PyCBC Live Search for Compact Binary Mergers in Advanced LIGO and Virgo's Fourth Observing Run

Arthur Tolley; Gareth S. Cabourn Davies; Ian Harry; Max Trevor; Stephanie Hoang; Thomas Dent; Tito Dal Canton

arxiv: 2606.07679 · v1 · pith:H6STHPRFnew · submitted 2026-06-04 · 🌌 astro-ph.IM · astro-ph.HE· gr-qc

PyCBC Live Search for Compact Binary Mergers in Advanced LIGO and Virgo's Fourth Observing Run

Max Trevor , Gareth S. Cabourn Davies , Tito Dal Canton , Thomas Dent , Ian Harry , Stephanie Hoang , Arthur Tolley This is my paper

Pith reviewed 2026-06-27 23:13 UTC · model grok-4.3

classification 🌌 astro-ph.IM astro-ph.HEgr-qc

keywords PyCBC Livegravitational wave searchcompact binary coalescencesO4 observing runlow-latency alertsfalse alarm rateearly warning searchranking statistic

0 comments

The pith

PyCBC Live O4 upgrades recover 79 percent of two-detector injections at false alarm rates below one per year, up from 51 percent in the prior configuration.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper presents updates to the PyCBC Live low-latency search pipeline for gravitational waves from compact binary coalescences ahead of the LIGO-Virgo O4 run. Changes include a ranking statistic with time-dependent background modeling from data quality streams, refined probability calculations for astrophysical origin, an early warning search for pre-merger alerts, and extended autogating across the full strain buffer. Validation on the Mock Data Challenge shows the O4 version identifies 1979 of 2495 two-detector injections with decisive SNR above 6 at a false alarm rate below one per year, versus 1262 for the O3 version. A reader would care because the gains support faster, more reliable alerts that can trigger electromagnetic follow-up observations of the same events.

Core claim

The O4 configuration of PyCBC Live identified 1979 of 2495 two-detector injections with decisive SNR greater than 6 at a false alarm rate below one per year (79.3 percent), compared to 1262 (50.6 percent) with the O3 configuration. For single-detector time injections, the O4 configuration identified 218 of 1174 (18.6 percent), compared to 170 (14.5 percent) previously. The pipeline implements an Early Warning search for binary neutron star and neutron star-black hole systems that provides alerts with 2.5-3.5 seconds latency and warning times up to 60 seconds before coalescence, while maintaining a median latency of 15.94 seconds from merger to candidate upload.

What carries the argument

The enhanced ranking statistic that incorporates time-dependent background modeling using data quality streams and daily updates of the noise model.

If this is right

The Early Warning search can issue pre-merger alerts for binary neutron star and neutron star-black hole systems up to 60 seconds before coalescence.
Sensitivity improves by factors of 1.7 to 2.3 for the coincident search at an inverse false alarm rate of 10 years.
The pipeline maintains a median latency of 15.94 seconds from merger to candidate upload.
Virgo can be included as a sky-map-only detector without contributing to the ranking statistic.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

If the mock data performance holds on real observations, the pipeline should produce more multi-messenger events with electromagnetic counterparts during O4.
The single-detector improvements could raise the overall detection count in periods when only one interferometer is operating.
The extended autogating may reduce losses from clusters of loud glitches that previously affected multiple segments.

Load-bearing premise

The Mock Data Challenge accurately reproduces the statistical properties of real O4 detector noise, glitches, and data quality variations that affect the ranking statistic and false alarm rate estimates.

What would settle it

Running the O4 pipeline configuration on actual O4 observing run data and comparing recovered events and false alarm rates against the Mock Data Challenge predictions.

Figures

Figures reproduced from arXiv: 2606.07679 by Arthur Tolley, Gareth S. Cabourn Davies, Ian Harry, Max Trevor, Stephanie Hoang, Thomas Dent, Tito Dal Canton.

**Figure 2.** Figure 2: FIG. 2. Sensitive volume ratio (O4 vs. O3 ranking statistic) [PITH_FULL_IMAGE:figures/full_fig_p007_2.png] view at source ↗

**Figure 3.** Figure 3: FIG. 3. Cumulative distribution of merger-to-upload latencies [PITH_FULL_IMAGE:figures/full_fig_p008_3.png] view at source ↗

**Figure 4.** Figure 4: FIG. 4. SNR optimizer performance on the MDC [ [PITH_FULL_IMAGE:figures/full_fig_p009_4.png] view at source ↗

read the original abstract

PyCBC Live is a low-latency search pipeline that identifies gravitational waves from compact binary coalescences and provides alerts for electromagnetic follow-up. This paper presents improvements to PyCBC Live that were implemented for the fourth observing run (O4) of the LIGO-Virgo-KAGRA network, which operated from May 2023 to November 2025. The ranking statistic was enhanced to incorporate time-dependent background modeling using data quality streams and daily updates of the noise model. Follow-up capabilities were improved through refined probability of astrophysical origin calculations, optimized SNR recovery with reduced computational cost, and a method to incorporate Virgo as a sky-map-only detector. An Early Warning search was implemented to detect binary neutron star and neutron star-black hole systems before merger, providing pre-merger alerts with a pipeline latency of 2.5-3.5 seconds and warning times up to 60 seconds before coalescence. The autogating procedure was extended to apply to the full strain buffer rather than individual analysis segments, improving rejection of loud and rapidly successive glitches. Performance validation using the Mock Data Challenge showed sensitivity improvements of factors of 1.7 to 2.3 for the coincident search depending on source mass at an inverse false alarm rate of 10 years, and factors of 1.3 to 1.7 for the single-detector search. For injections in two-detector time, the O4 configuration identified 1979 of 2495 injections with a decisive SNR greater than 6 at a false alarm rate below one per year (79.3%), compared to 1262 (50.6%) with the O3 configuration. For injections in single-detector time, the O4 configuration identified 218 of 1174 injections (18.6%), compared to 170 (14.5%) with the O3 configuration. The search maintained a median latency of 15.94 seconds from merger to candidate upload.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

Solid engineering upgrades to PyCBC Live for O4 with clear MDC numbers, but gains rest on how faithfully the mocks capture real noise and glitches.

read the letter

The paper walks through concrete updates to the existing PyCBC Live pipeline ahead of and during O4. They added time-dependent background modeling that pulls in data quality streams and refreshes the noise model daily, built an early-warning mode that can flag BNS and NSBH events 2.5-3.5 seconds after merger with up to 60 seconds of warning, extended autogating to the full strain buffer, and allowed Virgo to contribute only to sky maps. These are targeted fixes rather than new search methods.

The numbers from the Mock Data Challenge are straightforward: the O4 configuration recovers 1979 of 2495 two-detector injections (79.3 %) at FAR below one per year versus 1262 (50.6 %) for the O3 setup, with smaller but still positive gains in single-detector time. Median latency stays at about 16 seconds. That level of before-and-after quantification is helpful for anyone who needs to know what actually changed and by how much.

The obvious limitation is that all the sensitivity claims come from the MDC. If the mock data under-represents the actual non-stationary glitches, correlations, or data-quality variations that appear in real O4 segments, the reported improvement factors will shrink once the pipeline runs live. The abstract gives no cross-check against real O4 data, so the 1.7–2.3 coincident gain remains provisional. The work avoids circularity by using independent injections, which is the right approach.

This is a methods paper aimed at the small group that maintains or uses low-latency CBC searches. It records the O4 configuration clearly and shows the testing that was done. The thinking is straightforward and the citations track the prior PyCBC Live papers without obvious gaps.

I would send it to peer review. The changes and the MDC results are worth referee time even if later real-data performance needs separate checking.

Referee Report

1 major / 2 minor

Summary. The manuscript describes updates to the PyCBC Live low-latency pipeline for O4, including time-dependent background modeling in the ranking statistic via data quality streams and daily noise model updates, refined astrophysical origin probabilities, an Early Warning search for pre-merger alerts (2.5-3.5 s latency, up to 60 s warning), Virgo as sky-map-only, and extended autogating on the full strain buffer. Validation via Mock Data Challenge reports sensitivity gains of 1.7-2.3 (coincident) and 1.3-1.7 (single-detector) at IFAR=10 yr, with 1979/2495 (79.3%) two-detector injections recovered at FAR<1/yr vs. 1262/2495 (50.6%) for O3, and 218/1174 (18.6%) vs. 170/1174 (14.5%) for single-detector; median latency is 15.94 s.

Significance. If the MDC results translate to real O4 data, the enhancements would meaningfully increase the number of low-latency detections available for electromagnetic follow-up and enable pre-merger alerts for BNS/NSBH systems. The work provides concrete, operational improvements to an existing pipeline used in multi-messenger astronomy.

major comments (1)

[Performance validation using the Mock Data Challenge] Performance validation using the Mock Data Challenge: the headline recovery rates (1979/2495 at FAR<1/yr for two-detector injections; 218/1174 for single-detector) and improvement factors (1.7-2.3 coincident, 1.3-1.7 single-detector) rest entirely on MDC results. The manuscript provides no quantitative assessment of how the MDC's glitch populations, non-stationarity, or data-quality variations compare to actual O4 observations, which directly affects whether the time-dependent ranking statistic and FAR estimates will deliver the claimed performance in live search.

minor comments (2)

The abstract states the Early Warning search provides 'warning times up to 60 seconds before coalescence'; the full text should specify the distribution of warning times and the fraction of events achieving >10 s or >30 s warnings.
Clarify whether the reported median latency of 15.94 s applies only to the standard search or also to the Early Warning configuration, and how autogating on the full buffer affects this latency.

Simulated Author's Rebuttal

1 responses · 0 unresolved

We appreciate the referee's thorough review and their recognition of the potential impact of our work on multi-messenger astronomy. We address the major comment point by point below.

read point-by-point responses

Referee: Performance validation using the Mock Data Challenge: the headline recovery rates (1979/2495 at FAR<1/yr for two-detector injections; 218/1174 for single-detector) and improvement factors (1.7-2.3 coincident, 1.3-1.7 single-detector) rest entirely on MDC results. The manuscript provides no quantitative assessment of how the MDC's glitch populations, non-stationarity, or data-quality variations compare to actual O4 observations, which directly affects whether the time-dependent ranking statistic and FAR estimates will deliver the claimed performance in live search.

Authors: We thank the referee for highlighting this important point. The current manuscript focuses on describing the O4 updates to PyCBC Live and validating them using the Mock Data Challenge (MDC), which incorporates time-dependent noise models and glitch populations informed by O3 and early O4 data. However, we agree that the manuscript lacks an explicit quantitative assessment of the MDC's fidelity to actual O4 observations in terms of glitch populations, non-stationarity, and data quality. We will revise the manuscript to include a more detailed description of the MDC construction and a discussion of its limitations, noting that the reported sensitivity improvements are based on this simulation and that real-world performance will be evaluated using the live O4 search results. This revision will help readers better contextualize the MDC results. revision: yes

Circularity Check

0 steps flagged

No circularity; performance metrics obtained from independent MDC injections

full rationale

The paper's central performance claims (e.g., 1979/2495 injections recovered at FAR < 1/yr) are direct empirical counts from the Mock Data Challenge, an external test set constructed separately from the ranking-statistic tuning. No equation reduces a reported gain to a fitted parameter by construction, no self-citation supplies a uniqueness theorem or ansatz that the present work then treats as given, and the derivation of the O4 ranking statistic (time-dependent background, data-quality streams, autogating) is presented as an independent engineering change whose effect is then measured on the MDC. The chain is therefore self-contained against external benchmarks.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

The central performance claims rest on the assumption that the Mock Data Challenge faithfully represents real O4 conditions; no free parameters or invented entities are explicitly introduced in the abstract.

axioms (1)

domain assumption The Mock Data Challenge accurately simulates real detector conditions including glitches and noise.
All reported sensitivity gains and injection recovery rates are measured against this challenge.

pith-pipeline@v0.9.1-grok · 5918 in / 1288 out tokens · 18895 ms · 2026-06-27T23:13:01.718927+00:00 · methodology

discussion (0)

Reference graph

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Modelling event PDFs over ranking statistic We model the background PDF with an exponential in ρc following [34]: fN(ρc|θ)≃α c exp(−αc(ρc −ρ th)) (ρ c > ρ th),(9) whereα c is a slope parameter (see also [38]). For lower- mass templates, which correspond to the systems most relevant for electromagnetic follow-up, we findα c = 6 is a good approximation of t...
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For lower- mass templates, which correspond to the systems most relevant for electromagnetic follow-up, we findα c = 6 is a good approximation of the distribution

Modelling event PDFs over ranking statistic We model the background PDF with an exponential in ρc following [34]: fN(ρc|θ)≃α c exp(−αc(ρc −ρ th)) (ρ c > ρ th),(9) whereα c is a slope parameter (see also [38]). For lower- mass templates, which correspond to the systems most relevant for electromagnetic follow-up, we findα c = 6 is a good approximation of t...

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For O4, we increased the number of bins (indexed byp) to 8, each with a signal trigger rater S,p and noise trigger rater N,p

Template dependence For the O3p astro estimate, the template bank was di- vided into 3 chirp mass bins [40], which provided only a coarse approximation of the signal distribution. For O4, we increased the number of bins (indexed byp) to 8, each with a signal trigger rater S,p and noise trigger rater N,p. The signal rate in each bin is estimated from O1–O3...

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For electromagnetic follow-up plan- ning, the relative probabilities of these classes are also needed

Binary source type classification The resultingp astro value covers all astrophysical com- pact binary source classes (BNS, binary black hole (BBH), and NSBH). For electromagnetic follow-up plan- ning, the relative probabilities of these classes are also needed. In PyCBC Live, these are estimated from the template chirp mass and a redshift estimate based ...

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Coincident searchThe updated ranking statistic described in this paper improved the sensitivity of the coincident search compared to O3

Search sensitivity a. Coincident searchThe updated ranking statistic described in this paper improved the sensitivity of the coincident search compared to O3. The top of Figure 2 shows the ratio of sensitive volume during two-detector 8 FIG. 3. Cumulative distribution of merger-to-upload latencies on the MDC. Median: 15.94 s; 99.89% of events within 50 s....

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The me- dian latency from merger to GraceDB upload was 15.94 seconds

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Of 10,270 GraceDB events retrieved, 5,091 were uploaded by the SNR optimizer

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2024

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Early warning search The EW search was evaluated using a dedicated in- jection campaign separate from the main MDC [50]. A set of 32,599 simulated BNS and NSBH signals were injected into 40 days of simulated colored Gaussian noise, with component masses 1–3M ⊙, near-zero spins (z-components drawn uniformly from±0.05), and net- work SNRs distributed unifor...

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