Presentation is loading. Please wait.

Presentation is loading. Please wait.

Acoustic intensity properties in an ocean waveguide Measurement and simulation of waveguide intensity structures David Dall’Osto and Peter H. Dahl Applied.

Published byRandolph Williams Modified over 8 years ago

Similar presentations

Presentation on theme: "Acoustic intensity properties in an ocean waveguide Measurement and simulation of waveguide intensity structures David Dall’Osto and Peter H. Dahl Applied."— Presentation transcript:

1 Acoustic intensity properties in an ocean waveguide Measurement and simulation of waveguide intensity structures David Dall’Osto and Peter H. Dahl Applied Physics Laboratory University of Washington Pacific Rim Underwater Acoustics Conference 2011 5-7 October 2011 Jeju Island, Korea

2 TAVEX Experiment ρ b = 1650 kg/m 3 c b = 1600 m/s Weight (1 ton) Bulb source Depth: ~35 m Range : 190 ~ 920 m Weight Acoustic release Battery & Data Acquisition frames 16 channels seperation : 3m fs : 20.47 kHz R/V Sunjin NRL VLA 12 bulb implosions (~40 m depth) measured on a VLA A1 pressure signal (190 m)

3 Acoustic Intensity (conservation of momentum) Hilbert Transform measured signal 90° out of phase Finite Difference Approximation pressure at midpoint complex signal from real signal particle velocity along array Scalar Intensity Instantaneous Intensity Complex Intensity Active Intensity Envelope Reactive Intensity Envelope Requires collocated measurement of both pressure and particle velocity

4 Complex Intensity: 190 m 27.5 m Active Intensity EnvelopeReactive Intensity Envelope 27.5 m DATA SIMULATION

5 Intensity structures: frequency domain B = 300 Hz f c = 210 Hz Crests (pressure/intensity maxima) Dislocations (pressure/intensity nulls) Normalized Quantity: pressure-intensity index crest null scalar intensity: f = 210 Hz (pekeris)

6 Frequency/Range Structure DATA (190 m)PE SIMULATION waveguide invariant Waveguide invariant observed in broadband measurements

7 Broadband every 50 m NB 210 Hz PE simulation DATA Experimental Visualization

8 Summary Complex Vertical Intensity: –Active: direction of energy propagation –Reactive: energy focusing/interference Intensity structures: pressure-intensity index –crests: |pI|<1 and |pQ|<1 –nulls/dislocations: |pI|>1 and |pQ|>1 The waveguide invariant: –map frequency to range –contours depict the modal structure of waveguide

Download ppt "Acoustic intensity properties in an ocean waveguide Measurement and simulation of waveguide intensity structures David Dall’Osto and Peter H. Dahl Applied."

Similar presentations

Sedan Interior Acoustics

Sedan Interior Acoustics
ISSUES IN PREDICTING SOLITARY WAVES IN STRAITS OF MESSINA AND LUZON A. Warn-Varnas, P. Smolarkiewicz, J. Hawkins, S. Piacsek, S. Chin-Bing, D. King and.

ISSUES IN PREDICTING SOLITARY WAVES IN STRAITS OF MESSINA AND LUZON A. Warn-Varnas, P. Smolarkiewicz, J. Hawkins, S. Piacsek, S. Chin-Bing, D. King and.
16.362 Signal and System I Magnitude-phase representation of Fourier Transform Magnitude-phase representation of frequency response of LTI systems.

Signal and System I Magnitude-phase representation of Fourier Transform Magnitude-phase representation of frequency response of LTI systems.
Purpose The aim of this project was to investigate receptive fields on a neural network to compare a computational model to the actual cortical-level auditory.

Purpose The aim of this project was to investigate receptive fields on a neural network to compare a computational model to the actual cortical-level auditory.
“ a disturbance or variation that transfers energy progressively from point to point in a medium and that may take the form of an elastic deformation or.

“ a disturbance or variation that transfers energy progressively from point to point in a medium and that may take the form of an elastic deformation or.
Long-Range Nonlinear Propagation in an Ocean Waveguide Kaëlig C ASTOR (1) Peter G ERSTOFT (1) Philippe R OUX (1) W. A. K UPERMAN (1) B. E. M C D ONALD.

Long-Range Nonlinear Propagation in an Ocean Waveguide Kaëlig C ASTOR (1) Peter G ERSTOFT (1) Philippe R OUX (1) W. A. K UPERMAN (1) B. E. M C D ONALD.
Chapter 4 Waves in Plasmas 4.1 Representation of Waves 4.2 Group velocity 4.3 Plasma Oscillations 4.4 Electron Plasma Waves 4.5 Sound Waves 4.6 Ion Waves.

Chapter 4 Waves in Plasmas 4.1 Representation of Waves 4.2 Group velocity 4.3 Plasma Oscillations 4.4 Electron Plasma Waves 4.5 Sound Waves 4.6 Ion Waves.
ECE 501 Introduction to BME

ECE 501 Introduction to BME
Head Waves, Diving Waves and Interface Waves at the Seafloor Ralph Stephen, WHOI ASA Fall Meeting, Minneapolis October 19, 2005 Ralph Stephen, WHOI ASA.

Head Waves, Diving Waves and Interface Waves at the Seafloor Ralph Stephen, WHOI ASA Fall Meeting, Minneapolis October 19, 2005 Ralph Stephen, WHOI ASA.
1 Sinusoidal Waves The waves produced in SHM are sinusoidal, i.e., they can be described by a sine or cosine function with appropriate amplitude, frequency,

1 Sinusoidal Waves The waves produced in SHM are sinusoidal, i.e., they can be described by a sine or cosine function with appropriate amplitude, frequency,
Study of the acoustic field generated by the electron beam in water Olga Ershova July, 19 th 2006 INFN Genova.

Study of the acoustic field generated by the electron beam in water Olga Ershova July, 19 th 2006 INFN Genova.
Mechanical Engineering UNIVERSITY OF WASHINGTON COLLEGE of ENGINEERING A Community of Innovators Prof. Peter Dahl Acoustics Research in Mechanical Engineering.

Mechanical Engineering UNIVERSITY OF WASHINGTON COLLEGE of ENGINEERING A Community of Innovators Prof. Peter Dahl Acoustics Research in Mechanical Engineering.
Waves Traveling Waves –Types –Classification –Harmonic Waves –Definitions –Direction of Travel Speed of Waves Energy of a Wave.

Waves Traveling Waves –Types –Classification –Harmonic Waves –Definitions –Direction of Travel Speed of Waves Energy of a Wave.
Preprocessing Ch2, v.5a1 Chapter 2 : Preprocessing of audio signals in time and frequency domain  Time framing  Frequency model  Fourier transform 

Preprocessing Ch2, v.5a1 Chapter 2 : Preprocessing of audio signals in time and frequency domain  Time framing  Frequency model  Fourier transform 
Extension of the Variable Rotated Parabolic Equation to Problems Involving Variable Topography Jon M. Collis and William L. Siegmann Rensselaer Polytechnic.

Extension of the Variable Rotated Parabolic Equation to Problems Involving Variable Topography Jon M. Collis and William L. Siegmann Rensselaer Polytechnic.
Statistics of broadband transmissions through a range-dependent fluctuating ocean waveguide Mark Andrews and Purnima Ratilal; Northeastern University,

Statistics of broadband transmissions through a range-dependent fluctuating ocean waveguide Mark Andrews and Purnima Ratilal; Northeastern University,
Methods Neural network Neural networks mimic biological processing by joining layers of artificial neurons in a meaningful way. The neural network employed.

Methods Neural network Neural networks mimic biological processing by joining layers of artificial neurons in a meaningful way. The neural network employed.
Pegasus Lectures, Inc. COPYRIGHT 2006 Volume I Companion Presentation Frank R. Miele Pegasus Lectures, Inc. Ultrasound Physics & Instrumentation 4 th Edition.

Pegasus Lectures, Inc. COPYRIGHT 2006 Volume I Companion Presentation Frank R. Miele Pegasus Lectures, Inc. Ultrasound Physics & Instrumentation 4 th Edition.
Scattered field from volume inhomogeneity First-order Rayleigh-Born approximation to Green’s Theorem Density contrastCompressibility contrast Monopole.

Scattered field from volume inhomogeneity First-order Rayleigh-Born approximation to Green’s Theorem Density contrastCompressibility contrast Monopole.
Single-path acoustic scintillation results from the Shallow Water 2006 Experiment DJ Tang, Daniel Rouseff, Frank Henyey, and Jie Yang Applied Physics Laboratory,

Single-path acoustic scintillation results from the Shallow Water 2006 Experiment DJ Tang, Daniel Rouseff, Frank Henyey, and Jie Yang Applied Physics Laboratory,

Similar presentations

Ads by Google