@inproceedings{9649491e95024d4394d0b7ca615abe3c,
title = "The high-speed X-ray camera on AXIS: design and performance updates",
abstract = "AXIS, a Probe mission concept now in a Phase A study, will provide transformative studies of high-energy astrophysical phenomena thanks to its high-resolution X-ray spectral imaging. These capabilities are enabled by improvements to the mirror design that greatly increase the X-ray throughput per unit mass compared to heritage missions like Chandra; and to the detector system, which operates more than an order of magnitude faster than heritage instruments while maintaining excellent spectral performance and low power consumption. We present updates to the design of the AXIS High-Speed Camera, a collaborative effort by MIT, Stanford University, the Pennsylvania State University, and the Southwest Research Institute. The camera employs large-format MIT Lincoln Laboratory CCDs that feature multiple high-speed, low-noise output amplifiers and an advanced single-layer polysilicon gate structure for fast, low-power clock transfers. A first lot of prototype CCID100 CCDs has completed fabrication and will soon begin X-ray performance testing. The CCDs are paired with high-speed, low-noise ASIC readout chips designed by Stanford to provide better performance than conventional discrete solutions at a fraction of the power consumption and footprint. Complementary Front-End Electronics employ state-of-the-art digital video waveform capture and advanced signal processing to further deliver low noise at high speed. The detector system is housed in a high-heritage camera body that ensures precise thermal control and minimization of molecular contamination. The Back-End Electronics provide high-speed identification of candidate X-ray events and transient monitoring that relays fast alerts of changing sources to the community. We highlight updates to our parallel X-ray performance test facilities at MIT and Stanford, and review the current performance of the CCD and ASIC technology from testing of prototype devices. These measurements achieve excellent spectral response at the required readout rate, demonstrating that we will meet mission requirements and enable AXIS to achieve world-class science.",
author = "Miller, \{Eric D.\} and Grant, \{Catherine E.\} and Robert Goeke and Bautz, \{Marshall W.\} and Christopher Leitz and Kevan Donlon and Allen, \{Steven W.\} and Sven Herrmann and Falcone, \{Abraham D.\} and \{Elio Angile\}, F. and Tanmoy Chattopadhyay and Michael Cooper and Jensen, \{Mallory A.\} and Jill Juneau and Beverly LaMarr and Andrew Malonis and \{Glenn Morris\}, R. and Peter Orel and Pan, \{Abigail Y.\} and Steven Persyn and Artem Poliszczuk and Prigozhin, \{Gregory Y.\} and Ilya Prigozhin and Andrew Ptak and Christopher Reynolds and Stueber, \{Haley R.\} and Keith Warner and Wilkins, \{Daniel R.\}",
note = "Publisher Copyright: {\textcopyright} 2025 SPIE. All rights reserved.; 24th UV, X-Ray, and Gamma-Ray Space Instrumentation for Astronomy ; Conference date: 05-08-2025 Through 07-08-2025",
year = "2025",
month = sep,
day = "18",
doi = "10.1117/12.3063378",
language = "English (US)",
series = "Proceedings of SPIE - The International Society for Optical Engineering",
publisher = "SPIE",
editor = "Siegmund, \{Oswald H.\} and Keri Hoadley",
booktitle = "UV, X-Ray, and Gamma-Ray Space Instrumentation for Astronomy XXIV",
address = "United States",
}