Baudrate- and Reach-Flexible All-Optical Equalization with a Co-Packaged Photonic Reservoir and Receiver

TL;DR

This paper demonstrates a novel, flexible all-optical equalization system using a co-packaged photonic reservoir and receiver, capable of supporting various baudrates and reaches with significant BER improvements.

Contribution

It introduces the first co-packaged photonic reservoir receiver and a flexible equalization method adaptable to different data rates and distances.

Findings

Achieved up to four orders of magnitude BER improvement over digital equalization.

Demonstrated all-optical equalization across 10-46 Gbaud and 10-250 km reach.

Implemented a 16-node spatially multiplexed reservoir with programmable readout.

Abstract

Intensity-modulation direct-detection links must support increasing baudrates and transmission distances while operating under stringent power and cost constraints. However, as data rates and reaches increase, chromatic dispersion induces stronger inter-symbol interference and, after direct detection, frequency-selective fading, thus requiring increasingly powerful equalization. In conventional receivers, this translates into digital equalization whose complexity scales unfavorably with data rate. Photonic-domain equalization offers a hardware-based alternative that operates naturally at line rate and mitigates frequency fading. However, prior demonstrations were not readily adaptable for different rate and/or reach operation. In this paper, we experimentally demonstrate all-optical equalization across 10-46 Gbaud and 10-250 km SSMF in the C-band enabled solely through retraining of the readout layer, achieving up to four orders of magnitude BER improvement over standard DSP equalization. The demonstrator comprises a 16-node spatially multiplexed reservoir, programmable on-chip readout, and co-packaged receiver front-end. To our knowledge, this is the first co-packaged photonic reservoir receiver and the first demonstration of simultaneous baudrate- and reach-flexible equalization using a fixed-topology integrated photonic circuit.