Proceedings Volume Sensors, Systems, and Next-Generation Satellites XXII, 107850Z https://doi.org/10.1117/12.2325690
Physikalisch-Technische Bundesanstalt (PTB) designed a new calibration facility, the Reduced Background Calibration Facility 2 (RBCF2) as the successor of the Reduced Background Calibration Facility (RBCF) [1] and brought it recently into operation. It provides traceable calibrations of space based infrared remote sensing experiments in terms of radiation temperature and spectral radiance.
Traceable measurements from space require the use of calibrated stable detector systems and / or source based calibration standards on board of the satellites. In any case they should be calibrated under space like conditions to ensure traceability with the smallest possible uncertainty. The RBCF2 enables therefore the calibration of radiators and detectors and cameras under cryogenic and / or vacuum conditions. The integration of the instruments under test into the RBCF2 can be done under ISO 5 clean room conditions.
The general concept of the RBCF2 is to connect different sources in the source chamber and detectors in the detector chamber via a liquid nitrogen cooled beam line. Source and detector chamber also incorporate cooling facilities. Translation units in both chambers enable the RBCF2 to compare and calibrate different sources and detectors with stable comparison instruments at cryogenic temperatures and under a common vacuum.
Reference sources for comparisons are dedicated vacuum variable temperature blackbodies, the vacuum medium temperature blackbody (VMTBB, 150 °C to 430 °C), the vacuum low temperature blackbody (VLTBB, -173 °C to 177 °C), the liquid operated blackbody (LBB, -80 °C to 80 °C), the large area heatpipe blackbody (LAHBB, -60 °C to 50 °C) featuring a radiating diameter of 250 mm, the liquid nitrogen blackbody (LNBB, -196 °C) and calibrated vacuum integrating sphere radiators for UV-VIS and SWIR applications. The radiation temperatures of the reference blackbodies and the radiance of the integrating sphere radiators are traceable to the ITS-90 via the primary standards of PTB. Using the calibrated vacuum infrared standard radiation thermometer (VIRST) [2] direct calibrations of sources in terms of radiation temperature in the wavelength range from 8 µm to 14 µm can also be performed.
The radiation of the reference sources and the sources under test can also be imaged on a vacuum Fourier-Transform Spectrometer (FTS) to allow spectrally resolved measurements. The FTS covers the wavelength range from 0.4 µm to 1000 µm. Here several detectors are employed, ranging from photomultipliers to liquid helium cooled bolometers. The different reference blackbodies enable measurements with respect to at least two reference temperatures, simultaneously. Hereby disturbances in the IR by background radiation resulting from inside the FTS can be effectively compensated. Sources can be also spatially mapped and characterized for the lateral distribution of their spectral radiance [3].
The flexible design of the facility allows also large aperture camera characterizations and modifications for customer needs and the measurement of directional spectral emissivities over a wide temperature and wavelength range [4].
[1] C. Monte, B. Gutschwager, J. Hollandt, The Reduced Background Calibration Facility for Detectors and Radiators at the Physikalisch-Technische Bundesanstalt, Sensors, Systems, and Next-Generation Satellites XIII, SPIE, 2009, 7474, 747414
[2] B. Gutschwager, J. Hollandt, T. Jankowski, R. Gärtner, A Vacuum Infrared Standard Radiation Thermometer at the PTB, International Journal of Thermophysics, 29, 330-340, 2008
[3] C. Monte, B. Gutschwager, A. Adibekyan, M. Kehrt, A. Ebersoldt, F. Olschewski, J. Hollandt, Radiometric calibration of the in-flight blackbody calibration system of the GLORIA interferometer Atmospheric Measurement Techniques, 2014, 7, 13-27
[4] A. Adibekyan, C. Monte, M. Kehrt, B. Gutschwager, J. Hollandt, Emissivity measurement under vacuum from 4 µm to 100 µm and from -40 °C to 450 °C at PTB, International Jounal of Thermophysics, 2015, 36, 283-289