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Advances in Optical Surface Texture Metrology covers the latest advances in the development of optical surface texture measuring instruments. Rather than concentrate on the basic principles of the optical measurement methods, this book takes a deeper dive into the operation of the instruments and the new application areas where they can be applied, with an emphasis on advanced manufacturing. Latest advances discussed will include the drive towards faster instruments for in-process applications, the ability to measure highly complex surfaces (in e.g. additive manufacturing) and advances in the use of machine learning to enhance data analysis. Key FeaturesCutting-edge advances in the fieldNew ISO framework for calibrationIncludes advances in artificial intelligenceIncludes advances in in-process measurement
This second edition of Lens Design: Automatic and quasi-autonomous computational methods and techniques shows how these new tools can design systems in minutes that would have required weeks or months of labor using older methods.Powerful search routines that can quickly produce excellent designs starting with plane-parallel plates are described. The principles are explained, and data files are provided so the user can duplicate these systems and learn how to use the new software to solve unexpected problems should they occur. Automatic substitution of real glass types for a glass model, and automatic matching to the testplates of a selected vendor are fully explained with examples.Key FeaturesDiscusses the pros and cons of traditional design tools and the role of aberration theory todayExplains the topology of the lens design landscape and why there are many different solutionsShows how to quickly achieve many potential solutions and how to select a preferred solutionDescribes tools for modifying a lens form by automatically inserting or deleting elementsLists a variety of tips and ideas that resulted from 50 years of experience
This book is an overview of state-of-the-art analytical homogenization formalisms used to estimate the effective electromagnetic properties of complex composite materials. Beginning with an introduction to homogenization, the book progresses to cover both constitutive and depolarization dyadics. The homogenization formalisms for linear and non-linear materials are examined, followed by their applications and multiple examples using Mathematica code. This text is a valuable reference for PhD students and researchers working on the electromagnetic theory of complex composite materials.Key FeaturesExplicit formulas provided for the homogenization of isotropic, anisotropic, and bianisotropic composite materialsNumerical data provided for a wide range of representative homogenized composite materialsIncludes Mathematica codes to enable readers to readily perform their own calculations
Intended for science and engineering students with a background in introductory physics and calculus, this textbook creates a bridge between classical and modern physics, filling the gap between descriptive elementary texts and formal graduate textbooks.
Rays Waves and Photons presents the foundational concepts of optical science. Written by subject, each topic is presented in a standalone chapter with a brief historical foundation, current developments, and future predictions. With non-technical language, this book provides accessible content with terms, concepts and definitions, a glossary, and appendices to enhance the reader''s experience. More than 40 subjects are discussed, including optical design, lenses, cameras, microscopes, telescopes, lasers, fibers, missiles, autonomous cars and remote sensing. This book will provide a useful resource for students, teachers, professionals, and general audiences interested in the complexity of optical phenomena and devices. Key FeaturesProvides foundations of the knowledge of light and its many applicationsUses simplified language for non-specialistsTerms and definitions are provided throughout, including a glossary
This book describes basic principles of electromagnetic induction measurements and consolidates the outcomes of recent research. It encompasses pipeline electromagnetic flow meters, electromagnetic flow meters, multiphase flow electromagnetic flowmeters and flow field of electromagnetic induction reconstruction.
This book describes the methodology and applications of solid-state NMR spectroscopy to studies of membrane proteins, membrane-active peptides and model biological membranes. As well as structural studies it contains coverage of membrane interactions and molecular motions. Advances in biological solid-state NMR are very pertinent with high-field developments seeing applications in biological membranes and whole cells. Many of the chapter authors and contributors are world-class experts and leaders in the development and application of biological solid-state NMR. Key Features Addresses principles, methods and applications of solid-state NMR methods to biomembrane studiesIntroduction to biological solid-state NMR and applications to biological membranesStructure and dynamics of membrane lipids, proteins and peptidesNMR studies of membrane interactions and molecular motion
Advances in Optical Form and Coordinate Metrology covers the latest advances in the development of optical form and coordinate measuring instruments plus the manipulation of point cloud data. The book presents some basic principles of the optical measurement methods and takes a deeper look at the operation of the instruments and the new application areas where they can be applied, with an emphasis on advanced manufacturing. Latest advances discussed include the drive towards faster instruments for in-process applications, the ability to measure highly complex objects (e.g. in additive manufacturing), performance verification and advances in the use of machine learning to enhance data analysis.Key FeaturesProvides cutting-edge advances in the fieldIncludes new ISO framework for performance verificationPresents advances in artificial intelligenceIncludes advances in in-process measurementDiscusses a forward look at calibration
Gas discharge plasma is the most common type of low-temperature plasma, with a large number of practical applications covering almost all areas of modern science and technology. This book is an introduction to the numerical modeling methods for gas discharge plasmas. It is intended to assist and direct graduate students and junior researchers, whose research activity deals with computational plasma physics. Topics covered include the essentials of basic modelling approaches (particle, fluid, and hybrid) for gas discharges, and the implementation of these methods with examples of glow (DC and RF) discharges. Numerical studies of nonlinear dynamics and formation of spatio-temporal patterns in gas discharge systems are also presented.Key FeaturesFocuses solely on gas discharge plasmasCovers basic modelling techniques, including particle, fluid, and hybridProvides details of applications and implementation for the considered methodsSpecial emphasis is given to the applicability and reliability of different modelling techniquesProvides specific examples of numerical simulations of the gas discharge plasmas
This book provides a thorough introduction to the topic of mathematical modeling of electrical activity in the heart, from molecular details of ionic channel dynamics to clinically derived patient-specific models.
Engineering Electrodynamics: A collection of theorems, principles and field representations deals with key theorems and principles that form the pillars on which engineering electromagnetics rests. In contrast to previous books, the emphasis here is on the underlying mathematical theme that binds these specific geometries. The relevant background material for the understanding of the various theorems is included in the book. After the theorems and principles are expounded, detailed examples are worked out, which further shed light on the those involved. This book also includes comprehensive material on some recent developments such as transformational electromagnetics. Detailed accounts of relevant complex variable theory, Bessel functions, and associated Legendre functions in the appendices make this book self-contained and suitable for graduate and advanced study. Key FeaturesSingle book that contains relevant theorems, principles and integral representations of importance to engineering electromagneticsIncludes new results not found in other booksDemonstrates the application of the theory to facilitate a clear understandingEmphasizes analysis as a complement as well as the building block to the more common approach of using computational/software tools in engineering problem solvingEnd-matter and appendices that contain valuable information on covariant formulation, special functions, and stochastic analysis
How do astronomers know what they know about the stars and planets? That is the question behind today''s rapid pace of cosmic discovery, for every new finding rests upon a centuries-long foundation of astronomical practice. Introduction to Stars and Planets: An activities-based exploration reveals the methods by which Earthbound observers have deduced the physical attributes of celestial bodies, whether situated within our solar neighborhood or at the far ends of the galaxy. The book''s 28 mildly mathematical activities invite readers to carry out the essential work of the astronomer by utilizing real observational data sets and high-quality celestial photographs to establish the innate properties of a range of cosmic systems. Taken in sequence, these activities illustrate the epic advancement of stellar and planetary astronomy over the past century, up to the present day.Key FeaturesWide-ranging topical coverage of both historical and up-to-the-minute aspects of astronomical discoveryUses a learning-by-doing approachStructured, goal-oriented framework centered on the methods and physical principles by which astronomers study the universeProvides real-time educational feedback to studentsIntroduces elementary mathematics for students to gain a truer sense of the work astronomers do
Common envelope evolution is the most important phase in the lives of many significant classes of binary stars. During a common envelope phase, the stars temporarily share the same outer layers, with the cores of both stars orbiting inside the same common envelope. This common envelope is sometimes ejected and helps to explain the formation of a wide variety of astrophysical phenomena, including cataclysmic variables, X-ray binaries, progenitors for type Ia supernovae, and gravitational-wave mergers.Modeling common envelope evolution is a challenging problem, and this important process has typically been described in evolutionary models using very approximate treatments. This book explains the physics of common envelope evolution and relates it to the approximations that are frequently used for modeling the onset, progression, and outcome of common envelope phases.Key FeaturesThe first book dedicated to the topicWritten by world-leading experts in the fieldProvides a thorough overview of theoretical foundations and state-of-art numerical modelsSuitable for graduate students and researchers
Encompasses the physics, design characteristics, simulation and interface electronics and including case studies, future challenges, as well as several other aspects of wider sensor technology, Advances in Modern Sensors provides an overview of modern sensors and their applications. The broad scope will appeal to industrial and academic researchers, and application engineers.
The use of spectroscopic techniques in the analysis and dating of archaeological and cultural artefacts is now well established and the data they produce is invaluable for archaeologists, curators and conservation scientists. This book reviews the applications of various spectroscopic techniques and, in particular, electron spin resonance spectroscopy in evaluating the structure and composition of materials for archaeological and cultural heritage research. Spanning both dating and compositional analysis methods of artefacts and their associated dating layers the book includes contributions from an international pool of researchers and uses case studies to demonstrate the applications of the techniques under discussion.
Electromagnetic Waves and Lasers reviews electromagnetic wave theory with a special emphasis on lasers and how to use them in optical systems. As a short treatise on this subject matter, this book aims to offer a quick overview that will allow the reader to gain a competent general understanding of electromagnetic waves and lasers, and how to use lasers in optical systems. Beginning with an introduction on electromagnetic waves, the book progresses to examine the application of electromagnetic wave theory, and the different aspects of working with lasers and their associated components. This second edition includes detailed information and procedures for setting up a laser optical system making it an excellent guide for those involved with using lasers.Key FeaturesA concise but detailed overview of electromagnetic waves and lasersIncludes detailed information and procedures for setting up a laser optical system, making it an excellent guide for those involved with using lasersProvides examples of how the theory is manifested in real life and also practical knowledge about lasers, their operation and usage
An Introduction to Fluorescence Correlation Spectroscopy represents a comprehensive introduction to fluorescence correlation spectroscopy (FCS), a biophysical experimental technique increasingly used to study and quantify molecular mobility, concentrations and interactions in vitro, as well as in living cells and multicellular organisms. Students and researchers who are new to FCS can use the book as the first introduction to the technique, while those who are already using FCS regularly in their research may find it useful to deepen their understanding of the technique, its possibilities, limitations, and potential pitfalls as well as ways to avoid them. This book introduces the reader to all aspects of FCS needed for practical usage of the technique in their research. In the beginning the concept of fluorescence intensity fluctuations and their auto- and cross-correlation functions are explained to give readers an understanding of the underlying principles. This is followed by an overview of instrumental FCS setups and various ways of data collection and processing, the derivations of theoretical models relating the experimentally obtained correlation functions to the underlying molecular processes, and the description of the fitting of experimental data with those models. Mathematically more involved portions are separated from the rest of the text and can be easily skipped by readers more interested in the conceptual and practical aspects of FCS. The book contains interactive graphics and is accompanied by an interactive computable document file allowing the reader to test the dependence of FCS results on a variety of experimental parameters, and to gain practical insights into FCS data fitting.Key FeaturesIntroduces the concepts of FCS in an accessible way, supported by animations and graphics in the ebook.Includes a supplementary interactive computable document file that allows the reader to experiment with various FCS setup and fit parameters, allowing readers to test their understanding and simulate experimental outcomes.Provides rigorous mathematical derivations of fundamental FCS equations and models.Pedagogical features include questions, short reviews and critical discussions of literature relevant to the particular chapter that include applications and fundamental developments in the field of FCS.
This book introduces the quantum statistical methods used in quantum physics and is an essential guide for any student beginning their studies in quantum physics.
This book provides an overview of the detailed physics involved in the imaging chain for an audience of scientists and engineers. With the increasing use of digital photography in a research environment, modern scientists and engineers need to better understand the science behind digital photography to fully exploit this invaluable research tool.
In the course of only a few decades computers have revolutionized scientific research and more and more scientists are writing computer programs for doing their work. In spite of the ubiquitous use of computers in science, few researchers in the natural sciences have any schooling in computer science, software engineering, or numerical analysis. They usually acquire their computing knowledge "on the job" and often feel overwhelmed by the amount of computing knowledge they must absorb. Computation in Science provides a background in computation for scientists who use computational methods. The book explains how computing is used in the natural sciences and provides a high-level overview of relevant aspects of computer science and software engineering with a focus on concepts, results, and applications. The goal of this book is to explain these basic principles, and to show how they relate to the tasks of a scientist''s daily work in a language familiar to them. Its unique feature is in connecting the dots between computational science, the theory of computation and information, and software engineering. It will compensate for the general lack of any formal training in computer science and information theory allowing readers to achieve a better understand how they use computers in their work, and how computers work. Readers will learn to use computers with more confidence, and to see computing technologies in a different light, evaluating them based on how they contribute to doing science.This new edition has been significantly updated and extended to reflect developments in scientific computing, including new examples and references. It also includes a new chapter on reproducibility which reflects the importance that computational reproducibility. Accompanied by a website maintained by the author, which hosts companion code and supplementary material, it is intended for both graduate students and experienced scientists. Some hands-on experience with computing is highly desirable, but no competence in any specific computing technology is expected.Key FeaturesSignificantly updated and enhanced, including a new chapter on reproducibility, it''s one of the first books to include this in the era of the "reproducibility crisis"Updated references to include the latest research resultsAccessible to a broad range of physical and life scientists with no formal training in computingWritten for both graduate students and experienced scientistsSupported by the website http://computation-in-science.khinsen.net/ with updates, links to useful sites and software
This book looks at analysis and modelling of active biopotential signal processing. It emphasises the real-time challenges in biomedical signal processing that occur due to the complex and non-stationary nature of signals in a variety of applications for analysis, classification and identification of different states for improvement of healthcare systems. The main focus of the book is on modelling; acquisition of biomedical signals for different disorders; implementation of methodologies and their impact on different cases; case studies and research directions; automatic identification of related disorders; design and simulation examples; and issues and challenges. Overall, the book addresses the real-time challenges in biomedical signal processing used in a variety of applications such as analysis, classification and identification of different disorders in healthcare systems. It is a valuable guide for all researchers and practitioners who are engaged in studies and research in the area of biomedical signals and their applications. Key Features Modelling and acquisition of biomedical signals for different disordersImplementation of methodologies and their impact on different casesCase studies and research directionsDesign and simulation examples
This graduate textbook introduces the physics and applications of transport in mesoscopic devices and nanoscale electronic systems and devices. Fully updated and contains the latest research in the field, including nano-devices for qubits. Worked examples, problems, solutions and videos are provided to enhance understanding.
Advances in wide bandgap semiconductor materials are enabling the development of a new generation of power semiconductor devices that far exceed the performance of silicon-based devices. These technologies offer potential breakthrough performance for a wide range of applications, including high-power and RF electronics, deep-UV optoelectronics, quantum information and extreme-environment applications.This reference text provides comprehensive coverage of the challenges and latest research in wide and ultra-wide bandgap semiconductors. Leading researchers from around the world provide reviews on the latest development of materials and devices in these systems.The book is an essential reference for researchers and practitioners in the field of wide bandgap semiconductors and power electronics, and valuable supplementary reading for advanced courses in these areas.Key Features Provides comprehensive coverage of wide bandgap semiconductor-based electronicsCovers both materials and devicesIncludes cutting-edge research not covered in other booksVery experienced editors - they have produced 19 other books in related areas
This book is an essential introduction to the basic principles of radiation protection and aerosol physics, including applications within international and UK law for the protection of the public against the dangers arising from ionising radiation. The text also discusses the difficulties with the monitoring and the health detriment associated with problematic radionuclides.
This book on the laboratory teaching of optics is based on the author's experience during many years in several universities and colleges. It describes basic experiments in optics that are suitable for student laboratories at undergraduate and graduate levels and do not require specialized equipment or measurement techniques.
Classical Mechanics: A professor-student collaboration is a textbook tailored for undergraduate physics students embarking on a first-year module in Newtonian mechanics. This book is a collaboration between Mario Campanelli and students that attended his course in classical mechanics at University College London, based on the course lecture notes w
This book is primarily devoted to recent advances in applying the approximate analytical method of the separation of rapid and slow subsystems to other quantum realms. These results are practically important in the quest for achieving controlled nuclear fusion on Earth, as well as expanding practical applications of lasers and other related fields.
This volume focuses on energy devices such as supercapacitors, batteries, energy harvesters, solar cells, and the applications of flexible electronics in displays and light-emission devices, CNT field emitters, sensors, memories, antennas and RFID tags.
This volume focuses on thin-film transistors (TFTs) and their properties, as well as covering field effect transistors (FETs), including electrolyte-gated field-effect transistors such as EGOFETs and OECFETs.
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