Bibcode
Brageot, E.; Groussin, O.; Lamy, P.; Reynaud, J.-L.; Fargant, G.; Licandro, J.; Helbert, J.; Knollenberg, J.; Kührt, E.
Bibliographical reference
Space Telescopes and Instrumentation 2012: Optical, Infrared, and Millimeter Wave. Proceedings of the SPIE, Volume 8442, id. 84424O-84424O-9 (2012).
Advertised on:
9
2012
Citations
0
Refereed citations
0
Description
We report on the feasibility study of a mid-infrared (8-18 µm)
spectro-imager called THERMAP, based on an uncooled micro-bolometer
detector array. Due to the recent technological development of these
detectors, which have undergone significant improvements in the last
decade, we wanted to test their performances for the Marco Polo R ESA
Cosmic Vision mission. In this study, we demonstrate that the new
generation of uncooled micro-bolometer detectors has all the imaging and
spectroscopic capabilities to fulfill the scientific objectives of this
mission. In order to test the imaging capabilities of the detector, we
set up an experiment based on a 640x480 ULIS micro-bolometer array, a
germanium objective and a black body. Using the results of this
experiment, we show that calibrated radiometric images can be obtained
down to at least 255 K (lower limit of our experiment), and that two
calibration points are sufficient to determine the absolute scene
temperature with an accuracy better than 1.5 K. Adding flux attenuating
neutral density mid-infrared filters (transmittance: 50%, 10%, 1%) to
our experiment, we were able to evaluate the spectroscopic performances
of the detector. Our results show that we can perform spectroscopic
measurements in the wavelength range 8-16 µm with a spectral
resolution of R~40-80 for a scene temperature <300 K, the typical
surface temperature of a Near Earth Asteroid at 1 AU from the Sun. The
mid-infrared spectro-imager THERMAP, based on the above detector, is
therefore well suited for the Marco Polo R mission.