Listening to the Sound: Ambient Noise in Admiralty Inlet

Slides:

Advertisements

Similar presentations

NNMREC Estimating the Acoustic Impact of a Tidal Energy Project Chris Bassett, Jim Thomson, and Brian Polagye University of Washington Mechanical Engineering.

Advertisements

Implications of Tidal Phasing for Power Generation at a Tidal Energy Site Brian Polagye and Jim Thomson Northwest National Marine Renewable Energy Center.

Contact: Merin Broudic Spatial variation of sediment/cobble motion noise Figure 1 highlights the background noise.

NNMREC National Marine Renewable Energy Centers Hawaii National Marine Renewable Energy Center (HINMREC) University of Hawaii Wave, OTEC Southeast National.

NNMREC Behavioral Response of Harbor Porpoises to Vessel Noise in a Tidal Strait Ambient Noise and Marine Mammals May 23, 2011 Brian Polagye 1, Jason Wood.

Differences measuring levels Root mean square (RMS) –For long (continuous) signals –Average power delivered Peak-to-peak (pp) –Extremely short signals.

Passive Aquatic Listener: A state-of-art system employed in Atmospheric, Oceanic and Biological Sciences in the Marine Environment Prof. E. N. Anagnostou,

Val Veirs Colorado College Colorado Springs, CO, Scott Veirs Beam Reach marine science and sustainability school Seattle, WA,

Model-based Estimation of Noise Impact Zones for Deep Offshore Seismic Surveys Alexander MacGillivray, Marie-Noël R. Matthews JASCO Applied Sciences,

Monitoring Processes at Sea using Underwater Sound Jeffrey Nystuen Marie Curie International Fellow Hellenic Center for Marine Research and Principal Oceanographer.

NNMREC November 5, 2010 Northwest National Marine Renewable Energy Center Standards and Protocols for Environmental Assessment Renewable Ocean Energy and.

Passive Aquatic Listener: A state-of-art system employed in Atmospheric, Oceanic and Biological Sciences 1 M. N. Anagnostou, J. A. Nystuen 2, E. N. Anagnostou.

SEAT Traverse The Satellite Era Accumulation Traverse (SEAT) collected near-surface firn cores and Ultra High Frequency (UHF) Frequency Modulated.

NNMREC Summary for Congressman Dave Reichart April 22, 2011 Northwest National Marine Renewable Energy Center University of Washington

NNMREC Passive Acoustic Monitoring for Tidal Energy Projects Brian Polagye, Chris Bassett, and Jim Thomson University of Washington Northwest National.

Nov 4, Detection, Classification and Tracking of Targets in Distributed Sensor Networks Presented by: Prabal Dutta Dan Li, Kerry Wong,

Defence Research and Development Canada Recherche et développement pour la défense Canada Canada The impact of noise on passive monitoring of marine mammals.

The Soundscape of a Nearshore Reef near an Urban Center Whitlow W. L. Au, Michael Richlen, Marc Lammers Marine Mammal Research Program Hawaii Institute.

Northwest National Marine Renewable Energy Center Site Characterization of Tidal Resources: Admiralty Inlet Jeff Epler.

Long-Term Ambient Noise Statistics in the Gulf of Mexico Mark A. Snyder & Peter A. Orlin Naval Oceanographic Office Stennis Space Center, MS Anthony I.

Sounds in the sea. Snapping shrimp Major source of biological noise in shallow temperate and tropical waters 20 dB above the noise level typical of sea.

NNMREC November 4, 2010 Passive Acoustics New Environmental Technologies Renewable Ocean Energy and the Marine Environment Brian Polagye, Chris Bassett,

ORE 654 Applications of Ocean Acoustics Lecture 6a Signal processing

NNMREC April 20, 2011 Ambient Noise in Admiralty Inlet Chris Bassett, Brian Polagye, and Jim Thomson University of Washington Northwest National Marine.

Monitoring underwater sound at the Seattle Aquarium Research proposal discussion Wednesday, July 19, 2006 Scott Veirs | | (206)

Instrument characterization discussion

1 | Program Name or Ancillary Texteere.energy.gov Water Power Peer Review Acoustic Effects of Hydrokinetic Tidal Turbines Dr. Brian Polagye University.

Northwest National Marine Renewable Energy Center In-stream Tidal Energy: NW National Marine Renewable Energy Center University of Washington

Review of Ground Motion Measurement Program of DESY in Various Sites R. Amirikas, A. Bertolini, W. Bialowons LHC tunnel, CERN HERA tunnel, DESY Ground.

Major Sources of Noise Sea State – Dominant factor above 500 Hz

S. Viola VLVνT 2015, Rome – 14/09/2015 Characterization and testing of the KM3NeT acoustic positioning system F. Simeone VLVνT 2015 – Rome, 14/09/2015.

Kilo Nalu Nearshore Reef Observatory Acoustic Monitoring The Soundscape of a Nearshore Reef near an Urban Center Whitlow W. L. Au Marine Mammal Research.

Energy Postgraduate Conference 2013 Resource Assessment of the Agulhas Current to determine Feasibility for Marine Energy Extraction Centre for Renewable.

OS 72B-0355 Analysis of Acoustic Signals from Ship Traffic at Pioneer Seamount Carl O. Vuosalo, 1 Craig Huber, 1 Michael D. Hoffman, 1 Newell Garfield,

Underwater Vessel Noise in the Haro Strait Lindsay H. Robinson University of Puget Sound Intern with Beam Reach Marine Science and Sustainability School.

Georges Bank Gulf of Maine SBNMS Acoustic Research in the Stellwagen Bank NMS D. Wiley & L. Hatch Stellwagen Bank National Marine Sanctuary 175 Edward.

Presented at Environmental Finance Workshop Series University of Toronto October 12, 2005 DEALING WITH UNCERTAINTY: Wind Resource Assessment D. C. McKay.

Sediment Properties and the Acoustic Field in a Three-layer Waveguide David Barclay AOS seminar June 1st, 2006.

Universitat Politècnica de Catalunya Michel André MEUST: Real-time Monitoring of Noise and Acoustic Events in Cetacean Acoustic Niches.

RESOURCE ASSESSMENT AT TURBINE TEST SITE (SEA SCHELDE) TIDAL TURBINE PERFORMANCE ESTIMATION TURBULENT PROPERTIES OF THE FLOW RELATIONSHIP WITH POWER PRODUCTION.

Val Veirs Colorado College Colorado Springs, CO Source Levels of Orca (Orcinus Orca) Social Vocalizations Measured with a Shore-Based Hydrophone Array.

NEMO-O DE NEMO First results from the NEMO Test Site G. Riccobene, for the NEMO Collaboration The NEMO Collaboration is performing the Phase 1 of the project,

Evaluation of SVP-BW drifters thanks to deployments near moored buoys DBCP-18 workshop - Martinique October 2002 By Pierre Blouch Presentation :

Northwest National Marine Renewable Energy Center A 3D Hydrodynamic model of inland marine waters of Washington State, United States, for tidal resource.

Properties of the non-propulsive ship noise field as measured from a research vessel moored in the Yellow Sea and relation to sea bed parameters Peter.

Status and First Results of the Acoustic Detection System AMADEUS in ANTARES Robert Lahmann for the ANTARES Collaboration ARENA 08, Rome, 26-June-2008.

Measuring Boat Wakes in Sydney Harbour Using Sentinel V ADCP ADCPs In Action in Australia 2015 Alex Le Royer.

Investigating the Effect of Large Vessel Noise on Southern Resident Killer Whales Hilary B. Rollins UC Davis Beam Reach Marine Science and Sustainability.

ARENA08 Roma June 2008 Francesco Simeone (Francesco Simeone INFN Roma) Beam-forming and matched filter techniques.

output power and turbulence in a tidal estuary

Correlation between underwater noise level and AIS data in the Gulf of Catania (Sicily) Sara Pulvirenti Erice International School.

Brian Polagye & Paul Murphy Keith Bethune, Patrick Cross, & Luis Vega

Robert Lahmann VLVnT – Toulon – 24-April-2008

Sound Source Verification

Acoustics in water: synergies with marine biology

EFC Media Center Training

VWPT EA211 MOBILE ENGINE NVH TEST REPORT

Introduction of energy, including underwater noise, is at levels that do not adversely affect the marine environment Mark Tasker for TG11.

Robert Lahmann for the ANTARES Collaboration

OS 72B-0355 Analysis of Acoustic Signals from Ship Traffic at Pioneer Seamount Carl O. Vuosalo,1 Craig Huber,1 Michael D. Hoffman,1 Newell Garfield,2 and.

LCDR John Hendrickson 17SEP2008

Combination of oceanographic data with wind data acquired during the cruise to try to draw conclusions on wind stress, Ekman transport and Ekman layer.

Characterization of Sound Speed Profiles

Operational Oceanography and Meteorology

Comparison of CTD/XBT Temperature Profiles and XBT/GDEM Sound Speed Profiles LT Annie Laird 08 March 2006.

EL NINO EFFECTS ON SOUND SPEED IN THE SOUTH CHINA SEA BASIN

University of Washington, Mechanical Engineering

Tidal Hydrokinetic Energy WW-ASME Dinner Meeting

Acoustics of the Puget Sound

Comparison of Wind Speed and Wind Stress to Ocean Ambient Sound

Presentation transcript:

Listening to the Sound: Ambient Noise in Admiralty Inlet

Motivation Study ambient noise and identify sources Results used by regulators in permitting process

Site Admiralty Inlet b/w Port Townsend and Whidbey Island

Data Collection Temporal Data Spatial Data -Three month sea spider deployments - Samples at 80 kHz. Spatial Data Deployment from R/V deck during cruises -Samples at 400 kHz

Typical Sources G. Wenz, 1962 identifies typical sources of ambient noise in deep water freq < 100 Hz: turbulent pressure fluctuations, seismic activity, explosions 10 – 10,000 Hz: ships, industrial activity 100 – 50,000 Hz: bubbles and spray, weather

Data Processing Basic Algorithm Raw voltage data is tapered FFT on tapered data FFT output to power spectral density Apply calibration curve Ensemble averages

Recording Hydrophone Results Spectra chosen to represent different acoustic conditions at the site.

Recording Hydrophone Results Spectrograms combine data in from individual spectra into a time series. Other ship traffic Ferry crossings June 15th, 2009 Spectrogram

Recording Hydrophone Results Sound Pressure Level (SPL) is obtained by integrating under the PSD curve June 15th, 2009 SPL Time Series

Recording Hydrophone Results Cumulative Probability Density Function for May-August mobile hydrophone deployment

Recording Hydrophone Results SPL and velocity time series data for May-August deployment

Recording Hydrophone Results SPL and depth averaged velocity time series for May 25th

Recording Hydrophone Results SPL vs. depth averaged velocity. Error bars represent two std. deviations. Error bars represent two standard deviations.

Recording Hydrophone Results Permanent Noise Levels for depth averaged velocity bins. Flood Ebb Depth Ave. Velocity (m/s) Total SPL (dB re 1 μPa) Per. Noise 0 - 0.5 112.8 ± 13.1 99.7 112.6 ± 13.3 99.3 0.5 - 1.0 115.7 ± 12.0 103.7 114.0 ±12.4 101.6 1.0 - 1.5 124.3 ± 10.8 113.5 118.7 ± 8.8 109.9 1.5 - 2.0 132.8 ± 8.3 124.5 126.5 ± 7.5 119.0 2.0 - 2.5 138.9 ± 6.9 132.0 133.1 ± 6.5 126.6 2.5 - 3.0 142.7 ± 3.8 138.9 138.1.6 ± 6.1 132.1 - 3.0 < 141.3 ± 4.1 137.2

Mobile Hydrophone Surveys Surveys taken in concentric circles around site at 0m, 500m, 1000m, 1500m, 2000m, and 2500m Surveys taken a 3m, 25m, and 50m below the surface Purpose is to search for patterns in spatial variations near the site.

Mobile Hydrophone Results Selected spectra demonstrate different conditions: Survey 10: Recreational boat near site (closest during 25m survey) - Survey 7: Quiet conditions

Mobile Hydrophone Results Mobile hydrophone survey map

Conclusions Stationary Hydrophone Surveys Mobile Hydrophone Surveys Stationary surveys demonstrate clear dependence on tidal currents Anthropogenic noise (ship traffic) also causes regular increases in spectral levels and SPLs Mobile Hydrophone Surveys Mobile hydrophones show no spatial patterns High resolution spectra and notes taken during surveys demonstrate impact of known anthropogenic noise sources on the acoustic environment

Ongoing Analysis Study impact of turbulent pressure fluctuations (psuedo sound) on recorded spectral levels - This is also called “flow noise” Seasonal variations? Use AIS to identify contributions from ship traffic

Ongoing Analysis Study feasibility of using the recording hydrophone in detecting cetacean vocalizations Example Orca Vocalization Acoustic Release

Acknowledgements Project funding provided by SnoPUD Joe Talbert for his fantastic equipment engineering Everybody in the CEE EFM lab Dr. Thomson and Dr. Polagye