Contracts
Avalanche Photodiodes and Photoreceivers |
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Ultra Sensitive Detector, BAA AL 2005-01 |
AFRL #FA8632-05-C-2456 |
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Program Goal: To develop the design of a sub-nanosecond response APD focal plane array (FPA) receiver in which each APD unit cell is capable of sensing single photons, measuring their time of flight to an accuracy of 500 ps and with 21 bits of temporal dynamic range. Development of Voxtel’s multi-stage APD design began under this program. The ROIC was designed to operate at 10,000 FPS, sampling 128 pulse returns per frame. |
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Airborne Laser Detector Tech. (ADET), BAA AL2003-01 |
AFRL #F33657-03-C-2043 |
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Program Goal:To support airborne laser (ABL) sensor missions such as active tracking, wavefront sensing, laser ranging, imaging, and scoring, by designing a 32×32 APD, with 1.0 to 1.7 -µm sensitivity, 10,000 FPS operation, NEI of 6 photons, and 1-nsec pulse arrival temporal resolution… |
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Solid-State LIDAR Chip |
NSWC #N00178-06-C-3024 |
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Program Goal: To fabricate and qualify a Solid-State Imaging LIDAR for integration with the AN/AES-1 (ALMDS) and AN/AQS-20A mine detection systems. |
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NIR Photon Counting APD |
NIST #SB1341-02-C-0015 |
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Program Goal: To develop a high-speed, large-area, single-photon sensitive Geiger APDs and active quenching circuits for measuring the polarization state of entangled photons. |
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Ultra-Low-Noise, High-Bandwidth, 1550 nm HgCdTe APD |
NASA #NNG05CA28C |
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Program Goal: To enable deep space laser communications, by fabricating a sub-nsec response, single-photon- sensitive linear mode low-noise, large-area HgCdTe APD photoreceiver, including low-noise amplification integrated circuit. |
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Phase II Radiation Hard, High Precision, Agile Star Tracker |
MDA #W9113M-07-C-0155 |
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Program Goal: To fabricate and demonstrate a 2K x 2K star tracker FPA, |
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ABL (Airborne Laser) Detection Sensor Improvements |
MDA #HQ00006-07-C-7777 |
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Program Goal: To develop an upgrade to the ABL, a single photon sensitive ranging camera. |
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HgCdTe Linear Mode APD |
NASA #NNG04CA94C |
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Program Goal: To develop the design of a SWIR sensitive high data rate, large-area (> 1-mm) single-photon sensitive, photon-number-discriminating APD receiver without Geiger mode operation. |
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Phase II Single Photon Sensitive HgCdTe Avalanche Photodiode Detector |
NASA #NNX07CA62P |
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Program Goal: To demonstrated and deliver to NASA a no excess noise, single photon sensitive, HgCdTe APD receiver for use in MWIR space communications systems and NASA LIDAR systems |
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Adaptive Multiwaveform Laser Ranging and Detection (LADAR) |
AFRL #FA8750-07-C-0173 |
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Program Goal: To demonstrate the effectiveness of encoded laser waveforms and APD receivers for strategic laser radar systems |
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Time-Resolved, X-Ray Photon Detector Array |
DOE #DE-FG02-07ER84759 |
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Program Goal: To develop large area silicon APD arrays to measure and |
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Large Area, Sold State Photomultiplier Array for Cherenkov Calorimetry |
DOE #DE-FG02-07ER84918 |
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Program Goal: To develop large area Geiger mode silicon APD arrays to |
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High ohm Resolution, 15-micron thin, Pixellated, SOI CMOS Vertex Sensor |
DOE #DE-FG02-07ER84919 |
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Program Goal: To Develop thin, back-illuminated SOI CMOS imager that records the amplitude and time of arrival of energetic particles from Vertex detectors such as for the International Linear Collider (ILC) |
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High Efficiency, High Speed Gamma Ray Detectors |
DOE #DE-FG02-07ER84759 |
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Program Goal: To develop arrays of silicon APDs for detecting blue scintillators |
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Phase II Enhancement Uncooled, Long-Life Wavefront/Tracking Sensor |
SMDC #W9113M-06-C-0126 |
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Program Goal:To Demonstrate prototype impact ionization engineered Linear Mode InGaAs APD arrays to replace the EBCCD cameras used on the AB1. |
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Phase II Enhanced Focal Plane Array Technology |
AFRL #FA9200-06-C-0322 |
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Program Goal: To developing Germanium arrays for high power laser imaging and NIR Wavefront sensing. |
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Enhanced Focal Plane Array |
AFRL #FA9200-05-C-0180 |
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Program Goal: To develop a NIR-sensitive, high current capacity, NIR, 2048×2048 FPA to be used for radiometric testing of high energy lasers. |
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Uncooled, Long-Life Wavefront/Tracking Sensor |
AFRL #FA9453-05-M-0066 |
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Program Goal: (as a precursor of SMDC W9113M-06-C0126 above) The goal was to develop APD-based FPAs as a more reliable alternative to the electron-bombarded charge-coupled devices (EBCCDs) that are presently used. |
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Improved Reliability EBCCD Sensors |
AFRL #F29601-03-M-0249 |
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Program Goal: To develop the back-thinning and surface passivation techniques necessary to produce high electron-bombarded silicon gain CMOS sensors that use commercial CMOS processes, but that dispense with the expensive and unreliable back-end processing commonly used to make back-thinned sensors. |
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Highly Stable, Large Format EUV Imager |
NASA #NNG04CA63C |
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Program Goal: To design a back-illuminated CMOS imager with improved EUV sensitivity and superior back-surface stability. |
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Optical Sensors for Tracking and Discrimination of Multiple Targets |
AFRL# FA9453-04-M-0265 |
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Program Goal: Voxtel developed space active tracking, the design of a deeply-depleted CMOS-based focal plane array. Features include improved 1030 nm and 1064 nm response, random, and non-destructive readout. |
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Back-Illuminated CMOS Detector Arrays |
NAVY #N00014-06-M-0089 |
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Program Goal: To develop a back-thinning process for CMOS imagers, for applications such as missile warning and beam riding. |
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Radiation Hard, High Precision, Agile Star Tracker |
SMDC #W9113M-06-C-0094 |
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Program Goal: To develop a rad-hard star tracker imager for space applications such as STSS. |
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SOI CMOS Star Tracker |
DTRA# DTRA01-02-P-0185 |
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Program Goal: To improve navigation in the harsh space radiation environments, Voxtel designed and simulated a novel rad-hard CMOS Star Tracker with radiation mitigation circuitry. |
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High Speed, Direct-Electron Microscopy Detector Array |
DOE# DE-FG02-06ER84405 |
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Program Goal: To develop a CMOS imaging array for direct-electron imaging in electron microscopes – eliminating phosphor. |
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Improved Vertex Focal Plane Array for Linear Colliders |
DOE #DE-FG02-06ER84489 |
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Program Goal: To develop a thin (15 micron) back-illuminated sensor, with time of arrival statistics to improve pulse pile in the planned ILC. |
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Ultra Sensitive Detector |
MDA# FA 8632-05-C-2456 |
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Program Goal: To develop a novel single photon sensitive InAlGaAs APD array and readout integrated circuit for laser ranging, pulse discrimination, and range time sampling. |
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Ultra-compact Low-Power NIR Flash LADAR Receiver |
NASA #NNG06LA37C |
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Revolutionary Photoreceivers |
AFRL# FA-8750-04-C-0152 |
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Program Goal: To Develop a novel, PbSe and PbSe hybrid quantum dot nanocrystal quantum dot – conductive polymer photodetector to be integrated into silicon waveguides for high speed, low cost distributed phased-array ladar receivers. |
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Innovative Techniques for Missile Defense |
SMDC# W9113M-04-P-0052 |
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Program Goal: To develop a SWIR “linear mode,†HgCdTe APD LADAR receiver, which achieves single photon signal amplitude sampling and high bandwidth without the deleterious effects of Geiger operation. |
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High Performance Geiger-mode 1.06 micron APD array |
SMDC #W911M-04-C-0103 |
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Program Goal: To develop a 32×32 array of single photon sensitive Geiger Mode NIR-sensitive InGaAs APD with low noise and high probability of detection |
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Kirtland Tracking |
AFRL #FA9453-04-M-0265 |
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Program Goal: To develop the design of a1024 x 1024 element NIR imagery for wavefront sensing. |
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Nanotechnology |
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High Efficiency, Engineered Nanomaterials for Thermoelectric Applications |
NASA #NNM06AA41C |
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Program Goal: To develop high thermoelectric figure-of-merit (ZT) nanocrystal quantum dot (NQD) thermoelectric (TE) materials. |
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Multifunctional Nanoparticles for Tracking Material |
ARMY #W911NF-06-C-0121 |
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Program Goal: To develop a security ink undetected by the naked eye |
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Nanostructured Materials with Improved Thermoelectric Properties |
NSF OII-0611239 |
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Program Goal: To develop a thermoelectric cooler based on colloidal quantum dot materials. |
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Binary Multi-Taggant System for Unique Target ID |
NAVY #N00014-06-M0332 |
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Program Goal: To develop a quantum dot taggant that is stimulated by non-solar radiation and is invisible to the human eye. |
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Next Generation Architecture for Night Vision Imaging |
AFRL #FA8650-05-C-0041, FA 8650-06-M-6672 |
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Program Goal: To develop the design of a flexible integrated quantum dot, organic SWIR detector, readout electronics, and display, which represents the future of night vision devices. |
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Phase II Engineered Nanomaterials for Thermoelectric Applications |
NASA# NNM07AA27C |
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Program Goal: To develop a three-dimensional, quantum-confined solids |
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EO Systems |
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ADS Dual-Band IR Radiometer |
USMC #M67854-04-C-6000 & M67854-02-C-1097 |
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Program Goal: To develop and fabricate, in a two-phase program, a highly accurate, two-color (MWIR & LWIR) ratio radiometer for the Active Denial System (ADS). The system is capable of measuring 1°C absolute temperature accuracy over a variety of atmospheric conditions. |
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Future Night Vision System |
AFRL #FA8650-05-C-6532 & FA8650-04-M-6484 |
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Program Goal: To developing, In support of the Joint Strike Fighter program, a helmet-mounted solid-state wide field-of-view (100 degree) night vision goggle with visible and NIR response that is well-matched to the night sky radiation. |
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LADAR Spectro-polarimeter |
AFRL #F08630-02-C-0052 |
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Program Goal: To design and simulate the performance of a LADAR with an active spectropolarimetric capability that aids in the detection and identification of remote objects. |
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3-D LADAR Polarimeter |
AFRL #F19628-03-C-0108 |
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Program Goal: To design and simulate the performance of a Stokes-vector LADAR polarimeter. |
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