First Page | Meta Content | |
---|---|---|
Document Date: 2010-04-27 15:49:34Open Document File Size: 864,26 KBShare Result on FacebookCityLas Vegas / Charlotte / Dallas / /CountryUnited States / /CurrencyUSD / / /FacilitySouthern Methodist University / Research Laboratory / /IndustryTermmultiaperture imaging / opaque paint / black acrylic paint / collaborative technology agreement / folded imaging architecture / real-time application / flat form factor imaging system / multiaperture imaging systems / computational imaging sensor / conventional imaging systems / multiaperture imaging system / computational imaging architecture utilizing micromirror / image simulation tool / computational imaging / infrared imaging systems / imaging / micromirror technology / reconstruction algorithm / generated using the image simulation tool / /OrganizationU.S. Air Force / Optical Society of America / Research Laboratory / Optical Society of America OCIS / United States Army / Southern Methodist University / Optical Society / Air Force / Department of Electrical Engineering / /PersonJoseph E. Ford / B. Gray / V / Rebecca Willett / Dennis Prather / M. P. Christensen / V / Robert Te Kolste / Caihua Chen / Robert Gibbons / Ronald A. Stack / Timothy Schulz / Rick L. Morrison / James Carriere / David Brady / Gonzalo Paez / Pedro Arguijo / Ravindra Athale / Nikos Pitsianis / David J. Brady / Dennis M. Healy / Mark A. Neifeld / Marija Strojnik Scholl / Eric J. Tremblay / /Positionrepresentative / candidate for manufacturing through molding / mpc@lyle.smu.edu *Corresponding author / /ProductB52 / Reconstruction Results A. Subimager Fabrication The injection / /ProvinceOrStateTexas / North Carolina / /Technologylaser / Optical Sensing / micromirror technology / DSR algorithm / simulation / reconstruction algorithm / C. Digital Superresolution Results The reconstruction algorithm / steering algorithm / /SocialTag |