3 research outputs found
A robust basis for multi-bit optical communication with vectorial light
Increasing the information capacity of communication channels is a pressing
need, driven by growing data demands and the consequent impending data crunch
with existing modulation schemes. In this regard, mode division multiplexing
(MDM), where the spatial modes of light form the encoding basis, has enormous
potential and appeal, but is impeded by modal noise due to imperfect channels.
Here we overcome this challenge by breaking the existing MDM paradigm of using
the modes themselves as a discrete basis, instead exploiting the polarization
inhomogeneity (vectorness) of vectorial light as our information carrier. We
show that this encoding basis can be partitioned and detected almost at will,
and measured in a channel independent fashion, a fact we confirm experimentally
using atmospheric turbulence as a highly perturbing channel example. Our
approach replaces conventional amplitude modulation with a novel modal
alternative for potentially orders of magnitude channel information
enhancement, yet is robust to fading even through noisy channels, offering a
new paradigm to exploiting the spatial mode basis for optical communication.Comment: 15 pages, 8 figure
Revealing the invariance of vectorial structured light in complex media
Optical aberrations place fundamental limits on the achievable resolution with focusing and imaging. In the context of structured light, optical imperfections and misalignments and perturbing media such as turbulent air, underwater and optical fibre distort the amplitude and phase of the light’s spatial pattern. Here we show that polarization inhomogeneity that defines vectorial structured light is immune to all such perturbations, provided they are unitary. As an example, we study the robustness of vector vortex beams propagating through highly aberrated systems, demonstrating that the inhomogeneous nature of polarization remains unaltered even as the medium itself changes. The unitary nature of the channel allows us to undo this change through a simple lossless operation. This approach paves the way to the versatile application of vectorial structured light, even through non-ideal optical systems, crucial in applications such as imaging and optical communication across noisy channels