Acoustical Measurement of Nonlinear Internal Waves Using the Inverted Echo Sounder

The performance of pressure sensor-equipped inverted echo sounders for monitoring nonlinear internal waves is examined. The inverted echo sounder measures the round-trip acoustic travel time from the sea floor to the sea surface and thus acquires vertically integrated information on the thermal stru...

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Hauptverfasser:	Li, Qiang, Farmer, David M, Duda, Timothy F, Ramp, Steve
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Sprache:	eng
Schlagworte:	ACOUSTIC MEASUREMENT ACOUSTIC SCATTERING Acoustics AMBIENT NOISE BAROCLINIC MODE DYNAMIC RESPONSE ECHO RANGING ECHO SOUNDER EIGENVECTORS HYDROSTATICS INTERNAL WAVES KIRCHHOFF APPROXIMATION MONITORING OCEAN BOTTOM Physical and Dynamic Oceanography REPRINTS SEA STATES SIMULATION SOUTH CHINA SEA STRATIFICATION SURFACE ROUGHNESS SURFACE WAVE RECONSTRUCTION THERMOCLINES UNCERTAINTY WIND
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creator	Li, Qiang Farmer, David M Duda, Timothy F Ramp, Steve
description	The performance of pressure sensor-equipped inverted echo sounders for monitoring nonlinear internal waves is examined. The inverted echo sounder measures the round-trip acoustic travel time from the sea floor to the sea surface and thus acquires vertically integrated information on the thermal structure, from which the first baroclinic mode of thermocline motion may be inferred. This application of the technology differs from previous uses in that the wave period (30 min) is short, requiring a more rapid transmission rate and a different approach to the analysis. Sources of error affecting instrument performance include tidal effects, barotropic adjustment to internal waves, ambient acoustic noise, and sea surface roughness. The latter two effects are explored with a simulation that includes surface wave reconstruction, acoustic scattering based on the Kirchhoff approximation, wind-generated noise, sound propagation, and the instrument's signal processing circuitry. Bias is introduced as a function of wind speed, but the simulation provides a basis for bias correction. The assumption that the waves do not significantly affect the mean stratification allows for a focus on the dynamic response. Model calculations are compared with observations in the South China Sea by using nearby temperature measurements to provide a test of instrument performance. After applying corrections for ambient noise and surface roughness effects, the inverted echo sounder exhibits an RMS variability of approximately 4 m in the estimated depth of the eigenfunction maximum in the wind speed range 0 U10 10 m s-1. This uncertainty may be compared with isopycnal excursions for nonlinear internal waves of 100 m, showing that the observational approach is effective for measurements of nonlinear internal waves in this environment. Published in the Journal of Atmospheric and Oceanic Technology v26 p2228-2242, May 2009.
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The inverted echo sounder measures the round-trip acoustic travel time from the sea floor to the sea surface and thus acquires vertically integrated information on the thermal structure, from which the first baroclinic mode of thermocline motion may be inferred. This application of the technology differs from previous uses in that the wave period (30 min) is short, requiring a more rapid transmission rate and a different approach to the analysis. Sources of error affecting instrument performance include tidal effects, barotropic adjustment to internal waves, ambient acoustic noise, and sea surface roughness. The latter two effects are explored with a simulation that includes surface wave reconstruction, acoustic scattering based on the Kirchhoff approximation, wind-generated noise, sound propagation, and the instrument's signal processing circuitry. Bias is introduced as a function of wind speed, but the simulation provides a basis for bias correction. The assumption that the waves do not significantly affect the mean stratification allows for a focus on the dynamic response. Model calculations are compared with observations in the South China Sea by using nearby temperature measurements to provide a test of instrument performance. After applying corrections for ambient noise and surface roughness effects, the inverted echo sounder exhibits an RMS variability of approximately 4 m in the estimated depth of the eigenfunction maximum in the wind speed range 0 U10 10 m s-1. This uncertainty may be compared with isopycnal excursions for nonlinear internal waves of 100 m, showing that the observational approach is effective for measurements of nonlinear internal waves in this environment. Published in the Journal of Atmospheric and Oceanic Technology v26 p2228-2242, May 2009.</description><language>eng</language><subject>ACOUSTIC MEASUREMENT ; ACOUSTIC SCATTERING ; Acoustics ; AMBIENT NOISE ; BAROCLINIC MODE ; DYNAMIC RESPONSE ; ECHO RANGING ; ECHO SOUNDER ; EIGENVECTORS ; HYDROSTATICS ; INTERNAL WAVES ; KIRCHHOFF APPROXIMATION ; MONITORING ; OCEAN BOTTOM ; Physical and Dynamic Oceanography ; REPRINTS ; SEA STATES ; SIMULATION ; SOUTH CHINA SEA ; STRATIFICATION ; SURFACE ROUGHNESS ; SURFACE WAVE RECONSTRUCTION ; THERMOCLINES ; UNCERTAINTY ; WIND</subject><creationdate>2009</creationdate><rights>Approved for public release; distribution is unlimited.</rights><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>230,780,885,27567,27568</link.rule.ids><linktorsrc>$$Uhttps://apps.dtic.mil/sti/citations/ADA513066$$EView_record_in_DTIC$$FView_record_in_$$GDTIC$$Hfree_for_read</linktorsrc></links><search><creatorcontrib>Li, Qiang</creatorcontrib><creatorcontrib>Farmer, David M</creatorcontrib><creatorcontrib>Duda, Timothy F</creatorcontrib><creatorcontrib>Ramp, Steve</creatorcontrib><creatorcontrib>RHODE ISLAND UNIV NARRAGANSETT GRADUATE SCHOOL OF OCEANOGRAPHY</creatorcontrib><title>Acoustical Measurement of Nonlinear Internal Waves Using the Inverted Echo Sounder</title><description>The performance of pressure sensor-equipped inverted echo sounders for monitoring nonlinear internal waves is examined. The inverted echo sounder measures the round-trip acoustic travel time from the sea floor to the sea surface and thus acquires vertically integrated information on the thermal structure, from which the first baroclinic mode of thermocline motion may be inferred. This application of the technology differs from previous uses in that the wave period (30 min) is short, requiring a more rapid transmission rate and a different approach to the analysis. Sources of error affecting instrument performance include tidal effects, barotropic adjustment to internal waves, ambient acoustic noise, and sea surface roughness. The latter two effects are explored with a simulation that includes surface wave reconstruction, acoustic scattering based on the Kirchhoff approximation, wind-generated noise, sound propagation, and the instrument's signal processing circuitry. Bias is introduced as a function of wind speed, but the simulation provides a basis for bias correction. The assumption that the waves do not significantly affect the mean stratification allows for a focus on the dynamic response. Model calculations are compared with observations in the South China Sea by using nearby temperature measurements to provide a test of instrument performance. After applying corrections for ambient noise and surface roughness effects, the inverted echo sounder exhibits an RMS variability of approximately 4 m in the estimated depth of the eigenfunction maximum in the wind speed range 0 U10 10 m s-1. This uncertainty may be compared with isopycnal excursions for nonlinear internal waves of 100 m, showing that the observational approach is effective for measurements of nonlinear internal waves in this environment. 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The assumption that the waves do not significantly affect the mean stratification allows for a focus on the dynamic response. Model calculations are compared with observations in the South China Sea by using nearby temperature measurements to provide a test of instrument performance. After applying corrections for ambient noise and surface roughness effects, the inverted echo sounder exhibits an RMS variability of approximately 4 m in the estimated depth of the eigenfunction maximum in the wind speed range 0 U10 10 m s-1. This uncertainty may be compared with isopycnal excursions for nonlinear internal waves of 100 m, showing that the observational approach is effective for measurements of nonlinear internal waves in this environment. Published in the Journal of Atmospheric and Oceanic Technology v26 p2228-2242, May 2009.</abstract><oa>free_for_read</oa></addata></record>
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subjects	ACOUSTIC MEASUREMENT ACOUSTIC SCATTERING Acoustics AMBIENT NOISE BAROCLINIC MODE DYNAMIC RESPONSE ECHO RANGING ECHO SOUNDER EIGENVECTORS HYDROSTATICS INTERNAL WAVES KIRCHHOFF APPROXIMATION MONITORING OCEAN BOTTOM Physical and Dynamic Oceanography REPRINTS SEA STATES SIMULATION SOUTH CHINA SEA STRATIFICATION SURFACE ROUGHNESS SURFACE WAVE RECONSTRUCTION THERMOCLINES UNCERTAINTY WIND
title	Acoustical Measurement of Nonlinear Internal Waves Using the Inverted Echo Sounder
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