Unexplored Opportunities for Automatic Differentiation in Astrophysics

TL;DR

This paper systematically identifies unexplored astrophysical domains where automatic differentiation can enhance optimization and exploration, introduces a unified framework (GRASP), and demonstrates potential computational advantages in various astrophysical problems.

Contribution

It is the first to systematically identify unexplored astrophysical areas suitable for automatic differentiation and to propose a unified framework (GRASP) for their implementation.

Findings

Identified nine astrophysical domains for AD application.

Extended GRAF's approach to astrophysical parameter spaces.

Proposed the GRASP framework for differentiable astrophysical computations.

Abstract

We present a systematic analysis of automatic differentiation (AD) applications in astrophysics, identifying domains where gradient-based optimization could provide significant computational advantages. Building on our previous work with GRAF (Gradient-based Radar Ambiguity Functions), which discovered optimal radar waveforms achieving 4x computational speedup by exploring the trade-off space between conflicting objectives, we extend this discovery-oriented approach to astrophysical parameter spaces. While AD has been successfully implemented in several areas including gravitational wave parameter estimation and exoplanet atmospheric retrieval, we identify nine astrophysical domains where, to our knowledge, gradient-based exploration methods remain unexplored despite favorable mathematical structure. These opportunities range from discovering novel solutions to the Einstein field equations in exotic spacetime configurations to systematically exploring parameter spaces in stellar astrophysics and planetary dynamics. We present the mathematical foundations for implementing AD in each domain and propose GRASP (Gradient-based Reconstruction of Astrophysical Systems & Phenomena), a unified framework for differentiable astrophysical computations that transforms traditional optimization problems into systematic exploration of solution spaces. To our knowledge, this is the first work to systematically delineate unexplored domains in astrophysics suitable for automatic differentiation and to provide a unified, mathematically grounded framework (GRASP) to guide their implementation.