Prof. Manuel Martínez-Corral
Full Professor at Univ de Valencia
SPIE Involvement:
Conference Chair | Author | Editor | Instructor
Area of Expertise:
3D Imaging and Display , 3D Microscopy
Websites:
Profile Summary

Manuel Martinez-Corral received the Ph. D. degree in Physics (Best Thesis Award) from the University of Valencia in 1993. Currently Full Professor of Optics at the University of Valencia, he co-leads the “3D Imaging and Display Laboratory”. He was elected Fellow of the SPIE in 2010 and Fellow of the OSA in 2017, respectively. His research interest includes resolution procedures in 3D scanning microscopy, and 3D imaging and display technologies. He has supervised on these topics 17 Ph. D. Theses (three honored with the Best Thesis Award), published over 120 technical articles in major journals (which received more than 3.000 citations), and pronounced a number of invited and keynote presentations in international meetings. He is also co-inventor of twelve patents, one of them supporting the creation of one Spin-off of the University of Valencia. He is has served in the Program Committee of a number of Conferences sponsored SPIE, OSA, IEEE, etc, and currently is co-chair of the Three-Dimensional Imaging, Visualization, and Display Conference within the SPIE meeting in Defense, Security, and Sensing. He is Topical Editor of the OSA journal Applied Optics.
Publications (63)

Proceedings Article | 15 June 2020 Paper
Proc. SPIE. 11521, Biomedical Imaging and Sensing Conference 2020
KEYWORDS: Microscopes, Sensors, Microscopy, 3D modeling, Relays, Deconvolution, Reconstruction algorithms, 3D displays, Molybdenum, 3D image processing

Proceedings Article | 18 May 2020 Paper
Proc. SPIE. 11396, Computational Imaging V
KEYWORDS: Microscopes, Microlens array, Cameras, Sensors, Microscopy, Image resolution, Relays, Deconvolution, Expectation maximization algorithms, 3D image processing

Proceedings Article | 22 April 2020 Presentation
Proc. SPIE. 11402, Three-Dimensional Imaging, Visualization, and Display 2020
KEYWORDS: Microscopes, Microlens array, Sensors, Microscopy, 3D modeling, Objectives, Microlens

Proceedings Article | 22 April 2020 Presentation
Proc. SPIE. 11402, Three-Dimensional Imaging, Visualization, and Display 2020
KEYWORDS: Microscopy, Reconstruction algorithms, Algorithm development, Optimization (mathematics)

Proceedings Article | 14 May 2019 Paper
Proc. SPIE. 10997, Three-Dimensional Imaging, Visualization, and Display 2019
KEYWORDS: Holograms, Holography, Digital holography, Imaging systems, Blood, Microscopy, Phase measurement

Showing 5 of 63 publications
Proceedings Volume Editor (11)

SPIE Conference Volume | 27 May 2020

SPIE Conference Volume | 17 August 2018

SPIE Conference Volume | 20 June 2017

SPIE Conference Volume | 25 July 2016

SPIE Conference Volume | 15 June 2015

Showing 5 of 11 publications
Conference Committee Involvement (20)
Three-Dimensional Imaging, Visualization, and Display 2020
27 April 2020 | Online Only, California, United States
Three-Dimensional Imaging, Visualization, and Display 2019
15 April 2019 | Baltimore, Maryland, United States
Three-Dimensional Imaging, Visualization, and Display 2018
16 April 2018 | Orlando, Florida, United States
Three-Dimensional Imaging, Visualization, and Display 2017
10 April 2017 | Anaheim, California, United States
Three-Dimensional Imaging, Visualization, and Display 2016
18 April 2016 | Baltimore, Maryland, United States
Showing 5 of 20 Conference Committees
Course Instructor
SC979: Fundamentals of Three-Dimensional Optical Microscopy
This course provides an introduction to the principles that govern the acquisition of 3D images with optical microscopes. Specifically, it provides attendees with practical knowledge to understand the limitations of conventional microscopes when imaging 3D samples, as well as the principles of different emerging microscopy techniques with optical-sectioning capacity The course will include three parts. In the first part, we describe the fundamentals of 2D imaging processes in conventional microscopes, and why they are not well adapted for imaging 3D samples. In the second part, we will focus on different optical-sectioning microscopy techniques, such as confocal, 4Pi, multi-photon, and structured illumination microscopy. In the third part, we will focus on emerging approaches, including one-shot 3D microscopes, digital holographic microscopes, etc. The attendee will benefit from a concise and realistic overview of microscopy procedures, which may help them to select the adequate microscope for various applications. The course will provide discussions of optical hardware and various practical applications of 3D optical microscopy. Also, discussions and examples will be presented on the benefits of 3D optical microscopy over conventional 2D optical microscopy.
SC1214: Fundamentals of 3D Imaging and 3D Displays
The course will review the following fundamentals which are necessary to understand, design, and analyze 3D imaging and display systems. The course helps the students to understand how 3D imaging works, what are the fundamentals, how to use optics to implement 3D displays, how to improve performance in 3D imaging systems and/or product lines and new product development programs, how to increase optical performance, or simply find new solutions to existing technological problems. Fundaments of Geometrical Optics: propagation of rays in transparent materials, refraction of rays in plane and spherical diopters, image formation with lenses, combination of lenses, aperture and field limitation, law of lenses: image position and magnification, examples and applications. Wave theory of image formation: the plane wave and the spherical waves, the wavefield as linear superposition of spherical waves, propagation of wavefields though converging lenses, waves through telecentric optical systems, image formation analyzed in terms of wave optics: the concepts of PSF, spatial resolution, OTF and frequency cut-off, light diffracted through periodic screens, examples and applications. Wave and ray theory of 3D optical capture and display systems such as plenoptic systems: capture of lightfield with an array of digital cameras: the synthetic aperture method, capture of lightfield with a plenoptic camera working in the 1.0 mode, capture of lightfield with a plenoptic camera working in the 2.0 mode, algorithms for the calculation of views and for the reconstruction in depth, examples and applications, implementation of synthetic-aperture setup, and implementation of a plenoptic camera.
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