Dr. Eustace L. Dereniak
at College of Optical Sciences Univ of Arizona
SPIE Involvement:
Awards Committee | Board of Directors | Executive Committee | Nominating Committee | Strategic Planning Committee | Symposia Committee | Fellow status | Conference Program Committee | Conference Chair | Symposium Chair | Conference Co-Chair | Track Chair | Author | Editor | Instructor
Area of Expertise:
Infrared Detectors , Imaging Polarimeters , Imaging Spectrometers
Profile Summary

Eustace L. Dereniak is a Professor of Optical Sciences and Electrical and Computer Engineering at the University of Arizona, Tucson, AZ. He is a co-author of several textbooks including Optical Radiation Detectors, Infrared Detectors and Systems, published by Wiley-Interscience, and Geometrical and Trigometrical Optics, published by Cambridge Press. He has written chapters in Imaging in Medicine, edited by S. Nudelman and D. Patton, related to research and development using thermograph instrumentation for the early detection of breast cancer. His publications also include over 100 authored or co-authored refereed articles. He is a Fellow of the SPIE and OSA, and a President of SPIE in 2012.

Dr. Dereniak received a BS in electrical engineering at Michigan Technological University, MS in Electrical Engineering from University of Michigan and a PhD in optics from the University of Arizona.

He has taught at West Point Military Academy on sabbatical as well as summer courses at the University of Michigan, New Mexico State University and University of Central Florida. He has also worked summer faculty positions at:

U.S. Air Force, Hanscom AFB, Massachusetts
University of Hawaii, Honolulu, Hawaii
U.S. Army, TACOM, Warren, Michigan
U.S. Air Force, AEDC, Tullahoma, Tennessee
U.S. Air Force, Elgin AFB, Ft Walton Beach, Forida
Publications (142)

Proc. SPIE. 9832, Laser Radar Technology and Applications XXI
KEYWORDS: Optical spheres, Detection and tracking algorithms, LIDAR, Sensors, Scanners, Laser scanners, Gaussian filters, Algorithm development, Panoramic photography, Spherical lenses

Proc. SPIE. 9853, Polarization: Measurement, Analysis, and Remote Sensing XII
KEYWORDS: Polarization, Scattering, Water, Photons, Light scattering, Laser scattering, Wave plates, Polarimetry, Ocean optics, Monte Carlo methods

PROCEEDINGS ARTICLE | September 1, 2015
Proc. SPIE. 9611, Imaging Spectrometry XX
KEYWORDS: Staring arrays, Hyperspectral imaging, Prisms, Imaging systems, Interferometers, Sensors, Calibration, Spectroscopy, Fourier transforms, Monochromators

Proc. SPIE. 9465, Laser Radar Technology and Applications XX; and Atmospheric Propagation XII
KEYWORDS: Optical spheres, Polarization, Fiber optic gyroscopes, Scattering, Particles, Photons, Light scattering, Poincaré sphere, Monte Carlo methods, Mie scattering

SPIE Conference Volume | November 19, 2014

PROCEEDINGS ARTICLE | September 5, 2014
Proc. SPIE. 9186, Fifty Years of Optical Sciences at The University of Arizona
KEYWORDS: Staring arrays, Infrared imaging, Polarization, Interferometers, Sensors, Spectrometers, Fourier transforms, Wave plates, Infrared radiation, Michelson interferometers

Showing 5 of 142 publications
Conference Committee Involvement (63)
Infrared Sensors, Devices, and Applications VIII
19 August 2018 | San Diego, California, United States
Infrared Sensors, Devices, and Applications VII
9 August 2017 | San Diego, California, United States
Algorithms and Technologies for Multispectral, Hyperspectral, and Ultraspectral Imagery XXIII
11 April 2017 | Anaheim, California, United States
Infrared Sensors, Devices, and Applications VI
31 August 2016 | San Diego, California, United States
Imaging Spectrometry XXI
29 August 2016 | San Diego, California, United States
Showing 5 of 63 published special sections
Course Instructor
SC152: Infrared Focal Plane Arrays
The course presents a fundamental understanding of two-dimensional arrays applied to detecting the infrared spectrum. The physics and electronics associated with 2-D infrared detection are stressed with special emphasis on the hybrid architecture unique to two-dimensional infrared arrays.
SC278: Infrared Detectors
This course will provide a broad and useful background on optical detectors, both photon and thermal, with a special emphasis placed on the infrared detectors. Discussion of optical detection will be stressed. The fundamentals of responsivity (Rl), noise equivalent power (NEPl) and specific detectivity (D*) will be discussed. These figures of merit will be extended to photon noise limited performance and Johnson noise limitations (RA product). Discussion of optical detector fundamentals will be stressed. To aid the attendee in selecting the proper detector choice, the detailed behavior of the more important IR detector materials will be described in detail. Newer technologies such as quantum well infrared photodetectors and blocked impurity bands as well as IR detectors will be covered briefly.
SC180: Imaging Polarimetry
This course covers imaging polarimeters from an instrumentation-design point of view. Basic polarization elements for the visible, mid-wave infrared, and long-wave infrared are described in terms of Mueller matrices and the Poincaré sphere. Polarization parameters such as the degree of polarization (DOP), the degree of linear polarization (DOLP) and the degree of circular polarization (DOCP) are explained in an imaging context. Emphasis is on imaging systems designed to detect polarized light in a 2-D image format. System concepts are discussed using a Stokes-parameter (s0,s1,s2,s3) image. Imaging-polarimeter systems design, pixel registration, and signal to noise ratios are explored. Temporal artifacts, characterization and calibration techniques are defined.
SC153: Imaging Spectrometry
This course covers the design of imaging spectrometers, from instrumentation to data exploitation. Emphasis is placed on scanning systems in recognition of their prevalence. All system concepts are discussed from the perspective of acquiring an image cube. Example systems (AVIRIS, HYDICE, etc.) illustrate current design practices. Noise-equivalent spectral radiance (NESR) will be introduced and explained. In addition, data exploitation is discussed and examples demonstrated.
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