Monterey Bay ambient noise profiles using underwater gliders

Chandrayadula, Tarun K.; Miller, Chris W.; Joseph, John E.

doi:10.1121/1.4805896

Cited by 3 publications

(3 citation statements)

References 3 publications

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“…Its possible noise sources, such as the air bladder, fin steering, battery movement and volume piston are described in [21]. Chandrayadula et al [11] showed that high-intensity sounds such as the sloshing of the glider at the sea surface, the bladder pump, the ballast pump, and the battery packs moving around are all broadband in nature. The bulk of the broadband noises were concentrated at the lower frequencies 0-3 kHz.…”

Section: Noise Sources Of the Underwater Glidermentioning

confidence: 99%

“…Among these platforms, underwater gliders have been actively used for measurement of environmental underwater ambient noise. The addition of a single hydrophone sensor to an underwater glider provides a capability for measurement of underwater noise level [7][8][9][10][11][12][13][14] and the addition of a hydrophone array enables surveillance of the underwater acoustic environment [15,16].…”

Section: Introductionmentioning

confidence: 99%

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Tertiary Waves Measured during 2017 Pohang Earthquake Using an Underwater Glider

Lee

Jung

et al. 2019

Applied Sciences

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An underwater glider equipped with a hydrophone observed the acoustic sounds of an earthquake that occurred on 15 November 2017 05:29:32 (UTC) in the Pohang area. The underwater glider observed the earthquake sounds after 19 s (05:29:51) at approximately 140 km from the Pohang epicenter. In order to distinguish the earthquake sound from the glider’s operation noise, the noise sources and Sound Pressure Level (SPL) of the underwater glider were analyzed and measured at laboratory tank and sea. The earthquake acoustic signal was distinguished from glider’s self-noises of fin, pumped Conductivity-Temperature-Depth profiler (CTD) and altimeter which exist over 100 Hz. The dominant frequencies of the earthquake acoustic signals due to the earthquake were 10 Hz. Frequencies at which the spectra had dropped 60 dB were 50 Hz. By analysis of time correlation with seismic waves detected by five seismic land stations and the earthquake acoustic signal, it is clearly shown that the seismic waves converted to Tertiary waves and then detected by the underwater glider. The results allow constraining the acoustic sound level of the earthquake and suggest that the glider provides an effective platform for enhancing the earth seismic observation systems and monitoring natural and anthropogenic ocean sounds.

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Section: Noise Sources Of the Underwater Glidermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tertiary Waves Measured during 2017 Pohang Earthquake Using an Underwater Glider

Lee

Jung

et al. 2019

Applied Sciences

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“…While the ROV is designed to make mobile acoustic measurements in the immediate vicinity of an MRE device, the presence of a tether can cause unwanted complications when operating in the vicinity of MRE devices consisting of several berths, connected with tendon-like cables. Additionally, given the low noise emitted by MRE devices, the presence of multiple thrusters and ballast pumps can significantly reduce the signal-to-noise ratio, a problem common in glider-based acoustic measurement platforms [7]. Furthermore, location estimation using a single pressure-only hydrophone remains a challenge, and the engineering costs involved in designing, maintaining, and deploying an ROV can be significant.…”

Section: Introductionmentioning

confidence: 99%

A Vector Sensor-Based Acoustic Characterization System for Marine Renewable Energy

Raghukumar

Chang

Spada

et al. 2020

JMSE

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NoiseSpotter is a passive acoustic monitoring system that characterizes, classifies, and geo-locates anthropogenic and natural sounds in near real time. It was developed with the primary goal of supporting the evaluation of potential acoustic effects of offshore renewable energy projects. The system consists of a compact array of three acoustic vector sensors, which measures acoustic pressure and the three-dimensional particle velocity vector associated with the propagation of an acoustic wave, thereby inherently providing bearing information to an underwater source of sound. By utilizing an array of three vector sensors, the application of beamforming techniques can provide sound source localization, allowing for characterization of the acoustic signature of specific underwater acoustic sources. Here, performance characteristics of the system are presented, using data from controlled acoustic transmissions in a quiet environment and ambient noise measurements in an energetic tidal channel in the presence of non-acoustic flow noise. Data quality is demonstrated by the ability to reduce non-acoustic flow noise contamination, while system utility is shown by the ability to characterize and localize sources of sound in the underwater environment.

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Using Petrel II Glider to Analyze Underwater Noise Spectrogram in the South China Sea

Liu

Lan

et al. 2018

Acoust Aust

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Monterey Bay ambient noise profiles using underwater gliders

Cited by 3 publications

References 3 publications

Tertiary Waves Measured during 2017 Pohang Earthquake Using an Underwater Glider

Tertiary Waves Measured during 2017 Pohang Earthquake Using an Underwater Glider

A Vector Sensor-Based Acoustic Characterization System for Marine Renewable Energy

Using Petrel II Glider to Analyze Underwater Noise Spectrogram in the South China Sea

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