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Principles of biophotonics. Volume 2, Light emission, detection, and statistics /

This Volume 2 of Principles of Biophotonics continues to pour the foundation on which the next five volumes of optics and three volumes of methods will be built. While Volume 1 covered the mathematical apparatus to be used throughout the book, Volume 2 describes the emission, detection, and statisti...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Popescu, Gabriel, 1971- (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2020]
Colección:IPEM-IOP series in physics and engineering in medicine and biology.
IOP ebooks. 2020 collection.
Temas:
Acceso en línea:Texto completo

MARC

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100 1 |a Popescu, Gabriel,  |d 1971-  |e author. 
245 1 0 |a Principles of biophotonics.  |n Volume 2,  |p Light emission, detection, and statistics /  |c Gabriel Popescu. 
246 3 0 |a Light emission, detection, and statistics. 
264 1 |a Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) :  |b IOP Publishing,  |c [2020] 
300 |a 1 online resource (various pagings) :  |b illustrations (some color). 
336 |a text  |2 rdacontent 
337 |a electronic  |2 isbdmedia 
338 |a online resource  |2 rdacarrier 
490 1 |a IPEM-IOP series in physics and engineering in medicine and biology 
490 1 |a IOP ebooks. [2020 collection] 
500 |a "Version: 20191101"--Title page verso. 
504 |a Includes bibliographical references. 
505 0 |a 1. Electromagnetic fields -- 1.1. Regions of the electromagnetic spectrum -- 1.2. Spectral absorption of water -- 1.3. Spectral absorption of hemoglobin -- 1.4. Problems 
505 8 |a 2. Radiometric properties of light -- 2.1. Energy -- 2.2. Energy density -- 2.3. Power -- 2.4. Temporal power spectrum -- 2.5. Intensity : spatial power spectrum -- 2.6. Irradiance -- 2.7. Spectral irradiance -- 2.8. Radiance -- 2.9. Spectral radiance -- 2.10. Exitance -- 2.11. Spectral exitance -- 2.12. Problems 
505 8 |a 3. Photon-based radiometric quantities -- 3.1. Number of photons -- 3.2. Photon density -- 3.3. Photon flux -- 3.4. Photon temporal power spectrum -- 3.5. Photon intensity -- 3.6. Photon irradiance -- 3.7. Photon spectral irradiance -- 3.8. Photon radiance -- 3.9. Photon spectral radiance -- 3.10. Photon exitance -- 3.11. Photon spectral exitance -- 3.12. Problems 
505 8 |a 4. Photometric properties of light -- 4.1. Luminous energy -- 4.2. Luminous flux -- 4.3. Luminous energy density -- 4.4. Luminous intensity -- 4.5. Illuminance -- 4.6. Luminance -- 4.7. Problems 
505 8 |a 5. Fluorescence -- 5.1. Jablonski diagram -- 5.2. Emission spectra -- 5.3. Rate equations -- 5.4. Quantum yield -- 5.5. Fluorescence lifetime -- 5.6. Quenching -- 5.7. Problems 
505 8 |a 6. Black body radiation -- 6.1. Planck's radiation formula -- 6.2. Wien's displacement law -- 6.3. Stefan-Boltzmann law -- 6.4. Asymptotic behaviors of Planck's formula -- 6.5. Einstein's derivation of Planck's formula -- 6.6. Problems 
505 8 |a 7. LASER : light amplification by stimulated emission of radiation -- 7.1. Population inversion, optical resonator, and narrow band radiation -- 7.2. Gain -- 7.3. Spectral line broadening -- 7.4. Threshold for laser oscillation -- 7.5. Laser kinetics -- 7.6. Gain saturation -- 7.7. Problems 
505 8 |a 8. Classification of optical detectors -- 8.1. Waves and photons -- 8.2. Photon detectors -- 8.3. Thermal detectors -- 8.4. Problems 
505 8 |a 9. Statistics of optical detection -- 9.1. Probabilities -- 9.2. Continuous random variables -- 9.3. Moments of a distribution -- 9.4. Common probability distributions -- 9.5. Problems 
505 8 |a 10. Detection noise -- 10.1. Mechanisms of noise generation -- 10.2. Spatio-temporal noise description -- 10.3. Noise contributions -- 10.4. Problems 
505 8 |a 11. Figures of merit of optical detectors -- 11.1. Quantum efficiency -- 11.2. Responsivity -- 11.3. Signal to noise ratio -- 11.4. Saturation -- 11.5. Dynamic range -- 11.6. Noise-equivalent power -- 11.7. Detectivity -- 11.8. Gain -- 11.9. Dark current -- 11.10. Spatial and temporal sampling : aliasing -- 11.11. Problems 
505 8 |a 12. Semiconductor materials -- 12.1. Insulators and conductors -- 12.2. Covalent bonds in semiconductor crystals -- 12.3. Energy band structure -- 12.4. Carrier distribution -- 12.5. Doping -- 12.6. Electron-hole pair generation by absorption of light -- 12.7. P-N junction -- 12.8. Problems 
505 8 |a 13. Photon detectors -- 13.1. The p-n junction photodiode -- 13.2. Photoconductive detectors -- 13.3. Photoemission detectors -- 13.4. Problems 
505 8 |a 14. Thermal detectors -- 14.1. Principle of photothermal detection -- 14.2. Noise in thermal detectors -- 14.3. Bolometers -- 14.4. Pyroelectric detectors -- 14.5. Problems 
505 8 |a 15. Statistics of optical fields -- 15.1. Optical fields as random variables -- 15.2. Spatiotemporal correlation function -- 15.3. Ergodic hypothesis -- 15.4. Stationarity and statistical homogeneity -- 15.5. Wiener-Khintchine theorem -- 15.6. Spatial correlations of monochromatic light -- 15.7. Temporal correlations of plane waves -- 15.8. Spatially-dependent coherence time and temporally-dependent coherence area -- 15.9. Problems. 
520 3 |a This Volume 2 of Principles of Biophotonics continues to pour the foundation on which the next five volumes of optics and three volumes of methods will be built. While Volume 1 covered the mathematical apparatus to be used throughout the book, Volume 2 describes the emission, detection, and statistical representation of optical fields. The book starts by placing the visible spectrum in the context of the electromagnetic frequency range. This presentation stresses how thin of a sliver one normally calls the 'optical' spectrum. And, yet, so much can be accomplished within this narrow range of frequencies. To be able to describe properties of light with technical accuracy, the most common radiometric quantities that the reader is bound to encounter in subsequent volumes are introduced. Although the conversion to photon-based quantities is straightforward, it is presented explicitly, to avoid any confusion. For completeness, an analogy to the photometric quantities of light is drawn as well. Each chapter also contains a set of practice problems and additional references. Part of Series in Physics and Engineering in Medicine and Biology. 
521 |a Students, instructors, and professionals who are active at the interface between biology, medicine, and optics. 
530 |a Also available in print. 
538 |a Mode of access: World Wide Web. 
538 |a System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader. 
545 |a Gabriel Popescu is a Professor in Electrical and Computer Engineering, University of Illinois at Urbana-Champaign. He received his PhD in Optics in 2002 from the School of Optics/ CREOL (now the College of Optics and Photonics), University of Central Florida. He continued his training with the late Michael Feld at MIT, working as a postdoctoral associate. He joined Illinois in August 2007 where he directs the Quantitative Light Imaging Laboratory (QLI Lab) at the Beckman Institute for Advanced Science and Technology. Aside from Principles of Biophotonics, he has authored another book on quantitative phase imaging, edited another book on nanobiophotonics, authored 170 journal publications, 220 conference presentations, 32 patents, and given 220 lecture/plenary/invited talks. He founded Phi Optics, Inc., a start-up company that commercializes quantitative phase imaging technology. He is a Fellow of OSA and SPIE and Senior member of IEEE. 
588 0 |a Title from PDF title page (viewed on December 9, 2019). 
650 0 |a Biophotometry. 
650 0 |a Photonics  |x Industrial applications. 
650 0 |a Photonics  |x Therapeutic use. 
650 0 |a Biomedical engineering. 
650 1 2 |a Biomedical Engineering. 
650 1 2 |a Optical Phenomena. 
650 2 2 |a Light. 
650 2 2 |a Optical Imaging. 
650 2 2 |a Optics and Photonics  |x methods. 
650 7 |a Biomedical engineering.  |2 bicssc 
650 7 |a SCIENCE / Mechanics / Hydrodynamics.  |2 bisacsh 
710 2 |a Institute of Physics (Great Britain),  |e publisher. 
776 0 8 |i Print version:  |z 9780750316422 
830 0 |a IPEM-IOP series in physics and engineering in medicine and biology. 
830 0 |a IOP ebooks.  |p 2020 collection. 
856 4 0 |u https://iopscience.uam.elogim.com/book/978-0-7503-1644-6  |z Texto completo