Quadrature-Aware Complex-Linear Neural Operator for Boundary-to-Field Prediction in Resonant Acoustics
Preprint, 2026

Repeated prediction of acoustic fields from spatially distributed boundary excitation is computationally expensive when each source realization requires a new wave simulation. This work introduces a quadrature-aware complex-linear boundary operator (CLBO) that maps complex normal velocity on a vibrating surface to complex pressure at receiver locations. The model couples learned source and receiver basis functions through an explicit complex surface-quadrature contraction, so the boundary excitation enters linearly by construction. This preserves complex superposition, homogeneity, and zero response to zero excitation, while representing the source through coordinates, normals, and quadrature weights rather than a fixed flattened input vector. Reference data were generated using a verified three-dimensional multiple-relaxation-time (MRT) lattice Boltzmann solver and stored in a solver-agnostic boundary-to-field format. CLBO was compared with a fixed-sensor complex DeepONet under matched case splits and optimization settings, with additional tests of structural consistency, receiver-coordinate interpolation, source discretization, source-family holdout, label efficiency, physics-informed ablations, unseen source mixtures, and computational cost. Across five training seeds, CLBO achieved a mean complex relative field error of 0.184 +/- 0.00771, compared with 0.367 +/- 0.00742 for DeepONet. Its measured source-superposition error was 1.31 x 10^-7, and its mean error on newly simulated mixed-source cases was 0.237, compared with 0.415 for DeepONet. Inference was 1.83 x 10^4 faster than the reference calculation for the reported query size. These results show that enforcing the known complex-linear boundary-to-field structure improves physical consistency and generalization under distributed acoustic excitation.

boundary excitation

Neural operator

complex linearity

lattice Boltzmann method

resonant acoustics

surface quadrature

Author

Muhammad Idrees Khan

Chalmers, Mechanics and Maritime Sciences (M2), Marine Technology

Huadong Yao

Chalmers, Mechanics and Maritime Sciences (M2), Marine Technology

3D Virtual Platform for Digitalization of Holistic Acoustic Environment in Cabs of Heavy-Duty Vehicles (OCTAVE)

Swedish Energy Agency (P2024-01011), 2024-10-01 -- 2027-09-30.

Subject Categories (SSIF 2025)

Solid and Structural Mechanics

Fluid Mechanics

Other Mechanical Engineering

Vehicle and Aerospace Engineering

Applied Mechanics

DOI

10.48550/arXiv.2607.04407

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7/8/2026 8