Auto-RSM: an automated parameter-selection algorithm for the RSM map exoplanet detection algorithm

TL;DR

This paper introduces Auto-RSM, an automated parameter-selection algorithm that optimizes the RSM map for exoplanet detection, improving performance over previous methods and reducing bias and time consumption.

Contribution

The paper presents a novel automated optimization procedure for the RSM map and PSF-subtraction techniques, enhancing exoplanet detection accuracy and efficiency.

Findings

Improved detection performance metrics with Auto-RSM.

Better results compared to earlier RSM and other techniques.

Validated on multiple high-contrast imaging datasets.

Abstract

Most of the high-contrast imaging (HCI) data-processing techniques used over the last 15 years have relied on the angular differential imaging (ADI) observing strategy, along with subtraction of a reference point spread function (PSF) to generate exoplanet detection maps. Recently, a new algorithm called regime switching model (RSM) map has been proposed to take advantage of these numerous PSF-subtraction techniques; RSM uses several of these techniques to generate a single probability map. Selection of the optimal parameters for these PSF-subtraction techniques as well as for the RSM map is not straightforward, is time consuming, and can be biased by assumptions made as to the underlying data set. We propose a novel optimisation procedure that can be applied to each of the PSF-subtraction techniques alone, or to the entire RSM framework. The optimisation procedure consists of three main steps: (i) definition of the optimal set of parameters for the PSF-subtraction techniques using the contrast as performance metric, (ii) optimisation of the RSM algorithm, and (iii) selection of the optimal set of PSF-subtraction techniques and ADI sequences used to generate the final RSM probability map. The optimisation procedure is applied to the data sets of the exoplanet imaging data challenge (EIDC), which provides tools to compare the performance of HCI data-processing techniques. The data sets consist of ADI sequences obtained with three state-of-the-art HCI instruments: SPHERE, NIRC2, and LMIRCam. The results of our analysis demonstrate the interest of the proposed optimisation procedure, with better performance metrics compared to the earlier version of RSM, as well as to other HCI data-processing techniques.