Fourier pixels for reciprocal light control

TL;DR

This paper introduces Fourier pixels based on plasmonic surface waves and Fourier analysis, enabling reciprocal control of light detection and emission with full amplitude, phase, and polarisation manipulation, advancing adaptive optics and holography.

Contribution

It presents a novel, scalable platform of multifunctional Fourier pixels capable of both sensing and generating complex optical wavefronts, a significant step beyond existing single-function pixels.

Findings

Demonstrated arbitrary wavefront generation using Fourier microstructures.

Achieved full characterization of incoming light's amplitude, phase, and polarisation.

Established a universal architecture for vectorially programmable optical pixels.

Abstract

Digital cameras and displays utilise picture elements (pixels) that perform a single function: detecting or emitting light intensity. To exploit the full information content of electromagnetic waves, more advanced elements are required. This has driven the development of multifunctional components, which for example, simultaneously detect and emit intensity or extract intensity and spectral information. However, no pixel exists that both senses and generates optical wavefronts with full control over amplitude, phase, and polarisation, limiting reciprocal control and feedback of sophisticated light fields. Here we present a route to such pixels by demonstrating a versatile platform of miniaturised diffractive elements based on Fourier optics. We exploit plasmonic surface waves, which propagate coherently and efficiently across metallic surfaces. When these plasmons are launched towards wavy microstructures designed with simple Fourier analysis, arbitrary and background-free optical wavefronts are generated. Conversely, incoming light can be sensed and its amplitude, phase, and polarisation fully characterised. By combining or superposing several such components, we create multifunctional 'Fourier pixels' that provide compact and accurate control over the optical field. Our approach, which could also use photonic waveguide modes, establishes a scalable, universal architecture for vectorially programmable pixels with applications in adaptive optics, holographic displays, optical communication, and quantum-information processing.