ASU graduate student to build infrared camera for nanosatelliteJanuary 23rd, 2013 in Astronomy & Space / Space Exploration
ASU/SESE graduate student Michael Veto has begun work on an infrared and visible camera system that will fly as part of the Prox-1 satellite payload. The infrared part of the camera (in breadboard form) lies to the left of the laptop. Credit: Arizona State University
Michael Veto, a third-year graduate student in the School of Earth and Space Exploration (SESE) at Arizona State University (ASU), has been chosen to build an infrared and visible light camera system that will launch on a space satellite. Veto, who earned his undergraduate degree in aerospace engineering at ASU, is a geology Ph.D. student of Philip Christensen, Regents' Professor of Geological Sciences in ASU's College of Liberal Arts and Sciences.
The new camera will play a central role in the payload for the Prox-1 satellite, which won the seventh University Nanosat Program (UNP) competition, sponsored by the Air Force Office of Scientific Research and the Air Force Research Laboratory. It will be constructed in a cleanroom at SESE's new Interdisciplinary Science and Technology Building 4 on the Tempe campus.
The Prox-1 mission is designed by students at the Georgia Institute of Technology under the guidance Professor David Spencer, within Georgia Tech's Center for Space Systems. It will demonstrate automated trajectory control in low-Earth orbit relative to a deployed sub-satellite, or cubesat.
The flight plan calls for Prox-1 to release this smaller spacecraft, which is a version of The Planetary Society's LightSail solar sail spacecraft. (A solar sail uses the pressure of sunlight for low-thrust propulsion.) Then using the ASU camera's images to guide its trajectory, Prox-1 will fly in formation with the LightSail spacecraft. The ASU camera will also take images of the LightSail solar sail as it opens.
In addition to demonstrating automated proximity operations, Prox-1 will provide first-time flight validation of advanced sun sensor technology, a small satellite propulsion system, and a lightweight thermal imager.
As the winner of the UNP competition, the Prox-1 mission will receive an Air Force launch slot as a secondary payload plus additional development funding over the next two years. The Prox-1 team will complete spacecraft integration and testing, working toward a launch in 2015.
In addition to support from the U.S. Air Force, the Prox-1 team has been supported by contributions from the Georgia Space Grant Consortium, The Aerospace Corporation, Raytheon Vision Systems, and the Jet Propulsion Laboratory.
Provided by Arizona State University
"ASU graduate student to build infrared camera for nanosatellite." January 23rd, 2013. http://phys.org/news/2013-01-asu-student-infrared-camera-nanosatellite.html