Simulations of a 2 x 1.5D coded aperture camera for X-ray astronomy

TL;DR

This paper studies the imaging performance of a 2 x 1.5D coded aperture X-ray camera using simulations, focusing on two decoding algorithms for space-based X-ray monitoring.

Contribution

It introduces and compares two decoding algorithms, IROS and MLM, for a 2 x 1.5D coded aperture camera in X-ray astronomy.

Findings

IROS effectively determines point source configurations.

MLM provides optimal source flux estimations.

Simulations include detector responses and electronics processing.

Abstract

The concept of two perpendicular one-dimensional coded aperture cameras, necessitated by the imaging capability of the detector, finds its application in the design of the Wide Field Monitor (WFM). This instrument has the future goal to monitor the variable X-ray sky for transient activity. Characteristic of each camera is a fine angular resolution in one direction (typically 5 arcmin) and a coarse one in the other (5 degrees). The coarse perpendicular resolution makes the camera so-called '1.5D'. The WFM has been studied for a number of space-borne X-ray observatory concepts: LOFT, eXTP, Strobe-X, ARCO and now LEM-X. We here report on a study of two decoding algorithms for this instrument and its imaging performance. Detector responses to the X-ray sky are simulated, including the signal processing by the front-end and back-end electronics. The decoding algorithms are the iterative removal of sources (IROS), in combination with cross correlation, and the maximum likelihood method (MLM). IROS is most suited for the determination of the point source configuration of the observed sky and MLM for the optimum determination of the source fluxes. (..) the WFM is a high performance monitoring instrument with straightforward and proven technology that enables the identification of new cosmic X-ray sources, for instance X-ray novae, gamma-ray bursts and electromagnetic counterparts to gravitational wave events from merging compact objects, and the detection of unusual and interesting behavior of persistent cosmic X-ray sources, such as accretion disk state changes.