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π Abstract
Abstract: Current self-supervised denoising techniques achieve impressive results, yet
their real-world application is frequently constrained by substantial
computational and memory demands, necessitating a compromise between inference
speed and reconstruction quality. In this paper, we present an
ultra-lightweight model that addresses this challenge, achieving both fast
denoising and high quality image restoration. Built upon the Noise2Noise
training framework-which removes the reliance on clean reference images or
explicit noise modeling-we introduce an innovative multistage denoising
pipeline named Noise2Detail (N2D). During inference, this approach disrupts the
spatial correlations of noise patterns to produce intermediate smooth
structures, which are subsequently refined to recapture fine details directly
from the noisy input. Extensive testing reveals that Noise2Detail surpasses
existing dataset-free techniques in performance, while requiring only a
fraction of the computational resources. This combination of efficiency, low
computational cost, and data-free approach make it a valuable tool for
biomedical imaging, overcoming the challenges of scarce clean training data-due
to rare and complex imaging modalities-while enabling fast inference for
practical use.
Authors (3)
TomΓ‘Ε‘ Chobola
Julia A. Schnabel
Tingying Peng
Submitted
October 17, 2025
Key Contributions
Noise2Detail (N2D) is an ultra-lightweight, data-free denoising model that achieves fast inference and high-quality restoration for biomedical images. It leverages the Noise2Noise framework and a novel multistage pipeline to disrupt noise patterns and recapture fine details without clean references.
Business Value
Improves diagnostic accuracy and efficiency in medical imaging by providing high-quality, denoised images quickly and with minimal computational overhead, aiding clinicians and researchers.