Underwater acoustics : analysis, design, and performance of sonar

Offering complete and comprehensive coverage of modern sonar spectrum system analysis, Underwater Acoustics: Analysis, Design and Performance of Sonar provides a state-of-the-art introduction to the subject and has been carefully structured to offer a much-needed update to the classic text by Urick. Expanded to included computational approaches to the topic, this book treads the line between the highly theoretical and mathematical texts and the more populist, non-mathematical books that characterize the existing literature in the field. The author compares and contrasts different techniques for sonar design, analysis and performance prediction and includes key experimental and theoretical results, pointing the reader towards further detail with extensive references. Practitioners in the field of sonar design, analysis and performance prediction as well as graduate students and researchers will appreciate this new reference as an invaluable and timely contribution to the field.

Chapters include the sonar equation, radiated, self and ambient noise, active sonar sources, transmission loss, reverberation, transducers, active target strength, statistical detection theory, false alarms, contacts and targets, variability and uncertainty, modelling detections and tactical decision aids, cumulative probability of detection, tracking target motion analysis and localization, and design and evaluation of sonars

Author Notes

RICHARD P. HODGES has forty years experience in sonar, operations analysis, modeling, and the simulation of military systems. He is currently working for Sonalysts, Inc as a principal analyst, and is a member of the Acoustic Society of America. He has taught courses at the Naval Underwater Warfare Center (NUWC) and elsewhere in naval analysis of sonar, acoustics, TMA, tactics, weapons, damage and kill mechanisms, C4I, non-acoustic sensors, platform dynamics weapons, tactics and on the use of NUWC's SIM II Naval Engagement Simulation.

About the Author

Preface

Acknowledgements

1 Introduction to Sonar

1.1 Acoustic Waves

1.2 Speed of Propagation

1.3 Acoustic Wave Parameters

1.4 Doppler Shift

1.5 Intensity, SPL, and Decibels

1.6 Combining Acoustic Waves

1.7 Comparative Parameter for Sound in Water and Air

References

2 The Sonar Equations

2.1 Signal-to-Noise Ratio

2.2 Active Sonar Equation

2.3 Signal Excess

2.4 Figure of Merit

References

3 Transducers, Directionality, and Arrays

3.1 Transducer Response

3.2 Beam Pattern Response

3.3 Linear Arrays

3.4 Rectangular Planar Array

3.5 Amplitude Shading

3.6 Continuous Arrays

3.7 Volumetric Arrays

3.8 Product Theorem

3.9 Broadband Beam Patterns

3.10 Directivity and Array Gain

3.11 Noise Cross-Correlation between Hydrophones

3.12 Directivity of Line Arrays

3.13 Directivity of Area Arrays

3.14 Directivity of Volumetric Arrays

3.15 Difference Arrays

3.16 Multiplicative Arrays

3.17 Sparsely Populated Arrays

3.18 Adaptive Beamforming

References

4 Active Sonar Sources

4.1 Source Level

4.2 Cavitation

4.3 Near-Field Interactions

4.4 Explosive Sources

4.5 Physics of Shock Waves in Water

4.6 Bubble Pulses

4.7 Pros and Cons of Explosive Charges

4.8 Parametric Acoustic Sources

References

5 Transmission Loss

5.1 Sound Speed Profile in the Sea

5.2 Snell's Law and Transmission across an Interface

5.3 Reflection and Transmission Coefficients

5.4 Transmission through a Plate

5.5 Ray Tracing

5.6 Spreading Loss

5.7 Absorption of Sound in the Ocean

References

6 Transmission Loss: Interaction with Boundaries

6.1 Sea State, Wind Speed, and Wave Height

6.2 Pierson-Moskowitz Model for Fully Developed Seas

6.3 Sea Surface Interaction

6.4 Bottom Loss

6.5 Leakage Out of a Duct, Low-Frequency Cutoff

6.6 Propagation Loss Model Descriptions

References

7 Ambient Noise

7.1 Ambient Noise Models

7.2 Seismic Noise

7.3 Ocean Turbulence

7.4 Shipping Noise

7.5 Wave Noise

7.6 Thermal Noise

7.7 Rain Noise

7.8 Temporal Variability of Ambient Noise

7.9 Depth Effects on Noise

7.10 Directionality of Noise

7.11 Under Ice Noise

7.12 Spatial Coherence of Ambient Noise

References

8 Reverberation

8.1 Scattering, Backscattering Strength, and Target Strength

8.2 Reverberation Frequency Spread and Doppler Gain Potential

8.3 Important Observation with Respect to Reverberation

References

9 Active Target Strength

9.1 Target Strength Definition

9.2 Active Target Strength of a Large Sphere

9.3 Active Target Strength of a Very Small Sphere

9.4 Target Strengths of Simple Geometric Forms

9.5 Target Strength of Submarines

9.6 The TAP Model

9.7 Target Strength of Surface Ships

9.8 Target Strength of Mines and Torpedoes

9.9 Target Strength of Fish

References

10 Radiated Noise

10.1 General Characteristics of Ship Radiated Noise

10.2 Propeller Radiated Noise

10.3 Machinery Noise

10.4 Resonance Noise

10.5 Hydrodynamic Noise

10.6 Platform Quieting

10.7 Total Radiated Noise

Reference

11 Self Noise

11.1 Flow Noise

11.2 Turbulent Noise Coherence

11.3 Strumming Noise

References

12 Statistical Detection Theory

12.1 Introduction

12.2 Case 1: Signal Is Known Exactly

12.3 Case 2: Signal Is White Gaussian Noise

References

13 Methodology for Calculation of the Recognition Differential

13.1 Continuous Broadband Signals (PBB)

13.2 Continuous Narrowband Signals (PNB)

13.3 Active Sonar

13.4 Aural Detection

13.5 Display Nomenclature

References

14 False Alarms, False Contacts, and False Targets

14.1 Sea Story

14.2 Failure to Detect

14.3 Detection Theory

14.4 False Alarm Probability Calculation

14.5 False/Nonthreat Contacts

14.6 False Targets

14.7 Summary and Conclusions

References

15 Variability and Uncertainty

15.1 Random Variability of a Sonar

15.2 Sources of Variability

References

16 Modeling Detection and Tactical Decision Aids

16.1 Figure of Merit Range or R50 %

16.2 Tactical Decision Aids

References

17 Cumulative Probability of Detection

17.1 Why is CPD Important?

17.2 Discrete Glimpse and Continuous Looking

17.3 Lambda-Sigma Jump Model

17.4 Nonjump Processes

17.5 What Are Appropriate Random Parameters?

17.6 Approximation Method for Computation of the Cumulative Probability of Detection (CPD)

References

18 Tracking, Target Motion Analysis, and Localization

18.1 Bearing Trackers

18.2 General Principle of Tracking and Bearing Measurement

18.3 Other Sources of Bearing Error for Area Arrays

18.4 Additional Sources of Errors for Line Arrays

18.5 Bottom Bounce

18.6 Manual versus Automatic Tracking

18.7 Localization and Target Motion Analysis

18.8 Bearings Only Methodologies

18.9 Four-Bearing TMA

18.10 Ekelund Ranging

18.11 Range and Bearing TMA

18.12 Other Bearings Only TMA Methodologies

18.13 Other TMA and Localization Schemes

References

19 Design and Evaluation of Sonars

19.1 Choice of Frequency and Size

19.2 Computational Requirements

19.3 Signal Processing after Beamformer

19.4 Active Pulse Choice

19.5 Monostatic, Bistatic, and Multistatic Active Sonars

19.6 Ambiguity Functions

19.7 Mine Hunting and Bottom Survey Sonars

19.8 Echo Sounding and Fishing Sonars

19.9 Navigation

19.10 Vehicle Location and At-Sea Rescue

19.11 Intercept Receivers

19.12 Communications

19.13 Marine Mammals and Active Sonar

References

A Fourier Transforms

A.1 Definitions

A.2 Parseval's Theorem and Plancherel's Theorem

A.3 Properties of Fourier Transforms

A.4 Localization or Uncertainty Property

B Analysis of Errors Associated with a Least Squares Methodology

Reference

Index

Available:*

On Order

Summary

Summary

Author Notes

Table of Contents