SPLIT: a robust semi-coherent inference pipeline for long-inspiral gravitational-wave sources

Abstract

The Laser Interferometer Space Antenna (LISA) will detect gravitational waves (GWs) from dozens of extreme- and intermediate-mass-ratio inspirals (EMRIs/IMRIs). These sources will stay in-band for months to years, offering extraordinary scientific potential. However, their fully phase-coherent analysis standard in current pipelines imposes stringent waveform accuracy requirements; failing to model the signal over such long durations can result in significant systematic biases. To address this, we formulate a robust semi-coherent Bayesian inference framework that segments the data into independent blocks, analyzes each block coherently, and recombines the results incoherently. By restricting phase-tracking to much shorter block durations, this approach prevents significant accumulation of phase errors. We implement this methodology in SPLIT (Semi-coherent Posteriors for Long-Inspiral Templates), a GPU-accelerated Python package. Applying SPLIT to an environment-rich injection, we demonstrate that while a fully-coherent vacuum-GR analysis incurs a maximum 1D systematic bias of ≈ 4.8σ from the truth, the shorter integration window of our semi-coherent approach restricts such biases to 0.5σ. Overall, despite a fractional loss of optimal signal-to-noise ratio, the substantial improvement in parameter accuracy offered by the semi-coherent approach presents a highly advantageous trade-off for LISA and other future GW detectors.