Large-Area Fabrication-aware Computational Diffractive Optics
Journal:
arXiv
Published Date:
May 28, 2025
Abstract
Differentiable optics, as an emerging paradigm that jointly optimizes optics
and (optional) image processing algorithms, has made innovative optical designs
possible across a broad range of applications. Many of these systems utilize
diffractive optical components (DOEs) for holography, PSF engineering, or
wavefront shaping. Existing approaches have, however, mostly remained limited
to laboratory prototypes, owing to a large quality gap between simulation and
manufactured devices. We aim at lifting the fundamental technical barriers to
the practical use of learned diffractive optical systems. To this end, we
propose a fabrication-aware design pipeline for diffractive optics fabricated
by direct-write grayscale lithography followed by nano-imprinting replication,
which is directly suited for inexpensive mass production of large area designs.
We propose a super-resolved neural lithography model that can accurately
predict the 3D geometry generated by the fabrication process. This model can be
seamlessly integrated into existing differentiable optics frameworks, enabling
fabrication-aware, end-to-end optimization of computational optical systems. To
tackle the computational challenges, we also devise tensor-parallel compute
framework centered on distributing large-scale FFT computation across many
GPUs. As such, we demonstrate large scale diffractive optics designs up to
32.16 mm $\times$ 21.44 mm, simulated on grids of up to 128,640 by 85,760
feature points. We find adequate agreement between simulation and fabricated
prototypes for applications such as holography and PSF engineering. We also
achieve high image quality from an imaging system comprised only of a single
DOE, with images processed only by a Wiener filter utilizing the simulation
PSF. We believe our findings lift the fabrication limitations for real-world
applications of diffractive optics and differentiable optical design.
