Tiny-box: A tool for the versatile development and characterization of low noise fast X-ray imaging detectors

TL;DR

This paper introduces Tiny-box, a versatile tool comprising a fast, low-noise electronics setup for characterizing and developing advanced X-ray imaging detectors, aiming to support next-generation space telescopes with large, fast-readout CCDs.

Contribution

The paper presents a novel, adaptable electronics and control system for high-speed, low-noise CCD readout, facilitating development of next-generation X-ray detectors.

Findings

Achieved low read noise and good energy resolution in initial tests.

Demonstrated the system's capability for high-speed data acquisition.

Laid groundwork for future multi-node, parallel CCD readout systems.

Abstract

X-ray Charge Coupled Devices (CCDs) have been the workhorse for soft X-ray astronomical instruments for the past quarter century. They provide broad energy response, extremely low electronic read noise, and good energy resolution in soft X-rays. These properties, along with the large arrays and small pixel sizes available with modern-day CCDs, make them a potential candidate for next generation astronomical X-ray missions equipped with large collecting areas, high angular resolutions and wide fields of view, enabling observation of the faint, diffuse and high redshift X-ray universe. However, such high collecting area (about 30 times Chandra) requires these detectors to have an order of magnitude faster readout than current CCDs to avoid saturation and pile up effects. In this context, Stanford University and MIT have initiated the development of fast readout X-ray cameras. As a tool for this development, we have designed a fast readout, low noise electronics board (intended to work at a 5 Megapixel per second data rate) coupled with an STA Archon controller to readout a 512 x 512 CCD (from MIT Lincoln Laboratory). This versatile setup allows us to study a number of parameters and operation conditions including the option for digital shaping. In this paper, we describe the characterization test stand, the concept and development of the readout electronics, and simulation results. We also report the first measurements of read noise, energy resolution and other parameters from this set up. While this is very much a prototype, we plan to use larger, multi-node CCD devices in the future with dedicated ASIC readout systems to enable faster, parallel readout of the CCDs.