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Vol 2 : Physical Image Formation<br> Introduction<br> 17 The Wave Equation<br> 18 Scalar Diffraction<br> 19 Interference and Coherence<br> 20 The Geometrical Optical Description and Incoherent Imaging<br> 21 The Abbe Theory of Imaging<br> 22 Coherence Theory of Optical Imaging<br> 23 Three Dimensional Imaging<br> 24 Image Examples of Selected Objects<br> 25 Special System Examples and Applications<br> 26 Polarization<br> 27 Vector Diffraction<br> 28 Polarization and Optical Imaging<br> A1 Mathematical Appendix

"... a compendium of information that would be of interest to optical engineering, physicists and others."<br> American Reference Books Annual<br> <br> "The first two out of six volumes of the series Handbook of optical systems comes with more than 800 fullcoloured illustrations and images for an easy understanding of complex optical systems. [...] This series can be used by professionals as a comprehensive reference as well as an introduction for beginners in technicaloptics."<br> Colloid Polym Sci <br>

Wolfgang Singer<br> <br> Wolfgang Singer was born in 1964 and studied Physics at the University of Erlangen. He received his Ph.D. at the Institute of Applied Optics in 1995 with a thesis on microoptics, propagation theory and tomography. He spent his post doctorate at the Institute de Microtechnique in Neuchatel, where he developed diffractive diffusors for DUV illumination systems. From 1996 to 1998, he was assistant at the Institute of Applied Optics at the University of Stuttgart. Since 1998, he has been with Carl Zeiss SMT AG, working in the department of optical design and simulation for lithographic optics. His work includes tolerancing of objectives and the design of illumination systems of EUV systems. He became principal scientist and was engaged at the scientific training programme at Carl Zeiss. His special interests are imaging theory and partial coherence, and he has written his own simulation software. He holds 50 patents and has published about 30 papers and contributions to textbooks.<br> <br> Michael Totzeck<br> <br> Michael Totzeck was born in 1961. He received his diploma degree in Physics in 1987 and his Ph.D. in 1989, both from the Technical University of Berlin, where he also did his habilitation in 1995. In 1991 he was awarded the Carl-Ramsauer-Award of the AEG AG for his Ph.D thesis on near field diffraction. From 1995 to 2002, he headed a group on high resolution microscopy at the Institute of Applied Optics in Stuttgart, working by experimental, theoretical and numerical means on optical metrology at the resolution limit. He has been with the Carl Zeiss SMT AG since 2002, working in the department for optical design. His current research topic is electromagnetic imaging with high-NA optical systems. He has published 40 papers on diffraction theory, near-field optics, high-resolution microscopy, interferometry, metrology, optical singularities, polarization-optics and physics education.<br> <br> <br> Herbert Gross<br> <br> Herbert Gross was born in 1955. He studied Physics at the University of Stuttgart and joined Carl Zeiss in 1982. Since then he has been working in the department of optical design. His special areas of interest are the development of simulation methods, optical design software and algorithms, the modelling of laser systems and simulation of problems in physical optics, and the tolerancing and the measurement of optical systems. Since 1995, he has been heading the central optical design department at Zeiss. He served as a lecturer at the University of Applied Sciences at Aalen and at the University of Lausanne, and gave seminars for the Photonics Net of Baden Wurttemberg as well as several company internal courses. In 1995, he received his PhD at the University of Stuttgart on a work on the modelling of laser beam propagation in the partial coherent region. He has published several papers and has given many talks at conferences.

The state-of-the-art full-colored handbook gives in six volumes a comprehensive introduction to the principles and the practice of calculation, layout and understanding of optical systems and lens design. Written by reputed industrial experts in the field the user is introduced to the basic properties of optical systems, aberration theory, classification and characterization of systems, advanced simulation models, measuring of system quality and manufacturing issues. More than 3,000 full-colored illustrations and images support the reader and supply an easy understanding of complex optical systems and optical modeling.<br> <br> Vol.1 Fundamentals of Technical Optics<br> Vol.2 Physical Image Formation<br> Vol.3 Aberration Theory and Correction of Optical Systems<br> Vol.4 Survey of Optical Instruments<br> Vol.5 Metrology of Optical Components and Systems<br> Vol.6 Advances Physical Optics<br> <br> <br> In this volume<br> Volume 2 continues the introduction given in volume 1 with the more advanced texts about the foundations of image formation. Emphasis is placed on an intuitive while theoretically exact presentation. Totally more 400 color graphs and selected references on the end of each chapter support this undertaking.<br> <br> From the content<br> <br> 17 Wave equation<br> 18 Diffraction<br> 19 Interference and coherence<br> 20 Imaging<br> 21 Imaging with partial coherence<br> 22 Three dimensional imaging<br> 23 Polarization<br> 24 Polarization and optical imaging<br> A1 Mathematical appendix<br>

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