Dynamic Scheduling: Target of Opportunity Observations of Gravitational Wave Events

TL;DR

This paper discusses optimized dynamic scheduling methods for telescope networks to improve the efficiency of follow-up observations of gravitational wave events, enhancing multi-messenger astronomy capabilities.

Contribution

It introduces new scheduling modifications for telescope networks to better handle large, disjointed localizations and incorporate prior observations, improving follow-up efficiency.

Findings

Enhanced scheduling efficiency for large skymaps

Improved handling of multiple epochs and fields

Increased likelihood of detecting optical counterparts

Abstract

The simultaneous detection of electromagnetic and gravitational waves from the coalescence of two neutron stars (GW170817 and GRB170817A) has ushered in a new era of "multi-messenger" astronomy, with electromagnetic detections spanning from gamma to radio. This great opportunity for new scientific investigations raises the issue of how the available multi-messenger tools can best be integrated to constitute a powerful method to study the transient universe in particular. To facilitate the classification of possible optical counterparts to gravitational-wave events, it is important to optimize the scheduling of observations and the filtering of transients, both key elements of the follow-up process. In this work, we describe the existing workflow whereby telescope networks such as GRANDMA and GROWTH are currently scheduled; we then present modifications we have developed for the scheduling process specifically, so as to face the relevant challenges that have appeared during the latest observing run of Advanced LIGO and Advanced Virgo. We address issues with scheduling more than one epoch for multiple fields within a skymap, especially for large and disjointed localizations. This is done in two ways: by optimizing the maximum number of fields that can be scheduled, and by splitting up the lobes within the skymap by right ascension to be scheduled individually. In addition, we implement the ability to take previously observed fields into consideration when rescheduling. We show the improvements that these modifications produce in making the search for optical counterparts more efficient, and we point to areas needing further improvement.