Broadband, compact, and training-free optical processors for parallel image classification
Abstract
As artificial intelligence becomes increasingly prevalent, the demand for faster and more energy-efficient computing approaches grows. While optical computing offers intrinsic advantages in bandwidth and power consumption, existing implementations remain bulky, wavelength-specific, and dependent on complex training procedures, limiting scalability and parallel operation. In this work, we demonstrate a compact, training-free optical processor based on wavy diffractive features, known as Fourier surfaces, for parallel image classification. Our device achieves classification accuracies of up to 84% for digit datasets and 66% for fashion datasets within a 4040 m footprint. The diffractive layer inherently separates incident wavelengths into distinct output directions, enabling broadband operation and allowing multiple colors to function as independent computation channels. As a result, this passive system supports up to 20 simultaneous computations within a single optical pass. These results highlight the potential of nanoscale diffractive systems to achieve high compute densities, paving the way for scalable, low-power optical processors for machine learning and image-recognition applications.
Cite
@article{arxiv.2602.18778,
title = {Broadband, compact, and training-free optical processors for parallel image classification},
author = {Sander J. W. Vonk and Boris de Jong and Yannik M. Glauser and David B. Seda and Matthieu F. Bidaut and Benjamin Savinson and Hannah Niese and David J. Norris},
journal= {arXiv preprint arXiv:2602.18778},
year = {2026}
}