Order recognition by Schubert polynomials generated by optical near-field statistics via nanometre-scale photochromism

TL;DR

This paper demonstrates an order recognition algorithm using Schubert polynomials generated from optical near-field patterns in nanometre-scale photochromism, outperforming traditional methods by exploiting inversion relations without estimating reward probabilities.

Contribution

It introduces a novel order recognition method based on Schubert calculus and optical near-field statistics, highlighting a new intersection of nanophotonics and mathematical permutation operations.

Findings

Optical near-field patterns generate Schubert polynomials for order recognition.

The method outperforms traditional probability-based algorithms.

Recognition performance correlates with the singularity count in Schubert polynomials.

Abstract

We have previously observed an irregular spatial distribution of photon transmission through a photochromic crystal photoisomerized by a local optical near-field excitation, manifesting complex branching processes via the interplay of deformation of the material and near-field photon transfer therein. Furthermore, by combining such naturally constructed complex photon transmission with a simple photon detection protocol, Schubert polynomials, the foundation of versatile permutation operations in mathematics, have been generated. In this study, we demonstrate an order recognition algorithm inspired by Schubert calculus using optical near-field statistics via nanometre-scale photochromism. More specifically, by utilizing Schubert polynomials generated via optical near-field patterns, we show that the order of slot machines with initially unknown reward probability is successfully recognized. We emphasize that, unlike conventional algorithms in the literature, the proposed principle does not estimate the reward probabilities. Instead, it exploits the inversion relations contained in the Schubert polynomials. To quantitatively evaluate the impact of the Schubert polynomials generated from an optical near-field pattern, order recognition performances are compared with uniformly distributed and spatially strongly skewed probability distributions, where the optical near-field pattern outperforms the others. We found that the number of singularities contained in Schubert polynomials and that of the given problem or considered environment exhibits a clear correspondence, indicating that superior order recognition performances may be attained if the singularity of the given problem is presupposed. This study paves a new way toward nanophotonic intelligent devices and systems by the interplay of complex natural processes and mathematical insights gained by Schubert calculus.