Automated Evaluation of Environmental Coupling for Advanced LIGO Gravitational Wave Detections

Vibrational coupling between \ac{LLO}'s \ac{HAM} 6 vacuum chamber Z-axis accelerometer and \ac{DARM} as measured prior to \ac{O3}. The vibrational coupling here is likely driven by stray light scattering off of the septum window dividing this vacuum chamber and the adjoining \ac{HAM} 5 chamber and then recombining with the main beam~\cite{septumalog}. The large fraction of upper limit estimates, rather than measured values, for the vibrational coupling is because \ac{PEM} injections could not be increased to an amplitude such that the injection was visible in the \ac{DARM} data without saturating the accelerometer signal. Each sensor count corresponds to $\unit[6.1]{\mu m~s^{-2}}$ of acceleration in the vertical direction~\cite{PEMpage}.

\ac{ASD} of the Z-axis \ac{HAM} 6 accelerometer during the background time. Background \ac{PEM} sensor data is used to compute the tuned \ac{CF} of section~\ref{sssec:tunedasd}. $\unit[45.75]{s}$ of sensor data were used to calculate this \ac{ASD}.

Top: Comparison of the \ac{CF} interpolated from the data in figure~\ref{fig:example_cf} to the interpolated, tuned \ac{CF} computed by analyzing the \ac{DARM} background \ac{ASD}. The untuned and tuned predictions for the \ac{ASD} largely agree, except near $30$ and $\unit[90]{Hz}$. The points where environmental contributions to \ac{DARM} are overestimated and need tuning are derived from upper limit estimates of the chamber motion to \ac{DARM} coupling. These frequencies are marked with black arrows. Bottom: Comparison of the \ac{DARM} $t_{\mathrm{back}}$ \ac{ASD} with the estimated contribution from the \ac{HAM} 6 accelerometer. The result of the tuning procedure is to constrain the predicted environmental contribution from a sensor to be not greater than the observed \ac{DARM} \ac{ASD}. As in the top plot, black arrows mark where the untuned \ac{CF} predicts that the \ac{DARM} \ac{ASD} should exceed its observed value to the \ac{HAM} 6 accelerometer data. These are the points which require tuning to reconcile the predicted and actual \ac{DARM} \ac{ASD}s.

The results of the $c$-statistic calculation for each spectrogram tile for the \ac{LLO} \ac{HAM} 6 accelerometer during GW190707. The value of $1-c$ is plotted for each tile so that time-frequency tiles with the highest likelihood of contamination, as calculated by \textsc{PEMcheck}, appear brighter. The time-frequency tiles enclosed by the red box track the evolution of the \ac{GW} signal as predicted by \ac{NR}. The lowest $c$-statistic found within the \ac{GW} track occurs at $\sim\unit[0.1]{s}$ and $\sim\unit[78]{Hz}$ prior to the event's $t_c$. A minimum $c$-statistic of $0.52$ indicates that environmental disturbances witnessed by this sensor do not couple to the \ac{GW} strain data during the event.

Histogram of the minimum $c$-statistic calculated by \textsc{PEMcheck} for all GWTC-2.1 and GWTC-3 confident events using the pre-\ac{O3} coupling data. The \textsc{PEMcheck} analysis identifies $6$ of the $149$ \ac{O3} \ac{GW} events as having a minimum $c$ below $0.2$

Cumulative distribution of the $c$-statistic found for each \ac{PEM} channel studied by \textsc{PEMcheck} for each \ac{GW} event in \ac{O3} using the pre-\ac{O3} coupling data. Each light grey trace corresponds to the \ac{CDF} of the $c$-statistic for an individual \ac{GW} event, while the black trace denotes the mean number of sensors with that particular value of $c$ or less. GW190707 as well as the three events with the lowest $c$ are highlighted.

\ac{CDF} of the $c$-statistic for each run of \textsc{PEMcheck} at \ac{LHO} with GW200115's properties. The \ac{CDF} marked ``foreground" corresponds to \textsc{PEMcheck} run at the actual time of the \ac{GW} event.

Below: constant-Q transform of \ac{LLO} \ac{GW} strain data during a thunderclap witnessed. The 31 red time-frequency tracks overlaid on the thunderclap data represent 31 hypothetical \ac{GW} time-frequency tracks with the properties given in table~\ref{tab:190521g_props} vetted by \textsc{PEMcheck}. Above: the lowest value of $c$ found by \textsc{PEMcheck} for the series of hypothetical \ac{GW} tracks overlaid on thunderclap data. The channel with the lowest $c$-statistic for a given trial is denoted by the marker style. The bold line corresponds to $c=0.2$.