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A detailed and comprehensive account of the engineering of the world’s first nonimaging Fresnel lens solar concentrator. The book closes a gap in solar concentrator design, and describes nonimaging refractive optics and its numerical mathematics. The book shows the reader how to find his or her own optical solution using the rules and methodologies covering the design and the assessment of the nonimaging lens.
From the early ground and polished prism facets of glass lighthouse Fresnel lenses to modern microreplicated flexible Fresnel lenses for solar concentrators, new applications of prismatic optical components for light control are constantly being developed. In addition, innovations utilizing single and compound prismatic and reflective optical components are emerging in the fields of metrology, polarization control, projection systems, illumination, and display lighting, among others. State-of-the-art multilayer optical coatings have enabled novel prism and reflector geometries to be developed for specific functions. The techniques and examples presented in this book should provide a good background to analyze, evaluate, and understand prismatic and reflector applications described in the literature. The material in this book may inspire readers themselves to create novel and useful devices utilizing prismatic and reflective optical components.
From its inception nearly 30 years ago, the optical subdiscipline now referred to as nonimaging optics, has experienced dramatic growth. The term nonimaging optics is concerned with applications where imaging formation is not important but where effective and efficient collection , concentration, transport and distribution of light energy is - i.e. solar energy conversion, signal detection, illumination optics, measurement and testing. This book will incorporate the substantial developments of the past decade in this field.* Includes all substantial developments of the past decade in the rapidly moving field of nonimaging optics* The only authoritative reference on nonimaging optics, from the leader in the field
LED Lighting is a self-contained and introductory-level book featuring a blend of theory and applications that thoroughly covers this important interdisciplinary area. Building on the underlying fields of optics, photonics, and vision science, it comprises four parts. PART I is devoted to fundamentals. The behavior of light is described in terms of rays, waves, and photons. Each of these approaches is best suited to a particular set of applications. The properties of blackbody radiation, thermal light, and incandescent light are derived and explained. The essentials of semiconductor physics are set forth, including the operation of junctions and heterojunctions, quantum wells and quantum dots, and organic and perovskite semiconductors. PART II deals with the generation of light in semiconductors, and details the operation and properties of III-V semiconductor devices (MQWLEDs and μLEDs), quantum-dot devices (QLEDs & WOLEDs), organic semiconductor devices (OLEDs, SMOLEDs, PLEDs, & WOLEDs), and perovskite devices (PeLEDs, PPeLEDs, QPeLEDs, & PeWLEDs). PART III focuses on vision and the perception of color, as well as on colorimetry. It delineates radiometric and photometric quantities as well as efficacy and efficiency measures. It relays the significance of metrics often encountered in LED lighting, including the color rendering index (CRI), color temperature (CT), correlated color temperature (CCT), and chromaticity diagram. PART IV is devoted to LED lighting, focusing on its history and salutary features, and on how this modern form of illumination is deployed. It describes the principal components used in LED lighting, including white phosphor-conversion LEDs, chip-on-board (COB) devices, color-mixing LEDs, hybrid devices, LED filaments, retrofit LED lamps, LED luminaires, and OLED light panels. It concludes with a discussion of smart lighting and connected lighting. Each chapter contains highlighted equations, color-coded figures, practical examples, and reading lists.
"The Field Guide to Solar Optics attempts to consolidate and summarize optical topics in solar technologies and engineering that are dispersed throughout literature. The field guide also attempts to clarify topics and terms that could be confusing or at times misused. As with any technology area, optics related to solar technologies can be a wide field. The topics selected for this field guide are ones that are frequently encountered in solar engineering and research for energy harvesting, particularly for electricity generation. Therefore, the topics selected are slanted towards solar thermal or commonly called concentrating solar power. The first section of the field guide provides background on energy needs and usage and where solar technologies fit into the energy mix. The next section covers properties of the sun and develop understandings for solar energy collection. The third section introduces optical properties, concepts, and basic components. In the fourth section, the various optical systems used in solar engineering are described. In solar, optical systems used for solar energy collection is commonly referred to as collectors (e.g., collector field). This term is used frequently in this field guide. Another term commonly used for solar collectors is non-imaging optics. The next section introduces concepts for characterizing optical components/systems and analysis approaches. Lastly, measurement tools commonly used in solar engineering and research are described. The fundamentals of the topics are provided. Providing methods or approaches to designs was not the goal of the field guide. However, the fundamental understanding can be extended and used for design of components and systems"--
This second edition of Principles of Solar Engineering covers the latest developments in a broad range of topics of interest to students and professionals interested in solar energy applications. With the scientific fundamentals included, the book covers important areas such as heating and cooling, passive solar applications, detoxification and biomass energy conversion. This comprehensive textbook provides examples of methods of solar engineering from around the world and includes examples, solutions and data applicable to international solar energy issues. A solutions manual is available to qualified instructors.
This comprehensive reference provides a practical, fully illustrated guide to design, specification, and application of state-of-the-art lighting, from the fundamentals of illumination to hands-on application. The full scope of light sources is examined and basic design methods for both indoor and outdoor lighting are presented, along with optimum application strategies for merchandise, offices, industrial settings, floodlighting, parking lots and street lighting. The second edition features a new chapter on skylights for industrial buildings, covering layout parameters and daylight availability calculations used to predict skylight performance. The chapter on lighting retrofits has been revised to emphasize methods for analyzing potential retrofits, examining how retrofit results can be predicted, how to evaluate retrofit proposals, and how to avoid common mistakes. Lighting maintenance, as well as the economics of lighting design, including life cycle cost analysis, are also covered.
This introductory text is a reader friendly treatment of geometrical and physical optics emphasizing problems and solved examples with detailed analysis and helpful commentary. The authors are seasoned educators with decades of experience teaching optics. Their approach is to gradually present mathematics explaining the physical concepts. It covers ray tracing to the wave nature of light, and introduces Maxwell’s equations in an organic fashion. The text then moves on to explains how to analyze simple optical systems such as spectacles for improving vision, microscopes, and telescopes, while also being exposed to contemporary research topics. Ajawad I. Haija is a professor of physics at Indiana University of Pennsylvania. M. Z. Numan is professor and chair of the department of physics at Indiana University of Pennsylvania. W. Larry Freeman is Emeritus Professor of Physics at Indiana University of Pennsylvania.
Humans receive the vast majority of sensory perception through the eyes and ears. This non-technical book examines the everyday physics behind hearing and vision to help readers understand more about themselves and their physical environment. It begins wit
Infused with more than 500 tables and figures, this reference clearly illustrates the intricacies of optical system design and evaluation and considers key aspects of component selection, optimization, and integration for the development of effective optical apparatus. The book provides a much-needed update on the vanguard in the field with vivid e