English

Differentiable Logical Programming for Quantum Circuit Discovery and Optimization

Quantum Physics 2026-04-10 v2 Machine Learning

Abstract

Designing high-fidelity quantum circuits remains challenging, and current paradigms often depend on heuristic, fixed-ansatz structures or rule-based compilers that can be suboptimal or lack generality. We introduce a neuro-symbolic framework that reframes quantum circuit design as a differentiable logic programming problem. Our model represents a scaffold of potential quantum gates and parameterized operations as a set of learnable, continuous ``truth values'' or ``switches,'' s[0,1]Ns \in [0, 1]^N. These switches are optimized via standard gradient descent to satisfy a user-defined set of differentiable, logical axioms (e.g., correctness, simplicity, robustness). We provide a theoretical formulation bridging continuous logic (via T-norms) and unitary evolution (via geodesic interpolation), while addressing the barren plateau problem through biased initialization. We illustrate the approach on tasks including discovery of a 4-qubit Quantum Fourier Transform (QFT) from a scaffold of 21 candidate gates. We also report hardware-aware adaptation experiments on the 156-qubit IBM Fez processor, where the method autonomously adapted to both gradual noise drift (24.2~pp over static baseline) and catastrophic hardware failure (46.7~pp post-failure improvement), using only measurement-driven gradient updates with no hardwired bias or prior path preference

Keywords

Cite

@article{arxiv.2602.08880,
  title  = {Differentiable Logical Programming for Quantum Circuit Discovery and Optimization},
  author = {Antonin Sulc},
  journal= {arXiv preprint arXiv:2602.08880},
  year   = {2026}
}
R2 v1 2026-07-01T10:28:17.085Z