Efficient and Stable Computation of Gravitational-Wave Fluxes from Generic Kerr Orbits via a Unified HeunC Framework

Author(s)

Chen, Changkai, Cao, Zhoujian, Jing, Jiliang

Abstract

Modeling extreme-mass-ratio inspirals hinges on the accurate and efficient computation of gravitational-wave fluxes from generic Kerr orbits. Conventional frequency-domain techniques are often limited by costly auxiliary parameter searches and numerical instabilities in the strong-field or high-frequency regimes. We address these challenges by reformulating both the angular and radial Teukolsky equations in terms of confluent Heun functions. Employing a hybrid analytic continuation algorithm to compute the connection coefficients eliminates the dependence on auxiliary parameters, directly yielding globally convergent solutions and scattering amplitudes. To resolve the highly oscillatory source integrands for generic orbits, we implement an adaptive bi-power mapping quadrature. Comprehensive benchmarks under standard double-precision arithmetic demonstrate that, for the total radiative flux summed over 168 low-order modes, our method achieves relative errors of order $10^{-11}$, with computational costs typically reduced by factors of 2--3 and 3--10 compared to the state-of-the-art \texttt{GeneralizedSasakiNakamura.jl} and \texttt{pybhpt} packages, respectively. These demonstrated gains in precision and efficiency establish the framework as a robust tool for strong-field perturbation theory, providing the numerical foundation for high-order self-force calculations and rapid, high-precision waveform generation.

Figures

: Real part of ${\bf G}_{\ell m \omega}^{\infty}$.
Caption : Real part of ${\bf G}_{\ell m \omega}^{\infty}$.
: Imaginary part of ${\bf G}_{\ell m \omega}^{\infty}$. : Real part of ${\bf G}_{\ell m \omega}^{{\rm{H}}}$.
Caption : Imaginary part of ${\bf G}_{\ell m \omega}^{\infty}$. : Real part of ${\bf G}_{\ell m \omega}^{{\rm{H}}}$.
: Imaginary part of ${\bf G}_{\ell m \omega}^{{\rm{H}}}$. : Integrand ${\bf G}_{\ell m \omega}^{\infty, {\rm{H}}}$ with $(l,m,n,k)=(4,4,3,4)$ and $(a,p,e,x_I)=(0.9, 10, 0.7, 0.1)$.
Caption : Imaginary part of ${\bf G}_{\ell m \omega}^{{\rm{H}}}$. : Integrand ${\bf G}_{\ell m \omega}^{\infty, {\rm{H}}}$ with $(l,m,n,k)=(4,4,3,4)$ and $(a,p,e,x_I)=(0.9, 10, 0.7, 0.1)$.
: Caption not extracted
Caption : Caption not extracted
: Real part of ${\bf G}_{\ell m \omega}^{\infty}$.
Caption : Real part of ${\bf G}_{\ell m \omega}^{\infty}$.
: Imaginary part of ${\bf G}_{\ell m \omega}^{\infty}$. : Real part of ${\bf G}_{\ell m \omega}^{{\rm{H}}}$.
Caption : Imaginary part of ${\bf G}_{\ell m \omega}^{\infty}$. : Real part of ${\bf G}_{\ell m \omega}^{{\rm{H}}}$.
: Imaginary part of ${\bf G}_{\ell m \omega}^{{\rm{H}}}$. : Integrand ${\bf G}_{\ell m \omega}^{\infty, {\rm{H}}}$ with $(l,m,n,k)=(4,4,50,4)$ and $(a,p,e,x_I)=(0.9, 10, 0.9, 0.5)$.
Caption : Imaginary part of ${\bf G}_{\ell m \omega}^{{\rm{H}}}$. : Integrand ${\bf G}_{\ell m \omega}^{\infty, {\rm{H}}}$ with $(l,m,n,k)=(4,4,50,4)$ and $(a,p,e,x_I)=(0.9, 10, 0.9, 0.5)$.
: Caption not extracted
Caption : Caption not extracted
: HeunC method.
Caption : HeunC method.
: GSN method~\cite{GeneralizedSasakiNakamura}. : Logarithmic error $\log_{10}\blacktriangle \left| {{\bf{G}}_{\ell m \omega}^\infty } \right|$ for $(l,m,n,k)=(4,4,3,4)$ and $(a,p,e,x_I)=(0.1, 10, 0.7, 0.1)$. The integrand is evaluated on a $1000 \times 1000$ uniform grid in the orbital phase coordinates $(\lambda_r, \lambda_\theta)$.
Caption : GSN method~\cite{GeneralizedSasakiNakamura}. : Logarithmic error $\log_{10}\blacktriangle \left| {{\bf{G}}_{\ell m \omega}^\infty } \right|$ for $(l,m,n,k)=(4,4,3,4)$ and $(a,p,e,x_I)=(0.1, 10, 0.7, 0.1)$. The integrand is evaluated on a $1000 \times 1000$ uniform grid in the orbital phase coordinates $(\lambda_r, \lambda_\theta)$.
: QNM eigenvalues.
Caption : QNM eigenvalues.
: Errors. : QNM eigenvalues and errors with $\ell = m=2$, $0\leq n \leq 7$ and $a \in [0,0.999]$.
Caption : Errors. : QNM eigenvalues and errors with $\ell = m=2$, $0\leq n \leq 7$ and $a \in [0,0.999]$.
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