This tutorial introduces the theory and applications of MTF, used to specify the image quality achieved by an imaging system. It covers basic linear systems theory and the relationship between impulse response, resolution, MTF, OTF, PTF, and CTF. Practical measurement and testing issues are discussed.
This practical guide is a compendium of frequently asked questions (FAQs). The answers are provided in graphs, equations, or diagrams. An engineering approach is taken, the equations may be approximations, but the region of applicability is clearly stated. Facts, rules-of-thumb, and back-of-the-envelope equations are highlighted. This easy-to-read reference covers optical systems, detectors, cameras (visible and infrared), sampling effects, Moiré patterns, system performance, resolution, system testing, lasers and lidar, fiber optics, and data analysis.
Topics covered by this text include imaging, radiometry, source detectors and lasers, with a special emphasis on flux-transfer issues. The author takes a first-order approach so that students and professionals can quickly make the back-of-envelope calculations needed for initial setup of optical apparatus. The target is to help readers solve the practical problems frequently encountered by those new to the field of electro-optics. The text aims to enable readers to answer such questions as: where is the image, how big is it, how much light gets to the detectors, and how small an object is it possible to see?
This engineering tool provides over 200 time and cost saving rules of thumb--short cuts, tricks, and methods that optical communications veterans have developed through long years of trial and error. * DWDM (Dense Wavelength Division Multiplexing) and SONET (Synchronous Optical NETwork) rules * Information Transmission, fiber optics, and systems rules
Presents practical electro-optical applications in the context of the fundamental principles of communication theory, thermodynamics, information theory and propagation theory. Combining systems issues with fundamentals of communications, this is an essential reference for all practising engineers and academic researchers in optical engineering.
Praise for the First Edition "Now a new laboratory bible for optics researchers has joined the list: it is Phil Hobbs's Building Electro-Optical Systems: Making It All Work." —Tony Siegman, Optics & Photonics News Building a modern electro-optical instrument may be the most interdisciplinary job in all of engineering. Be it a DVD player or a laboratory one-off, it involves physics, electrical engineering, optical engineering, and computer science interacting in complex ways. This book will help all kinds of technical people sort through the complexity and build electro-optical systems that just work, with maximum insight and minimum trial and error. Written in an engaging and conversational style, this Second Edition has been updated and expanded over the previous edition to reflect technical advances and a great many conversations with working designers. Key features of this new edition include: Expanded coverage of detectors, lasers, photon budgets, signal processing scheme planning, and front ends Coverage of everything from basic theory and measurement principles to design debugging and integration of optical and electronic systems Supplementary material is available on an ftp site, including an additional chapter on thermal Control and Chapter problems highly relevant to real-world design Extensive coverage of high performance optical detection and laser noise cancellation Each chapter is full of useful lore from the author's years of experience building advanced instruments. For more background, an appendix lists 100 good books in all relevant areas, introductory as well as advanced. Building Electro-Optical Systems: Making It All Work, Second Edition is essential reading for researchers, students, and professionals who have systems to build.
This book describes the analysis and modeling involved with the design, specification and evaluation of electro-optical systems and components. The emphasis is on imaging infrared sensor systems, with analytical models that include the radiation source, atmospheric transmission, geometric and physical optics, a detector, amplifier and optical noise analysis, and detection and false alarm probabilities. Much of the analysis goes beyond what is normally available in engineering texts; the noise analysis includes a practical detector/amplifier 1/f noise model based, in part on real world results. The last chapter, "Example Calculations," includes a complete model of an infrared sensor system working in the 3 to 5 micron atmospheric transmission window. The examples, which incorporate much of the work of the previous chapters, shows how to specify the frame and integration time, detection and false alarm probabilities, array size, the angular resolution and so forth. Once these parameters are specified, using practical inputs, the various noise contributors are calculated, and important system level parameters are determined. The parameters include the signal to noise ratio, the specific detectivity (which is related to the sensitivity of the system) and dynamic range. This book is, however, more general than a sensor system book. The "Geometric Optics" chapter includes thick and thin lenses along with the other standard topics. "Electromagnetic Waves & Physical Optics" starts with Maxwell's Equations and ends with reflection at an air-metal interface. The chapter on "Angular Characterization & Related Parameters" includes aberrations, stops, vignetting, f-number, numerical aperture, diffraction and various geometric blur diameters. It also includes determination of array size, field of view, integration time, time delay and integration, etc. In "Radiometry and Photometry," various radiometric and photometric functions are defined, starting at radiant and luminous energy and ending with the Etendue Theorem. Tristimulus Colorimetry and the Photopic/Scotopic Spectral functions are also discussed. In the chapter, "Radiometry Calculation Procedures," conversions between various radiometric quantities are illustrated using a grey-body source; the background, signal, scattered and emitted flux are also considered. In "Detector and Amplifier Parameters," the electrical bandwidth, reset time, all major noise mechanisms, the Responsivity, Noise Equivalent Power, Specific Detectivity, are some of the topics discussed. In System Parameters, there are compact discussions of Fourier Transforms, the Autocorrelation Function, the Nyquist Criteria, Modulation Transfer Functions, Atmospheric Transmission, signal to noise and threshold to noise (detection/false alarm probabilities). The last chapter is the example calculation of sensor performance.
Geometrical Optics in the Paraxial Area; Theory of Imaging; Sources of Light and Illumination Systems; Detectors of Light; Optical Systems for Spectral Measurements; Non-contact Measurements of Temperature; Optical Scanners and Acousto-Optics; Optical Systems for Distance and Size Measurements; Optical Systems for Flow Parameter Measurements; Color and Its Measurement.
"Field Guide to Infrared Systems, Detectors, and FPAs, Third Edition is devoted to fundamental background issues for optical detection processes. It compares the characteristics of cooled and uncooled detectors with an emphasis on spectral and blackbody responsivity, detectivity, as well as the noise mechanisms related to optical detection. It introduces the concepts of barrier infrared detector technologies, and encompasses the capabilities and challenges of third-generation infrared focal plane arrays as well as the advantages of using dual-band technology. The book combines numerous engineering disciplines necessary for the development of an infrared system. It considers the development of search infrared systems and specifies the main descriptors used to characterize thermal imaging systems. Furthermore, this guide clarifies, identifies, and evaluates the engineering tradeoffs in the design of an infrared system"--