Compressively sampling the optical transmission matrix of a multimode fibre

0543621 - ÚPT 2022 RIV GB eng J - Journal Article
Li, S. - Saunders, C. - Lum, D. J. - Murray-Bruce, J. - Goyal, V. K. - Čižmár, Tomáš - Phillips, D. B.
Compressively sampling the optical transmission matrix of a multimode fibre.
Light-Science & Applications. Roč. 10, č. 1 (2021), č. článku 88. ISSN 2047-7538. E-ISSN 2047-7538
R&D Projects: GA MŠMT EF15_003/0000476
Institutional support: RVO:68081731
Keywords : multimode fibers * optical communication * optical transmission matrix * probe measurements * sampling strategies * micromanipulators * matrix algebra * aberration correction * accurate estimation
OECD category: Optics (including laser optics and quantum optics)
Impact factor: 20.257, year: 2021
Method of publishing: Open access
https://www.nature.com/articles/s41377-021-00514-9

The measurement of the optical transmission matrix (TM) of an opaque material is an advanced form of space-variant aberration correction. Beyond imaging, TM-based methods are emerging in a range of fields, including optical communications, micro-manipulation, and computing. In many cases, the TM is very sensitive to perturbations in the configuration of the scattering medium it represents. Therefore, applications often require an up-to-the-minute characterisation of the fragile TM, typically entailing hundreds to thousands of probe measurements. Here, we explore how these measurement requirements can be relaxed using the framework of compressive sensing, in which the incorporation of prior information enables accurate estimation from fewer measurements than the dimensionality of the TM we aim to reconstruct. Examples of such priors include knowledge of a memory effect linking the input and output fields, an approximate model of the optical system, or a recent but degraded TM measurement. We demonstrate this concept by reconstructing the full-size TM of a multimode fibre supporting 754 modes at compression ratios down to similar to 5% with good fidelity. We show that in this case, imaging is still possible using TMs reconstructed at compression ratios down to similar to 1% (eight probe measurements). This compressive TM sampling strategy is quite general and may be applied to a variety of other scattering samples, including diffusers, thin layers of tissue, fibre optics of any refractive profile, and reflections from opaque walls. These approaches offer a route towards the measurement of high-dimensional TMs either quickly or with access to limited numbers of measurements.
Permanent Link: http://hdl.handle.net/11104/0320813