All-optically untangling light propagation through multimode fibres

TL;DR

This paper introduces an all-optical method to unscramble light that has been scrambled by a multimode fibre, enabling real-time imaging and potential applications in communications and quantum photonics.

Contribution

The authors develop an optical inverter using multi-plane light conversion that can reverse light scattering in multimode fibres without computational processing.

Findings

Successfully unscrambled 30 modes through 1m MMF

Enabled near-instantaneous incoherent imaging

Demonstrated reconfigurability of the optical inverter

Abstract

When light propagates through a complex medium, such as a multimode optical fibre (MMF), the spatial information it carries is scrambled. In this work we experimentally demonstrate an all-optical strategy to unscramble this light again. We first create a digital model capturing the way light has been scattered, and then use this model to inverse-design and build a complementary optical system - which we call an optical inverter - that reverses this scattering process. Our implementation of this concept is based on multi-plane light conversion, and can also be understood as a diffractive artificial neural network or a physical matrix pre-conditioner. We present three design strategies allowing different aspects of device performance to be prioritised. We experimentally demonstrate a prototype optical inverter capable of simultaneously unscrambling up to 30 spatial modes that have propagated through a 1m long MMF, and show how this enables near instantaneous incoherent imaging, without the need for any beam scanning or computational processing. We also demonstrate the reconfigurable nature of this prototype, allowing it to adapt and deliver a new optical transformation if the MMF it is matched to changes configuration. Our work represents a first step towards a new way to see through scattering media. Beyond imaging, this concept may also have applications to the fields of optical communications, optical computing and quantum photonics.