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Quantitative phase microscopy and tomography : techniques using partially spatially coherent monochromatic light / Dalip Singh Mehta, Ankit Butola, Veena Singh.

By: Mehta, Dalip Singh [author.].
Contributor(s): Butola, Ankit [author.] | Singh, Veena (M. Tech. in laser technology) [author.] | Institute of Physics (Great Britain) [publisher.].
Material type: materialTypeLabelBookSeries: IOP (Series)Release 22: ; IOP series in advances in optics, photonics and optoelectronics: ; IOP ebooks2022 collection: Publisher: Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2022]Description: 1 online resource (various pagings) : illustrations (some color).Content type: text Media type: electronic Carrier type: online resourceISBN: 9780750339872; 9780750339865.Subject(s): Phase-contrast microscopy | Tomography | Optical physics | SCIENCE / Physics / Optics & LightAdditional physical formats: Print version:: No titleDDC classification: 502/.8/2 Online resources: Click here to access online Also available in print.
Contents:
1. Introduction -- 1.1. Bright field microscopy -- 1.2. Phase contrast microscopy -- 1.3. Quantitative phase microscopy -- 1.4. Coherence properties of laser light -- 1.5. Origin of speckles in imaging and microscopy -- 1.6. Effects of speckle on imaging and microscopy -- 1.7. Methods of generating partially spatially coherent light
2. Partially spatially coherent off-axis quantitative phase microscopy -- 2.1. Off-axis holographic phase microscopy -- 2.2. Partially spatially coherent off-axis quantitative phase microscopy -- 2.3. Image characteristics -- 2.4. Extraction of quantitative information using phase map
3. Partially spatially coherent common-path quantitative phase microscopy -- 3.1. Gabor (in-line) holography -- 3.2. Diffraction phase microscopy -- 3.3. Fourier phase microscopy -- 3.4. Lateral shearing interferometric phase microscopy -- 3.5. Fresnel bi-prism based interferometric phase microscopy -- 3.6. Spatial phase sensitivity -- 3.7. Temporal phase stability -- 3.8. Resolution of the system
4. Structured illumination quantitative phase microscopy -- 4.1. Diffraction-limited resolution of phase microscopy -- 4.2. Structured illumination schemes for phase microscopy -- 4.3. Common-path geometries for SIQPM -- 4.4. Phase reconstruction algorithms for SIPM
5. Multimodal on-chip nanoscopy and quantitative phase microscopy -- 5.1. Fluorescence imaging -- 5.2. Total internal reflections fluorescence microscopy -- 5.3. Super-resolution fluorescence imaging -- 5.4. Integrated on-chip nanoscopy and partially spatially coherent quantitative phase microscopy -- 5.5. Applications of integrated on-chip nanoscopy and quantitative phase microscopy
6. Longitudinal spatial coherence gated tomography using partially spatially coherent monochromatic light -- 6.1. Introduction to time-domain and frequency-domain optical coherence tomography -- 6.2. Axial-resolution in OCT systems -- 6.3. Dispersion effects in OCT -- 6.4. Concept of longitudinal spatial coherence -- 6.5. Longitudinal spatial coherence gated topography and tomography
7. Low-coherence (white light) interference microscopy with colour fringe analysis -- 7.1. Introduction to low coherence interferometry -- 7.2. Phase-shifting white light interference microscopy -- 7.3. Color fringe analysis -- 7.4. Quantitative information about biological samples
8. Artificial intelligence : a computational tool to interpret quantitative phase imaging -- 8.1. Introduction -- 8.2. Machine learning to understand QPI/need of machine learning and deep learning in phase microscopy -- 8.3. Practical prescription for machine learning in QPI -- 8.4. Outlook
9. Multi-spectral and hyper-spectral phase microscopy -- 9.1. Introduction -- 9.2. Multi-spectral phase microscopy -- 9.3. Hyper-spectral quantitative phase microscopy -- 9.4. Optical configurations of multi-spectral and hyper-spectral phase microscopy -- 9.5. Light sources for multi-spectral and hyper-spectral phase microscopy -- 9.6. Recording devices for multi-spectral and hyper-spectral phase microscopy -- 9.7. Algorithms for image reconstruction -- 9.8. Applications of multi-spectral and hyper-spectral phase microscopy -- 10. Conclusions and future prospects.
Abstract: This book develops and describes the most advanced QPM techniques and computational imaging techniques using partially spatially coherent monochromatic light rather than highly coherent lasers.
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"Version: 20221201"--Title page verso.

Includes bibliographical references.

1. Introduction -- 1.1. Bright field microscopy -- 1.2. Phase contrast microscopy -- 1.3. Quantitative phase microscopy -- 1.4. Coherence properties of laser light -- 1.5. Origin of speckles in imaging and microscopy -- 1.6. Effects of speckle on imaging and microscopy -- 1.7. Methods of generating partially spatially coherent light

2. Partially spatially coherent off-axis quantitative phase microscopy -- 2.1. Off-axis holographic phase microscopy -- 2.2. Partially spatially coherent off-axis quantitative phase microscopy -- 2.3. Image characteristics -- 2.4. Extraction of quantitative information using phase map

3. Partially spatially coherent common-path quantitative phase microscopy -- 3.1. Gabor (in-line) holography -- 3.2. Diffraction phase microscopy -- 3.3. Fourier phase microscopy -- 3.4. Lateral shearing interferometric phase microscopy -- 3.5. Fresnel bi-prism based interferometric phase microscopy -- 3.6. Spatial phase sensitivity -- 3.7. Temporal phase stability -- 3.8. Resolution of the system

4. Structured illumination quantitative phase microscopy -- 4.1. Diffraction-limited resolution of phase microscopy -- 4.2. Structured illumination schemes for phase microscopy -- 4.3. Common-path geometries for SIQPM -- 4.4. Phase reconstruction algorithms for SIPM

5. Multimodal on-chip nanoscopy and quantitative phase microscopy -- 5.1. Fluorescence imaging -- 5.2. Total internal reflections fluorescence microscopy -- 5.3. Super-resolution fluorescence imaging -- 5.4. Integrated on-chip nanoscopy and partially spatially coherent quantitative phase microscopy -- 5.5. Applications of integrated on-chip nanoscopy and quantitative phase microscopy

6. Longitudinal spatial coherence gated tomography using partially spatially coherent monochromatic light -- 6.1. Introduction to time-domain and frequency-domain optical coherence tomography -- 6.2. Axial-resolution in OCT systems -- 6.3. Dispersion effects in OCT -- 6.4. Concept of longitudinal spatial coherence -- 6.5. Longitudinal spatial coherence gated topography and tomography

7. Low-coherence (white light) interference microscopy with colour fringe analysis -- 7.1. Introduction to low coherence interferometry -- 7.2. Phase-shifting white light interference microscopy -- 7.3. Color fringe analysis -- 7.4. Quantitative information about biological samples

8. Artificial intelligence : a computational tool to interpret quantitative phase imaging -- 8.1. Introduction -- 8.2. Machine learning to understand QPI/need of machine learning and deep learning in phase microscopy -- 8.3. Practical prescription for machine learning in QPI -- 8.4. Outlook

9. Multi-spectral and hyper-spectral phase microscopy -- 9.1. Introduction -- 9.2. Multi-spectral phase microscopy -- 9.3. Hyper-spectral quantitative phase microscopy -- 9.4. Optical configurations of multi-spectral and hyper-spectral phase microscopy -- 9.5. Light sources for multi-spectral and hyper-spectral phase microscopy -- 9.6. Recording devices for multi-spectral and hyper-spectral phase microscopy -- 9.7. Algorithms for image reconstruction -- 9.8. Applications of multi-spectral and hyper-spectral phase microscopy -- 10. Conclusions and future prospects.

This book develops and describes the most advanced QPM techniques and computational imaging techniques using partially spatially coherent monochromatic light rather than highly coherent lasers.

Researcher's, doctoral and post-doctoral students working in the area of biomedical optics, bio-photonics, advance microscopy, holography and optical metrology.

Also available in print.

Mode of access: World Wide Web.

System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.

Dr. Dalip Singh Mehta is currently a Professor at the Department of Physics, Indian Institute of Technology Delhi.

Title from PDF title page (viewed on January 9, 2023).

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