Image_1_The Next Wave of Passive Acoustic Data Management: How Centralized Access Can Enhance Science.JPEG

Passive acoustic data collection has grown exponentially over the past decade resulting in petabytes of data that document our ocean soundscapes. This effort has resulted in two big data challenges: (1) the curation, management, and global dissemination of passive acoustic datasets and (2) efficient...

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Main Authors: Carrie C. Wall (10316129), Samara M. Haver (7176887), Leila T. Hatch (7176899), Jennifer Miksis-Olds (760728), Rob Bochenek (11131005), Robert P. Dziak (7176893), Jason Gedamke (445301)
Format: Still Image
Language:unknown
Published: 2021
Subjects:
Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
passive acoustic monitoring
soundscape
marine mammal
anthropogenic noise
data management
open access
Arctic
Pacific
Northwest Atlantic
Online Access:https://doi.org/10.3389/fmars.2021.703682.s001
id ftsmithonian:oai:figshare.com:article/14979402
record_format openpolar
spelling ftsmithonian:oai:figshare.com:article/14979402 2023-05-15T15:18:52+02:00 Image_1_The Next Wave of Passive Acoustic Data Management: How Centralized Access Can Enhance Science.JPEG Carrie C. Wall (10316129) Samara M. Haver (7176887) Leila T. Hatch (7176899) Jennifer Miksis-Olds (760728) Rob Bochenek (11131005) Robert P. Dziak (7176893) Jason Gedamke (445301) 2021-07-14T05:48:55Z https://doi.org/10.3389/fmars.2021.703682.s001 unknown https://figshare.com/articles/figure/Image_1_The_Next_Wave_of_Passive_Acoustic_Data_Management_How_Centralized_Access_Can_Enhance_Science_JPEG/14979402 doi:10.3389/fmars.2021.703682.s001 CC BY 4.0 CC-BY Oceanography Marine Biology Marine Geoscience Biological Oceanography Chemical Oceanography Physical Oceanography Marine Engineering passive acoustic monitoring soundscape marine mammal anthropogenic noise data management open access Image Figure 2021 ftsmithonian https://doi.org/10.3389/fmars.2021.703682.s001 2021-07-25T17:07:53Z Passive acoustic data collection has grown exponentially over the past decade resulting in petabytes of data that document our ocean soundscapes. This effort has resulted in two big data challenges: (1) the curation, management, and global dissemination of passive acoustic datasets and (2) efficiently extracting critical information and comparing it to other datasets in the context of ecosystem-based research and management. To address the former, the NOAA National Centers for Environmental Information recently established an archive for passive acoustic data. This fast-growing archive currently contains over 100 TB of passive acoustic audio files mainly collected from stationary recorders throughout waters in the United States. These datasets are documented with standards-based metadata and are freely available to the public. To begin to address the latter, through standardized processing and centralized stewardship and access, we provide a previously unattainable comparison of first order sound level-patterns from archived data collected across three distinctly separate long-term passive acoustic monitoring (PAM) efforts conducted at regional and national scales: NOAA/National Park Service Ocean Noise Reference Station Network, the Atlantic Deepwater Ecosystem Observatory Network, and the Sanctuary Soundscape Monitoring Project. Nine sites were selected from these projects covering the Alaskan Arctic, Northeast and Central Pacific, Gulf of Mexico, Caribbean Sea, and Mid and Northwest Atlantic. Sites could generally be categorized into those strongly influenced by anthropogenic noise (e.g., vessel traffic) and those that were not. Higher sound levels, specifically for lower frequencies (<125 Hz), and proximity to densely populated coastal zones were common characteristics of sites influenced by anthropogenic noise. Conversely, sites with lower overall sound levels and away from dense populations resulted in soundscape patterns influenced by biological sources. Seasonal variability in sound levels across selected decidecade bands was apparent for most sites and often represented changes in the presence or behavior of sound-producing species. This first order examination of levels across projects highlights the utility of these initial metrics to identify patterns that can then be examined in more detail. Finally, to help the PAM community collectively and collaboratively move forward, we propose the next frontier for scalable data stewardship, access, and processing flow. Still Image Arctic Northwest Atlantic Unknown Arctic Pacific
institution Open Polar
collection Unknown
op_collection_id ftsmithonian
language unknown
topic Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
passive acoustic monitoring
soundscape
marine mammal
anthropogenic noise
data management
open access
spellingShingle Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
passive acoustic monitoring
soundscape
marine mammal
anthropogenic noise
data management
open access
Carrie C. Wall (10316129)
Samara M. Haver (7176887)
Leila T. Hatch (7176899)
Jennifer Miksis-Olds (760728)
Rob Bochenek (11131005)
Robert P. Dziak (7176893)
Jason Gedamke (445301)
Image_1_The Next Wave of Passive Acoustic Data Management: How Centralized Access Can Enhance Science.JPEG
topic_facet Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
passive acoustic monitoring
soundscape
marine mammal
anthropogenic noise
data management
open access
description Passive acoustic data collection has grown exponentially over the past decade resulting in petabytes of data that document our ocean soundscapes. This effort has resulted in two big data challenges: (1) the curation, management, and global dissemination of passive acoustic datasets and (2) efficiently extracting critical information and comparing it to other datasets in the context of ecosystem-based research and management. To address the former, the NOAA National Centers for Environmental Information recently established an archive for passive acoustic data. This fast-growing archive currently contains over 100 TB of passive acoustic audio files mainly collected from stationary recorders throughout waters in the United States. These datasets are documented with standards-based metadata and are freely available to the public. To begin to address the latter, through standardized processing and centralized stewardship and access, we provide a previously unattainable comparison of first order sound level-patterns from archived data collected across three distinctly separate long-term passive acoustic monitoring (PAM) efforts conducted at regional and national scales: NOAA/National Park Service Ocean Noise Reference Station Network, the Atlantic Deepwater Ecosystem Observatory Network, and the Sanctuary Soundscape Monitoring Project. Nine sites were selected from these projects covering the Alaskan Arctic, Northeast and Central Pacific, Gulf of Mexico, Caribbean Sea, and Mid and Northwest Atlantic. Sites could generally be categorized into those strongly influenced by anthropogenic noise (e.g., vessel traffic) and those that were not. Higher sound levels, specifically for lower frequencies (<125 Hz), and proximity to densely populated coastal zones were common characteristics of sites influenced by anthropogenic noise. Conversely, sites with lower overall sound levels and away from dense populations resulted in soundscape patterns influenced by biological sources. Seasonal variability in sound levels across selected decidecade bands was apparent for most sites and often represented changes in the presence or behavior of sound-producing species. This first order examination of levels across projects highlights the utility of these initial metrics to identify patterns that can then be examined in more detail. Finally, to help the PAM community collectively and collaboratively move forward, we propose the next frontier for scalable data stewardship, access, and processing flow.
format Still Image
author Carrie C. Wall (10316129)
Samara M. Haver (7176887)
Leila T. Hatch (7176899)
Jennifer Miksis-Olds (760728)
Rob Bochenek (11131005)
Robert P. Dziak (7176893)
Jason Gedamke (445301)
author_facet Carrie C. Wall (10316129)
Samara M. Haver (7176887)
Leila T. Hatch (7176899)
Jennifer Miksis-Olds (760728)
Rob Bochenek (11131005)
Robert P. Dziak (7176893)
Jason Gedamke (445301)
author_sort Carrie C. Wall (10316129)
title Image_1_The Next Wave of Passive Acoustic Data Management: How Centralized Access Can Enhance Science.JPEG
title_short Image_1_The Next Wave of Passive Acoustic Data Management: How Centralized Access Can Enhance Science.JPEG
title_full Image_1_The Next Wave of Passive Acoustic Data Management: How Centralized Access Can Enhance Science.JPEG
title_fullStr Image_1_The Next Wave of Passive Acoustic Data Management: How Centralized Access Can Enhance Science.JPEG
title_full_unstemmed Image_1_The Next Wave of Passive Acoustic Data Management: How Centralized Access Can Enhance Science.JPEG
title_sort image_1_the next wave of passive acoustic data management: how centralized access can enhance science.jpeg
publishDate 2021
url https://doi.org/10.3389/fmars.2021.703682.s001
geographic Arctic
Pacific
geographic_facet Arctic
Pacific
genre Arctic
Northwest Atlantic
genre_facet Arctic
Northwest Atlantic
op_relation https://figshare.com/articles/figure/Image_1_The_Next_Wave_of_Passive_Acoustic_Data_Management_How_Centralized_Access_Can_Enhance_Science_JPEG/14979402
doi:10.3389/fmars.2021.703682.s001
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/fmars.2021.703682.s001
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