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Multi-dimensional Imaging

Book Description

Provides a broad overview of advanced multidimensional imaging systems with contributions from leading researchers in the field

Multi-dimensional Imaging takes the reader from the introductory concepts through to the latest applications of these techniques. Split into 3 parts covering 3D image capture, processing, visualization and display, using 1) a Multi-View Approach and 2.) a Holographic Approach, followed by a 3rd part addressing other 3D systems approaches, applications and signal processing for advanced 3D imaging. This book describes recent developments, as well as the prospects and challenges in advances in imaging sciences and engineering such as 3D image sensing, 3D holographic imaging, imaging applications for bio-photonics and 3D image recognition. Advanced imaging systems incorporate knowledge from various fields. It is a complex technology that combines physics, optics, signal processing, and image capture techniques.

  • Provides a broad overview of advanced multidimensional imaging systems with contributions from leading researchers in the field.

  • Integrates the background, introductory material with new advances in 3D imaging and applications.

  • Covers the most recent technologies such as high speed digital holography, compressive sensing, real-time 3D integral imaging, 3D TV, photon counting imaging.

  • To be available as an enhanced ebook with added functionality of colour films showing the effects of advanced 3D applications such as 3D microscopy, 3D biomedical imaging and 3D for security and defense applications.

  • Acts as a single source reference to the rapidly developing field of 3D imaging technology.

  • Provides supplementary material on a companion website including video clips, examples, numerical simulations, and experimental results to show the theoretical concepts.

  • With contributions from leading researchers from across these fields, Multi-dimensional Imaging is a comprehensive reference for the imaging technology research community.

    Table of Contents

    1. Cover
    2. Title Page
    3. Copyright
    4. Dedication
    5. About the Editors
    6. List of Contributors
    7. Preface
    8. Acknowledgments
    9. Part One: Multi-Dimensional Digital Holographic Techniques
    10. Chapter 1: Parallel Phase-Shifting Digital Holography
      1. 1.1 Chapter Overview
      2. 1.2 Introduction
      3. 1.3 Digital Holography and Phase-Shifting Digital Holography
      4. 1.4 Parallel Phase-Shifting Digital Holography
      5. 1.5 Experimental Demonstration of Parallel Phase-Shifting Digital Holography
      6. 1.6 High-Speed Parallel Phase-Shifting Digital Holography System
      7. 1.7 Single-Shot Femtosecond-Pulsed Parallel Phase-Shifting Digital Holography System
      8. 1.8 Portable Parallel Phase-Shifting Digital Holography System
      9. 1.9 Functional Extension of Parallel Phase-Shifting Digital Holography
      10. 1.10 Prospects and Conclusion
      11. Acknowledgments
      12. References
    11. Chapter 2: Imaging and Display of Human Size Scenes by Long Wavelength Digital Holography
      1. 2.1 Introduction
      2. 2.2 Digital Holography Principles
      3. 2.3 Infrared Digital Holography
      4. 2.4 Latest Achievements in IRDH
      5. 2.5 Conclusion
      6. References
    12. Chapter 3: Digital Hologram Processing in On-Axis Holography
      1. 3.1 Introduction
      2. 3.2 Model of Hologram Image Formation
      3. 3.3 DH Reconstruction Based on Back Propagation
      4. 3.4 Hologram Reconstruction Formulated as an Inverse Problem
      5. 3.5 Estimation of Accuracy
      6. 3.6 Fast Processing Algorithms
      7. 3.7 Conclusion
      8. References
    13. Chapter 4: Multi-dimensional Imaging by Compressive Digital Holography
      1. 4.1 Introduction
      2. 4.2 Compressive Sensing Preliminaries
      3. 4.3 Conditions for Accurate Reconstruction of Compressive Digital Holographic Sensing
      4. 4.4 Applications of Compressive Digital Holographic Sensing
      5. 4.5 Conclusion
      6. Acknowledgments
      7. References
    14. Chapter 5: Dispersion Compensation in Holograms Reconstructed by Femtosecond Light Pulses
      1. 5.1 Introduction
      2. 5.2 Fundamental Features of the DCM
      3. 5.3 Holographic Applications of the DCM with Ultrafast Light Pulses
      4. 5.4 Conclusion
      5. Acknowledgments
      6. References
    15. Part Two: Biomedical Applications and Microscopy
    16. Chapter 6: Advanced Digital Holographic Microscopy for Life Science Applications
      1. 6.1 Introduction
      2. 6.2 DHM Configurations
      3. 6.3 Automated 3D Holographic Analysis
      4. 6.4 Applications
      5. 6.5 Conclusion
      6. Acknowledgments
      7. References
    17. Chapter 7: Programmable Microscopy
      1. 7.1 Introduction
      2. 7.2 Optical Design Considerations and Some Typical Setups
      3. 7.3 Liquid Crystal Spatial Light Modulator
      4. 7.4 Aberration Correction
      5. 7.5 Phase Contrast Imaging
      6. 7.6 Stereo Microscopy
      7. 7.7 Conclusion
      8. References
    18. Chapter 8: Holographic Three-Dimensional Measurement of an Optically Trapped Nanoparticle
      1. 8.1 Introduction
      2. 8.2 Experimental Setup
      3. 8.3 Experimental Results of 3D Position Measurement of Nanoparticles
      4. 8.4 Twilight Field Technique for Holographic Position Detection of Nanoparticles
      5. 8.5 Conclusion
      6. References
    19. Chapter 9: Digital Holographic Microscopy: A New Imaging Technique to Quantitatively Explore Cell Dynamics with Nanometer Sensitivity
      1. 9.1 Chapter Overview
      2. 9.2 Introduction
      3. 9.3 Holographic Techniques
      4. 9.4 Cell Imaging with Digital Holographic Quantitative Phase Microscopy
      5. 9.5 Future Issues
      6. Acknowledgments
      7. References
    20. Chapter 10: Super Resolved Holographic Configurations
      1. 10.1 Introduction
      2. 10.2 Digital Holography
      3. 10.3 Metal Nanoparticles
      4. 10.4 Resolution Enhancement in Digital Holography
      5. 10.5 Field of View Enhancement in Digital Holography
      6. 10.6 Eliminating the DC Term and the Twin Images
      7. 10.7 Additional Applications
      8. References
    21. Part Three: Multi-Dimensional Imaging and Display
    22. Chapter 11: Three-Dimensional Integral Imaging and Display
      1. 11.1 Introduction
      2. 11.2 Basic Theory
      3. 11.3 The Plenoptic Function
      4. 11.4 Methods for the Capture of the Plenoptic Field
      5. 11.5 Walking in Plenoptic Space
      6. 11.6 Reconstruction of Intensity Distribution in Different Depth Planes
      7. 11.7 Implementation of the Integral Imaging Display Device
      8. 11.8 Conclusion
      9. Acknowledgments
      10. References
    23. Chapter 12: Image Formats of Various 3-D Displays
      1. 12.1 Chapter Overview
      2. 12.2 Introduction
      3. 12.3 Multiplexing Schemes
      4. 12.4 Image Formats for 3-D Imaging
      5. References
    24. Chapter 13: Ray-based and Wavefront-based 3D Representations for Holographic Displays
      1. 13.1 Introduction
      2. 13.2 Ray-based and Wavefront-based 3D Displays
      3. 13.3 Conversion between Ray-based and Wavefront 3D Representations
      4. 13.4 Hologram Printer Based on a Full-Parallax Holographic Stereogram
      5. 13.5 Computational Holography Using a Ray-Sampling Plane
      6. 13.6 Occlusion Culling for Computational Holography Using the Ray-Sampling Plane
      7. 13.7 Scanning Vertical Camera Array for Computational Holography
      8. 13.8 Conclusion and Future Issues
      9. Acknowledgments
      10. References
    25. Chapter 14: Rigorous Diffraction Theory for 360° Computer-Generated Holograms
      1. 14.1 Introduction
      2. 14.2 Three-Dimensional Object and Its Diffracted Wavefront
      3. 14.3 Point-Spread Function Approach for Spherical Holography
      4. 14.4 Rigorous Point-Spread Function Approach
      5. 14.5 Conclusion
      6. References
    26. Part Four: Spectral and Polarimetric Imaging
    27. Chapter 15: High-Speed 3D Spectral Imaging with Stimulated Raman Scattering
      1. 15.1 Introduction
      2. 15.2 Principles and Advantages of SRS Microscopy
      3. 15.3 Spectral Imaging with SRS
      4. 15.4 High-Speed Spectral Imaging
      5. 15.5 Summary
      6. Acknowledgments
      7. References
    28. Chapter 16: Spectropolarimetric Imaging Techniques with Compressive Sensing
      1. 16.1 Chapter Overview
      2. 16.2 Single-Pixel Imaging and Compressive Sensing
      3. 16.3 Single-Pixel Polarimetric Imaging
      4. 16.4 Single-Pixel Multispectral Imaging
      5. 16.5 Single-Pixel Spectropolarimetric Imaging
      6. 16.6 Conclusion
      7. Acknowledgments
      8. References
    29. Chapter 17: Passive Polarimetric Imaging
      1. 17.1 Introduction
      2. 17.2 Representations of Polarized Light
      3. 17.3 Polarized Reflection and Emission
      4. 17.4 Atmospheric Contributions to Polarimetric Signatures
      5. 17.5 Data Reduction Matrix Analysis of Modulated Polarimeters
      6. 17.6 Fourier Domain Analysis of Modulated Polarimeters
      7. 17.7 Radiometric and Polarimetric Calibration
      8. 17.8 Polarimetric Target Detection
      9. References
    30. Index
    31. End User License Agreement