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.

This newly revised and updated edition offers a current and complete introduction to the analysis and design of Electro-Optical (EO) imaging systems. The Third Edition provides numerous updates and several new chapters including those covering Pilotage, Infrared Search and Track, and Simplified Target Acquisition Model. The principles and components of the Linear Shift-Invariant (LSI) infrared and electro-optical systems are detailed in full and help you to combine this approach with calculus and domain transformations to achieve a successful imaging system analysis. Ultimately, the steps described in this book lead to results in quantitative characterizations of performance metrics such as modulation transfer functions, minimum resolvable temperature difference, minimum resolvable contrast, and probability of object discrimination. The book includes an introduction to two-dimensional functions and mathematics which can be used to describe image transfer characteristics and imaging system components. You also learn diffraction concepts of coherent and incoherent imaging systems which show you the fundamental limits of their performance. By using the evaluation procedures contained in this desktop reference, you become capable of predicting both sensor test and field performance and quantifying the effects of component variations. The book contains over 800 time-saving equations and includes numerous analyses and designs throughout. It also includes a reference link to special website prepared by the authors that augments the book in the classroom and serves as an additional resource for practicing engineers. With its comprehensive coverage and practical approach, this is a strong resource for engineers needing a bench reference for sensor and basic scenario performance calculations. Numerous analyses and designs are given throughout the text. It is also an excellent text for upper-level students with an interest in electronic imaging systems.

Proceedings of the 22nd Course of the International School of Quantum Electronics, held 27 November-2 December 1997, in Erice, Italy. In recent years, fiber optical sensors and optical microsystems have assumed a significant role in sensing and measurement of many kinds. These optical techniques are utilised in a wide range of fields, including biomedicine, environmental sensing, mechanical and industrial measurement, and art preservation. This volume, an up-to-date survey of optical sensors and optical microsystems, aims at combining a tutorial foundation with analysis of current research in this area, and an extensive coverage of both technology and applications.

A video signal measurement system which provides more reliable estimates of the performance parameters of E-O sensors than has been possible using previous methods is described. This system, consisting of 100 MHz sample-rate transient recorder interfaced to a minicomputer, acquires data from a sensor under test at near-real-time rates and then rapidly analyzes the data to obtain performance parameter estimates. The use of the system for the measurement of signal-to-noise ratios, signal transfer functions, spectral transfer functions, modulation transfer functions, aperture response, and noise spectral density are described. The measurement of the above parameters under static and dynamic conditions with stationary and moving targets is discussed. Results of measurements performed on a low light level television sensor are given along with a comparison of the measurements obtained on this sensor using standard analog methods.

A cutting-edge, advanced level, exploration of optical sensing application in power transformers Optical Sensing in Power Transformers is filled with the critical information and knowledge on the optical techniques applied in power transformers, which are important and expensive components in the electric power system. Effective monitoring of systems has proven to decrease the transformer lifecycle cost and increase a high level of availability and reliability. It is commonly held that optical sensing techniques will play an increasingly significant role in online monitoring of power transformers. In this comprehensive text, the authors—noted experts on the topic—present a scholarly review of the various cutting-edge optical principles and methodologies adopted for online monitoring of power transformers. Grounded in the authors’ extensive research, the book examines optical techniques and high-voltage equipment testing and provides the foundation for further application, prototype, and manufacturing. The book explores the principles, installation, operation, condition detection, monitoring, and fault diagnosis of power transformers. This important text; Provides a current exploration of optical sensing application in power transformers Examines the critical balance and pros and cons of cost and quality of various optical condition monitoring techniques Presents a wide selection of techniques with appropriate technical background Extends the vision of condition monitoring testing and analysis Treats condition monitoring testing and analysis tools together in a coherent framework Written for researchers, technical research and development personnel, manufacturers, and frontline engineers, Optical Sensing in Power Transformers offers an up-to-date review of the most recent developments of optical sensing application in power transformers.

This report describes efforts to support technology developments for advanced sensor testing at Arnold Engineering Development Center (AEDC). Advanced sensor testing concepts and methodologies for AEDC test facilities are described in detail. Methodologies are provided to Support generation of complex scenes for sensor testing with some emphasis devoted to fractal interpolation. Experimental evaluation and development efforts demonstrate the feasibility of extending the Direct Write Scene Generation (DWSG) method for optical projection through electrooptical sensor systems containing the sensor optics. The report provides a discussion of verification and validation concepts and methods to support advanced optical diagnostics and sensor testing.