Four-dimensional direct detection with Jones space optical full-field recovery

TL;DR

This paper introduces a novel four-dimensional Jones space optical field recovery scheme that captures both intensity and phase information without a local oscillator, enabling efficient, long-distance data transmission for data centers.

Contribution

The proposed 4-D JSFR scheme is the first to recover the full optical field without LO, using deep learning, and offers a cost-effective, integrable solution for high-speed optical communications.

Findings

Achieves spectral efficiency comparable to intradyne coherent detection.

Extends transmission distance beyond fiber chromatic dispersion limits.

Eliminates the need for a local oscillator, simplifying system design.

Abstract

Data centers, the engines of the global Internet, are supported by massive high-speed optical interconnects. In optical fiber communication, the classic direct detection obtains only the intensity of the optical field, while the coherent detection counterpart utilizes both phase and polarization diversities at the expense of beating with a narrow-linewidth and high-stable local oscillator (LO). Herein, we propose and demonstrate a four-dimensional Jones space optical field recovery (4-D JSFR) scheme without LO. The information encoded on the intensity and phase of both polarizations can be captured by the polarization-diversity full-field receiver structure and subsequently extracted through deep neural network-aided field recovery. It achieves similar electrical spectral efficiency as standard intradyne coherent detection. The fully recovered optical field can extend the transmission distance beyond the power fading limitation induced by fiber chromatic dispersion. Furthermore, the LO-free advantage makes 4-D JSFR suitable for monolithic photonic integration, offering a spectrally efficient and cost-effective candidate for large-scale data center applications. Our results could motivate a fundamental paradigm shift in the optical field recovery theory and future optical transceiver design.