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E-raamat: Introduction to Sonar Systems Engineering 2nd edition [Taylor & Francis e-raamat]

(Naval Postgraduate School, Monterey, California, USA)
  • Formaat: 747 pages, 48 Tables, black and white; 153 Line drawings, black and white; 9 Halftones, color; 162 Illustrations, black and white
  • Ilmumisaeg: 23-Aug-2022
  • Kirjastus: CRC Press
  • ISBN-13: 9781003259640
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  • Taylor & Francis e-raamat
  • Hind: 258,50 €*
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  • Tavahind: 369,29 €
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Introduction to Sonar Systems Engineering 2nd editionSuurem pilt
  • Formaat: 747 pages, 48 Tables, black and white; 153 Line drawings, black and white; 9 Halftones, color; 162 Illustrations, black and white
  • Ilmumisaeg: 23-Aug-2022
  • Kirjastus: CRC Press
  • ISBN-13: 9781003259640
Teised raamatud teemal:
Taylor & Francis e-raamatudRohkem infot Taylor & Francis e-raamatute kohta
Raamatu kodulehekülg: https://www.taylorfrancis.com/books/9781003259640
An Introduction to Sonar Systems Engineering

Second Edition

Important topics that are fundamental to the understanding of modern-day sonar systems engineering are featured. Linear, planar, and volume array theory, including near-field and far-field beam patterns, beam steering, and array focusing, are covered. Real-world arrays such as the twin-line planar array and a linear array of triplets, which are solutions to the port/starboard (left/right) ambiguity problem associated with linear towed arrays, are examined in detail.

Detailed explanations of the fundamentals of side-looking (side-scan) and synthetic-aperture sonars are presented. Bistatic scattering with moving platforms is explored with derivations of exact solutions for the time delay, time-compression/time-expansion factor, and Doppler shift at a receiver for both the scattered and direct acoustic paths. Time-domain and frequency-domain descriptions, and the design of CW, LFM, and Doppler-invariant HFM pulses, are explained. Target detection in the presence of reverberation and noise is examined. Time-domain and frequency-domain descriptions of MFSK, MQAM, and OFDM underwater acoustic communication signals are also discussed.

Although the book is mathematically rigorous, it is written in a tutorial style. Many useful, practical design and analysis equations for both passive and active sonar systems are derived from first principles. No major steps in the derivation of important results are skipped all assumptions and approximations are clearly stated. Particular attention is paid to the correct units for functions and parameters. Many figures, tables, examples, and practical homework problems at the end of each chapter are included to aid in the understanding of the material covered.

New to the Second Edition





Chapter 15 Synthetic-Aperture Sonar





Chapter 13, Section 13.3, The Rectangular-Envelope HFM Pulse





Chapter 10, Section 10.7, Moving Platforms, was rewritten, which allowed for the elimination of Appendix 10C from the first edition





New explanations/discussions were added to Subsections 1.2.1 and 1.3.1 in Chapter 1





Appendix 1A was rewritten and the new Table 1A-1 was added to Chapter 1 A solutions manual is available for adopting professors
1. Complex Aperture Theory Volume Apertures General Results.
2.
Complex Aperture Theory Linear Apertures. 3 Complex Aperture Theory
Planar Apertures.
4. Time-Average Radiated Acoustic Power. 5 Side-Looking
Sonar.
6. Array Theory Linear Arrays.
7. Array Gain.
8. Array Theory
Planar Arrays.
9. Array Theory Volume Arrays.
10. Bistatic Scattering.
11.
Real Bandpass Signals and Complex Envelopes. 
12. Target Detection in the
Presence of Reverberation and Noise.
13. The Auto-Ambiguity Function and
Signal Design.
14. Underwater Acoustic Communication Signals. 15
Synthetic-Aperture Sonar.
Dr. Lawrence J. Ziomek is a Professor Emeritus with the Department of Electrical and Computer Engineering at the Naval Postgraduate School in Monterey, CA, where he was also a member of the Undersea Warfare Executive Committee and the Undersea Warfare Academic Group. With over 37 years of research and teaching experience, his research and teaching interests include underwater acoustics, sonar systems engineering and signal processing, Biosonar, communication theory, and signal detection and estimation theory. He received a B.E. degree in electrical engineering from Villanova University, a M.S.E.E. degree from the University of Rhode Island, and a Ph.D. degree in acoustics (underwater acoustics specialization) from The Pennsylvania State University, with a minor in electrical engineering.
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