Abstract
We introduce a gravitational waveform inversion strategy that discovers mechanical models of binary black hole (BBH) systems. We show that only a single time series of (possibly noisy) waveform data is necessary to construct the equations of motion for a BBH system. Starting with a class of universal differential equations parameterized by feed-forward neural networks, our strategy involves the construction of a space of plausible mechanical models and a physics-informed constrained optimization within that space to minimize the waveform error. We apply our method to various BBH systems including extreme and comparable mass ratio systems in eccentric and noneccentric orbits. We show that the resulting differential equations apply to time durations longer than the training interval, and relativistic effects, such as perihelion precession, radiation reaction, and orbital plunge, are automatically accounted for. The methods outlined here provide a data-driven approach to studying the dynamics of binary black hole systems.
Highlights
Classical physical theories begin with scientific laws as ansätze, which are validated by repeated scientific experiment
We have presented a data-driven gravitational waveform inversion strategy, which generates mechanical models of binary black hole systems
Our differential equations are trained by solving a physicsinformed constrained optimization problem that seeks to minimize the waveform error
Summary
Classical physical theories begin with scientific laws as ansätze, which are validated by repeated scientific experiment. We follow a different approach to learning physical equations: we solve an optimization problem that isolates the most likely physical model (differential equations) that would deliver certain physical measurements (data). The techniques described here may apply to both traditional modeling endeavors that require NR waveform data for calibration and gravitational-wave (GW) astronomy In the latter case, where the training data is comprised of GW observations, our inversion strategy avoids the need to solve or analyze Einstein’s equation of general relativity to learn the orbital model.
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