Spatially multiplexed single-photon sources based on binary-tree multiplexers with optimized structure

TL;DR

This paper presents a systematic method to optimize binary-tree multiplexers for spatially multiplexed single-photon sources, significantly enhancing their single-photon probability by considering all possible configurations and system loss parameters.

Contribution

The authors develop a comprehensive optimization procedure for binary-tree multiplexers that maximizes single-photon probability considering realistic loss parameters.

Findings

Optimal multiplexers outperform other spatial multiplexers in single-photon probability.

The method is effective even for small system sizes typical in current experiments.

Optimized structures are feasible with experimentally realizable transmission and detection efficiencies.

Abstract

We develop a method for optimizing the structure of general binary-tree multiplexers realized with asymmetric photon routers aiming at improving the performance of spatially multiplexed single-photon sources. Our procedure systematically considers all possible binary-tree multiplexers that can be formed by a certain number of photon routers. Using this method one can select the multiplexer structure that leads to the highest single-photon probability for a given set of loss parameters characterizing the system. We determine the optimal general binary-tree multiplexers for experimentally realizable values of the transmission coefficients of the photon routers and that of the detector efficiency. We show that single-photon sources based on such optimal multiplexers yield higher single-photon probabilities than that can be achieved with single-photon sources based on any other spatial multiplexer considered in the literature. Our approach improves the performance of multiplexed single-photon sources even for small system sizes which is the typical situation in current experiments.