Next Generation Imaging Detectors Could Enhance Space Missions
Rochester Institute of Technology and the University of Rochester recently won $847,000 from NASA’s Astronomy Physics Research and Analysis program to build and test a detector that will capture sharper images and consume less power than technology currently in use.
The new imaging sensor, which will function at wavelengths spanning from ultraviolet to mid-infrared, will be able to operate reliably in the harsh radiation environment of space.
“These benefits will lead to lower mission cost and greater scientific productivity,” says Donald Figer, director of the Rochester Imaging Detector Laboratory at RIT and lead scientist on the project. The team also includes Zoran Ninkov from RIT and Zeljko Ignjatovic from the University of Rochester.
The new detector is based on a technology created by Ignjatovic and his colleagues at the UR. It will shrink the required hardware on NASA planetary missions from the size of a crate weighing tens of pounds to a tiny thumb-sized chip. It also will enhance images captured by ground telescopes that will rival those from orbiting telescopes, like the Hubble Space Telescope.
Ignjatovic’s chip integrates an analog-to-digital converter at each pixel in a sensor. “Previous attempts to do this on-pixel conversion have required far too many transistors, leaving too little area to collect light,” says Ignjatovic.
“First tests on the chip show that it uses 50 times less power than the industry’s current best, which is especially helpful on deep-space missions where energy is precious.”
Despite the chip’s low power consumption and sensitivity, it is surprisingly resistant to the radiation noise of space. Since each pixel converts the signal from analog to digital before moving it off-chip, the signal is digital and clear before it has a chance to travel and degrade.
Coatings applied to the light sensitive portion of the sensor will optimize the technology and the ability to detect a range of wavelengths. RIT’s Ninkov will explore techniques for bonding the coating to the delicate circuit using industrial microwave ovens. Further testing of the overall system will determine how the sensors hold up in cryogenic environments where the device is cooled to very low temperatures, imitating conditions in space.
In addition to astronomical applications, the detector could improve biomedical imaging devices used in emergency rooms or on battlefields. The technology could aid in homeland security surveillance efforts to watch the nation’s borders. Likewise, military applications could adopt the detector for use as airborne or space-based lasers designed to shoot down missiles aimed at the United States.
Figer was recruited by RIT’s Chester F. Carlson Center for Imaging Science through a faculty development program grant awarded by the New York State Office of Science, Technology and Academic Research (NYSTAR). The grant provides interim state assistance to help attract distinguished faculty throughout the world to New York’s academic research centers, and to retain leading researchers already in New York Institutions of Higher Education.
“In the first year of the NYSTAR award, we’re landing this anchor project for our program,” Figer says. “With this project, we will establish the capability to develop imaging sensors for multidisciplinary applications, an important objective in becoming an internationally leading laboratory, and in leveraging cutting-edge technologies for the benefit of regional industry.”
To speak to Donald Figer, contact Susan Gawlowicz at (585) 475-5061 or firstname.lastname@example.org.
April 19, 2019
RIT professor created simulation that could help treat heart patients
WROC-TV features Elizabeth Cherry, associate professor and director of the mathematical modeling program.
April 18, 2019
Student Spotlight: Participating in the ASCE Concrete Canoe competition
Meet Brady Smith, a fourth-year civil engineering technology student and captain of this year’s Concrete Canoe team.
April 17, 2019
Imagine RIT Preview: Virtual Bugs
When the Seneca Park Zoo Society needed a way to create detailed 3D computer models of rare insects from Madagascar, they turned to RIT’s imaging science program for help. A multidisciplinary team of first-year students designed and built a new system to tackle the problem and will showcase the final product at the Imagine RIT festival.
April 16, 2019
Rochester community invited to learn about star constellations at RIT Observatory April 22
The Rochester Institute of Technology Observatory is hosting an open house to teach members of the Rochester community how to identify constellations, the patterns of stars in the sky that mark the figures of heroes, monsters, and characters from ancient myths.