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Autori principali: Pisnoy, Shimon, Chandravamsi, Hemanth, Chen, Ziv, Goldgewert, Aaron, Shaviner, Gal, Shragner, Boris, Frankel, Steven H.
Natura: Preprint
Pubblicazione: 2026
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Accesso online:https://arxiv.org/abs/2604.15645
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author Pisnoy, Shimon
Chandravamsi, Hemanth
Chen, Ziv
Goldgewert, Aaron
Shaviner, Gal
Shragner, Boris
Frankel, Steven H.
author_facet Pisnoy, Shimon
Chandravamsi, Hemanth
Chen, Ziv
Goldgewert, Aaron
Shaviner, Gal
Shragner, Boris
Frankel, Steven H.
contents We present PINNACLE, an open-source computational framework for physics-informed neural networks (PINNs) that integrates modern training strategies, multi-GPU acceleration, and hybrid quantum-classical architectures within a unified modular workflow. The framework enables systematic evaluation of PINN performance across benchmark problems including 1D hyperbolic conservation laws, incompressible flows, and electromagnetic wave propagation. It supports a range of architectural and training enhancements, including Fourier feature embeddings, random weight factorization, strict boundary condition enforcement, adaptive loss balancing, curriculum training, and second-order optimization strategies, with extensibility to additional methods. We provide a comprehensive benchmark study quantifying the impact of these methods on convergence, accuracy, and computational cost, and analyze distributed data parallel scaling in terms of runtime and memory efficiency. In addition, we extend the framework to hybrid quantum-classical PINNs and derive a formal estimate for circuit-evaluation complexity under parameter-shift differentiation. Results highlight the sensitivity of PINNs to architectural and training choices, confirm their high computational cost relative to classical solvers, and identify regimes where hybrid quantum models offer improved parameter efficiency. PINNACLE provides a foundation for benchmarking physics-informed learning methods and guiding future developments through quantitative assessment of their trade-offs.
format Preprint
id arxiv_https___arxiv_org_abs_2604_15645
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle PINNACLE: An Open-Source Computational Framework for Classical and Quantum PINNs
Pisnoy, Shimon
Chandravamsi, Hemanth
Chen, Ziv
Goldgewert, Aaron
Shaviner, Gal
Shragner, Boris
Frankel, Steven H.
Machine Learning
Computational Physics
Quantum Physics
We present PINNACLE, an open-source computational framework for physics-informed neural networks (PINNs) that integrates modern training strategies, multi-GPU acceleration, and hybrid quantum-classical architectures within a unified modular workflow. The framework enables systematic evaluation of PINN performance across benchmark problems including 1D hyperbolic conservation laws, incompressible flows, and electromagnetic wave propagation. It supports a range of architectural and training enhancements, including Fourier feature embeddings, random weight factorization, strict boundary condition enforcement, adaptive loss balancing, curriculum training, and second-order optimization strategies, with extensibility to additional methods. We provide a comprehensive benchmark study quantifying the impact of these methods on convergence, accuracy, and computational cost, and analyze distributed data parallel scaling in terms of runtime and memory efficiency. In addition, we extend the framework to hybrid quantum-classical PINNs and derive a formal estimate for circuit-evaluation complexity under parameter-shift differentiation. Results highlight the sensitivity of PINNs to architectural and training choices, confirm their high computational cost relative to classical solvers, and identify regimes where hybrid quantum models offer improved parameter efficiency. PINNACLE provides a foundation for benchmarking physics-informed learning methods and guiding future developments through quantitative assessment of their trade-offs.
title PINNACLE: An Open-Source Computational Framework for Classical and Quantum PINNs
topic Machine Learning
Computational Physics
Quantum Physics
url https://arxiv.org/abs/2604.15645