http://arxiv.org/abs/1911.04684
Astronomical observations often require the detection of faint signals in the presence of noise, and the near-infrared regime is no exception. In particular, where the application has short exposure time constraints, we are frequently and unavoidably limited by the read noise of a system. A recent and revolutionary development in detector technology is that of linear-mode avalanche photodiode (LmAPD) arrays. By the introduction of a signal multiplication region within the device, effective read noise can be reduced to <0.2 e-, enabling the detection of very small signals at frame rates of up to 1 kHz. This is already impacting ground-based astronomy in high-speed applications such as wavefront sensing and fringe tracking, but has not yet been exploited for scientific space missions. We present the current status of a collaboration with Leonardo MW – creators of the ‘SAPHIRA’ LmAPD array – as we work towards the first in-orbit demonstration of a SAPHIRA device in ‘Emu’, a hosted payload on the International Space Station. The Emu mission will fully benefit from the ‘noiseless’ gains offered by LmAPD technology as it produces a time delay integration photometric sky survey at 1.4 microns, using compact readout electronics developed at the Australian National University. This is just one example of a use case that could not be achieved with conventional infrared sensors.
J. Gilbert, A. Grigoriev, S. King, et. al.
Wed, 13 Nov 19
71/73
Comments: Paper presented at the 70th International Astronautical Congress, 21-25 October 2019, Washington D.C., United States