English

INFER : Learning Implicit Neural Frequency Response Fields for Confined Car Cabin

Sound 2025-10-10 v1

Abstract

Accurate modeling of spatial acoustics is critical for immersive and intelligible audio in confined, resonant environments such as car cabins. Current tuning methods are manual, hardware-intensive, and static, failing to account for frequency selective behaviors and dynamic changes like passenger presence or seat adjustments. To address this issue, we propose INFER: Implicit Neural Frequency Response fields, a frequency-domain neural framework that is jointly conditioned on source and receiver positions, orientations to directly learn complex-valued frequency response fields inside confined, resonant environments like car cabins. We introduce three key innovations over current neural acoustic modeling methods: (1) novel end-to-end frequency-domain forward model that directly learns the frequency response field and frequency-specific attenuation in 3D space; (2) perceptual and hardware-aware spectral supervision that emphasizes critical auditory frequency bands and deemphasizes unstable crossover regions; and (3) a physics-based Kramers-Kronig consistency constraint that regularizes frequency-dependent attenuation and delay. We evaluate our method over real-world data collected in multiple car cabins. Our approach significantly outperforms time- and hybrid-domain baselines on both simulated and real-world automotive datasets, cutting average magnitude and phase reconstruction errors by over 39% and 51%, respectively. INFER sets a new state-of-the-art for neural acoustic modeling in automotive spaces

Keywords

Cite

@article{arxiv.2510.07442,
  title  = {INFER : Learning Implicit Neural Frequency Response Fields for Confined Car Cabin},
  author = {Harshvardhan C. Takawale and Nirupam Roy and Phil Brown},
  journal= {arXiv preprint arXiv:2510.07442},
  year   = {2025}
}
R2 v1 2026-07-01T06:24:56.385Z