Direct-detection LADAR systems / Richard D. Richmond and Stephen C. Cain.

Format:

Book

Author/Creator:

Richmond, Richard D., author.

Contributor:

Cain, Stephen C., 1969-

Society of Photo-Optical Instrumentation Engineers.

Series:

Tutorial texts in optical engineering ; TT85.

Tutorial texts in optical engineering ; v. TT85

Language:

English

Subjects (All):

Optical radar.

Physical Description:

1 online resource (xiv, 139 pages) : illustrations, digital file.

Place of Publication:

Bellingham, Wash. : SPIE, 2010.

System Details:

Mode of access: World Wide Web.

text file

Summary:

This text is designed to introduce engineers-in-training to the basic concepts and operation of 3D imaging LADAR systems. The book covers laser range equations; sources of noise in LADAR signals; LADAR waveforms; the effects of wavefront propagation on LADAR beams through optical systems and atmospheric turbulence; algorithms for detecting, ranging, and tracking targets; and comprehensive system simulation.

Contents:

Preface

Mathematical notation

Chapter 1. Introduction to LADAR systems

1.1. Background

1.2. LADAR and RADAR fundamentals. 1.2.1. Heterodyne versus direct detection

1.3. LADAR range equation. 1.3.1. Laser transmitter models; 1.3.2. Atmospheric transmission; 1.3.3. Target reflectivity and angular dispersion; 1.3.4. Dispersion upon reflection; 1.3.5. LADAR receiver throughput and efficiency

1.4. Types of LADAR systems and applications. 1.4.1. Three-dimensional-imaging LADAR systems

1.5. Sources of noise in LADAR systems. 1.5.1. Photon counting noise; 1.5.2. Laser speckle noise; 1.5.3. Thermal noise; 1.5.4. Background noise

1.6. LADAR systems and models. 1.6.1. Computational model for the range equation and signal-to-noise ratio (SNR); 1.6.2. Avalanche photodiode

1.7. Problems.

Chapter 2. LADAR Waveform Models

2.1. Fourier transform. 2.1.1. Properties of the DFT; 2.1.2. Transforms of some useful functions

2.2. Laser pulse waveform models. 2.2.1. Gaussian pulse model; 2.2.2. Negative parabolic pulse model; 2.2.3. Hybrid pulse models; 2.2.4. Digital waveform models

2.3. Pulse/target surface interaction models

2.4. LADAR system clock frequency and ranging error

2.5. Waveform noise models. 2.5.1. Waveform noise sources introduced at the single-sample level; 2.5.2. Sampling criteria and the effect of aliasing on waveforms

2.6. Problems.

Chapter 3. Wave propagation models.

3.1. Rayleigh-Sommerfeld propagation

3.2. Free-space propagation

3.3. Atmospheric turbulence phase screen simulation

3.4. LADAR system point spread function

3.5. Problems.

Chapter 4. Detection and estimation theory applied to LADAR signal detection.

4.1. Simple binary hypothesis testing

4.2. Decision criteria

4.3. Detection methods using waveform data

4.4. Receiver operating characteristics

4.5. Range estimation. 4.5.1. Peak estimator; 4.5.2. Cross-correlation range estimator; 4.5.3. Leading-edge detectors

4.6. Range resolution and range accuracy

4.7. Problems.

Chapter 5. LADAR imaging systems

5.1. Single-pixel scanning imagers

5.2. Gated viewing imagers. 5.2.1. Design and modeling considerations

5.3. Staring or FLASH Imagers

5.4. Modeling 2D and 3D FLASH LADAR systems

5.5. Speckle mitigation for imaging LADAR systems

References

Index.

Notes:

"SPIE digital library."

Includes bibliographical references (pages 135-136) and index.

Title from PDF t.p. (viewed on May 28, 2010).

ISBN:

9780819480736

OCLC:

646251910

Access Restriction:

Restricted for use by site license.