Evaluation of Automated Fermi GBM Localizations of Gamma-ray Bursts

The capability of the Fermi Gamma-ray Burst Monitor (GBM) to localize gamma-ray bursts (GRBs) is evaluated for two different automated algorithms: the GBM Team's RoboBA algorithm and the independently developed BALROG algorithm. Through a systematic study utilizing over 500 GRBs with known locations from instruments like Swift and the Fermi Large Area Telescope, we directly compare the effectiveness of, and accurately estimate the systematic uncertainty for, both algorithms. We show that simple adjustments to the GBM Team's RoboBA, in operation since early 2016, yield significant improvement in the systematic uncertainty, removing the long tail identified in the systematic, and improve the overall accuracy. The systematic uncertainty for the updated RoboBA localizations is 18 for 52% of GRBs and 41 for the remaining 48%. Both from public reporting by BALROG and our systematic study, we find the systematic uncertainty of 1 degrees-2 degrees quoted in circulars for bright GRBs is an underestimate of the true magnitude of the systematic, which we find to be 27 for 74% of GRBs and 33 degrees for the remaining 26%. We show that, once the systematic uncertainty is considered, the RoboBA 90% localization confidence regions can be more than an order of magnitude smaller in area than those produced by BALROG.