Kavli Affiliate: Eric D. Miller
| First 5 Authors: Artem Poliszczuk, Dan Wilkins, Steven W. Allen, Eric D. Miller, Tanmoy Chattopadhyay
| Summary:
Traditional cosmic ray filtering algorithms used in X-ray imaging detectors
aboard space telescopes perform event reconstruction based on the properties of
activated pixels above a certain energy threshold, within 3×3 or 5×5 pixel
sliding windows. This approach can reject up to 98% of the cosmic ray
background. However, the remaining unrejected background constitutes a
significant impediment to studies of low surface brightness objects, which are
especially prevalent in the high-redshift universe. The main limitation of the
traditional filtering algorithms is their ignorance of the long-range
contextual information present in image frames. This becomes particularly
problematic when analyzing signals created by secondary particles produced
during interactions of cosmic rays with body of the detector. Such signals may
look identical to the energy deposition left by X-ray photons, when one
considers only the properties within the small sliding window. Additional
information is present, however, in the spatial and energy correlations between
signals in different parts of the frame, which can be accessed by modern
machine learning (ML) techniques. In this work, we continue the development of
an ML-based pipeline for cosmic ray background mitigation. Our latest method
consist of two stages: first, a frame classification neural network is used to
create class activation maps (CAM), localizing all events within the frame;
second, after event reconstruction, a random forest classifier, using features
obtained from CAMs, is used to separate X-ray and cosmic ray features. The
method delivers >40% relative improvement over traditional filtering in
background rejection in standard 0.3-10keV energy range, at the expense of only
a small (<2%) level of lost X-ray signal. Our method also provides a convenient
way to tune the cosmic ray rejection threshold to adapt to a user’s specific
scientific needs.
| Search Query: ArXiv Query: search_query=au:”Eric D. Miller”&id_list=&start=0&max_results=3