Polarimetric compressed sensing with hollow, self-assembled diffractive films

TL;DR

This paper introduces a nanophotonic approach using self-assembled hollow nanocavity arrays for polarimetric compressed sensing, enabling high-resolution imaging with fewer samples by encoding polarization and wavefront information into interference patterns.

Contribution

It presents a novel self-assembled nanostructure-based optical encoder that reduces sampling requirements for polarization imaging and integrates with neural networks for wavefront and polarization prediction.

Findings

Random optical encoders outperform ordered ones in resolution.

Self-assembled nanostructures effectively encode polarization and wavefront information.

The system achieves high-resolution polarization imaging with fewer measurements.

Abstract

Sensing light's polarization and wavefront direction enables surface curvature assessment, material identification, shadow differentiation, and improved image quality in turbid environments. Traditional polarization cameras utilize multiple sensor measurements per pixel and polarization-filtering optics, which result in reduced image resolution. We propose a nanophotonic pipeline that enables compressive sensing and reduces the sampling requirements with a low-refractive-index, self-assembled optical encoder. These nanostructures scatter light into lattice modes, which encode the wavefront direction and the polarization ellipticity in the linearly-polarized components of the diffracted, interference patterns. Combining optical encoders with a neural network, the system predicts pointing and polarization when the interference patterns are adequately sampled. A comparison of ``ordered'' and ``random'' optical encoders shows that the latter both blurs the interference patterns and achieves higher resolution. Our work centers on the unexpected modulation and spatial multiplexing of incident light polarization by self-assembled hollow nanocavity arrays as a class of materials distinct from traditional metasurfaces that will not only enable encoding for polarization and optical computing but also for compressed sensing and imaging.