Optical Detection Theory for Laser Applications

A comprehensive treatment of the fundamentals of optical detection theory

Laser system applications are becoming more numerous, particularly in the fields of communications and remote sensing. Filling a significant gap in the literature, Optical Detection Theory for Laser Applications addresses the theoretical aspects of optical detection and associated phenomenologies, describing the fundamental optical, statistical, and mathematical principles of the modern laser system.

The book is especially valuable for its extensive treatment of direct detection statistics, which has no analog in radar detection theory and which has never before been compiled in a cohesive manner in a single book. Coverage includes:
* A review of mathematical statistics and statistical decision theory
* Performance of truncated and untruncated coherent and direct detection systems using Huygens-Fresnel and Gaussian beam theories
* Rough surface scatter and atmospheric propagation effects
* Single-pulse detection statistics for direct and coherent detection systems
* Multi-pulse detection statistics for direct and coherent detection systems

Supported by additional comments providing further insights into the physics or mathematics discussed and an extensive list of classic references, Optical Detection Theory for Laser Applications comprises a much-needed reference for the professional scientist or engineer, as well as a solid textbook for advanced students.

Table of Contents

Preface.

Chapter 1. Introduction and Background.

Chapter 2. Signal and Noise Analysis.  

Chapter 3. Random Processes in Beam Propagation.

Chapter 4. Single-Pulse Direct-Detection Statistics.

Chapter 5. Single-Pulse Coherent Detection Statistics.

Chapter 6. Multiple-Pulse Detection.

Appendix A. Advanced Mathematical Functions.

Appendix B. Additional Derivations.

References.

Index