Quantum-Informed Machine Learning for Predicting Spatiotemporal Chaos with Practical Quantum Advantage

TL;DR

This paper presents a quantum-informed machine learning framework that enhances long-term predictions of chaotic systems, demonstrating improved accuracy and stability, with potential quantum advantages in data compression and scalability.

Contribution

The authors introduce a novel QIML framework combining quantum generative models with classical predictors, achieving superior modeling of chaotic dynamics and demonstrating practical quantum benefits.

Findings

QIML improves predictive accuracy by up to 17.25% over classical methods.

QIML achieves up to 29.36% higher fidelity in full-spectrum predictions.

Quantum prior training on a superconducting quantum processor stabilizes long-term forecasts.

Abstract

We introduce a quantum-informed machine learning (QIML) framework for modelling the long-term behaviour of high-dimensional chaotic systems. QIML combines a one-time, offline-trained quantum generative model with a classical autoregressive predictor for spatiotemporal field generation. The quantum model learns a quantum prior (Q-Prior) that guides the representation of small-scale interactions and improves the modelling of fine-scale dynamics. We evaluate QIML on the Kuramoto-Sivashinsky equation, two-dimensional Kolmogorov flow, and the three-dimensional turbulent channel flow used as a realistic inflow condition. Across these systems, QIML improves predictive distribution accuracy by up to 17.25% and full-spectrum fidelity by up to 29.36% relative to classical baselines. For turbulent channel inflow, the Q-Prior is trained on a superconducting quantum processor and proves essential: without it, predictions become unstable, whereas QIML produces physically consistent long-term forecasts that outperform leading PDE solvers. Beyond accuracy, QIML offers a memory advantage by compressing multi-megabyte datasets into a kilobyte-scale Q-Prior, enabling scalable integration of quantum resources into scientific modelling.