions derived from the hypothesis that humpback whales echolocate are also critical to understanding how they use sound. Recognizing that sonic echolocation by whales may differ substantially from ultrasonic echolocation in smaller species is an important step toward clarifying the role that active auditory perception plays in whale behavior.

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Feasibility of Acoustic Remote Sensing of Large Herring Shoals and Seafloor by Baleen Whales

Cited by 12 publications

References 43 publications

Instantaneous 3D Continental-Shelf Scale Imaging of Oceanic Fish by Multi-Spectral Resonance Sensing Reveals Group Behavior during Spawning Migration

Instantaneous 3D Continental-Shelf Scale Imaging of Oceanic Fish by Multi-Spectral Resonance Sensing Reveals Group Behavior during Spawning Migration

Vocalization Source Level Distributions and Pulse Compression Gains of Diverse Baleen Whale Species in the Gulf of Maine

Humpback whale (Megaptera novaeangliae) sonar: Ten predictions.

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