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Updated and easy-to-use, Linne & Ringsrud's Clinical Laboratory Science: The Basics and Routine Techniques, 6th Edition delivers a fundamental overview of the laboratory skills and techniques essential for success in your classes and your career. Author Mary Louise Turgeon's simple, straightforward writing clarifies complex concepts, and a discipline-by-discipline approach helps you build the knowledge to confidently perform clinical laboratory tests and ensure accurate, effective results. Expert insight from respected educator and author Mary Louise Turgeon reflects the full spectrum of clinical laboratory science. Engaging full-color design and illustrations familiarize you with what you'll see under the microscope. Streamlined approach makes must-know concepts and practices more accessible. Broad scope provides an ideal introduction to clinical laboratory science at various levels, including MLS/MLT and Medical Assisting. Hands-on procedures guide you through the exact steps you'll perform in the lab. Learning objectives help you identify key chapter content and study more effectively. Case studies challenge you to apply concepts to realistic scenarios. Review questions at the end of each chapter help you assess your understanding and identify areas requiring additional study. A companion Evolve website provides convenient online access to procedures, glossary, audio glossary and links to additional information. Updated instrumentation coverage familiarizes you with the latest technological advancements in clinical laboratory science. Perforated pages make it easy for you to take procedure instructions with you into the lab. Enhanced organization helps you study more efficiently and quickly locate the information you need. Convenient glossary provides fast, easy access to definitions of key terms.
This Spotlight teaches the commands necessary to analyze spectroscopic data (Raman/FTIR) using MATLAB. It explains how to build an analysis routine step by step and perform pre-processing and multivariate analysis with a single click. The script for support vector machines (SVMs) is also briefly addressed so that readers can build a script tailored to their own laboratory routine.
This Spotlight is intended for experimentalists learning how to perform laser damage measurements on cameras. The importance of understanding the laser-induced damage threshold of a camera and how it can define protection measures is discussed. A guide to the experimental methodology and testing considerations to measure the damage threshold of an off-the-shelf visible-band charge-coupled device (CCD) camera to a pulsed laser under laboratory conditions is presented. This same methodology can be applied to other 2-D detector arrays, and the steps to adjust the experimental process to perform continuous-wave laser damage threshold measurements are described. Finally, data analysis techniques relevant to this type of experiment are addressed.
This Spotlight discusses the theoretical and experimental aspects of RGB interferometry. It also focuses on various advanced RGB interferometers and their applications for 3-D surface profiling, deformation measurements, non-destructive testing (NDT), refractive index profiling of biological cells/tissues, etc. RGB interferometry is a fast, simple, and cost-effective tool for optical metrology and imaging applications.
This Spotlight provides a quick survey of methods used for patterning small structures using directed self-assembly (DSA). All flows currently considered are presented, along with the benefits and shortcomings of each, in an easy-to-follow guide for anyone doing patterning work. Materials needed and used in these processes are discussed.
This Spotlight discusses the generation of ultrashort pulses in three spectral regions: visible, deep-ultraviolet, and terahertz ranges. We explore a method to control the carrier-envelope phase (CEP) dynamics based on all-optical phase stabilization. The concepts presented here can be used to generate high-intensity, low-cycle laser optical fields with an exactly locked CEP. Such pulses are indispensable to the study of coherent x-ray and attosecond physics.
This Spotlight discusses photoacoustic imaging (PAI) techniques and highlights the importance of pulsed laser diodes (PLDs). The text introduces the basic principle, signal detection, and various implementations. Computed tomography systems and their instrumentation are also addressed. Other topics include alternative laser sources , high-pulse repetition rate, pulse duration, signal-to-noise ratio, and safety.
This Spotlight offers a perspective on the role of Monte Carlo simulation in the analysis and tolerancing of optical systems. The book concisely explores two overarching questions: (1) What principles can we adopt from a variety of statistical methods - such as the analysis of variance (ANOVA), "root sum of squares" (RSS), and Monte Carlo simulation - to analyze variability in complex optical systems? (2) When we assign perturbations to component variables (such as tilts and radii of curvatures) subject to arbitrary probability distributions, are the resulting distributions of system parameters (such as EFL, RMS spot size, and MTF) necessarily normal? These questions address the problem of analyzing and managing variability in modern product development, where many functions integrate to produce a complete instrument. By discussing key concepts from optics, multivariable calculus, and statistics, and applying them to two practical examples in modern technology, this book highlights the role Monte Carlo simulations play in the tolerancing of optical systems that comprise many components of variation.
This Spotlight presents the state-of-the-art of aerosol remote sensing, including remote sensing principles and satellite- and ground-based approaches. The mechanism and theories are introduced along with the component mixing rules, e.g., Maxwell-Garnett, Bruggeman, and volume-weighted average approaches. Recent advances in aerosol-component methods are discussed, focusing on composition schemes, inversion methods, and validation results. The final section looks at the remote sensing applications of atmospheric aerosol composition and species.