Comparison of Low Complexity Coherent Receivers for UDWDM-PONs ($\lambda$-to-the-user)

TL;DR

This paper compares low complexity coherent receivers for UDWDM-PONs, highlighting the Alamouti-coding receiver's advantages in sensitivity and hardware simplicity over traditional designs, enabling higher data rates and longer transmission distances.

Contribution

It introduces and evaluates a low complexity, polarization-independent Alamouti-coding coherent receiver for access networks, demonstrating its superior sensitivity and reduced hardware complexity.

Findings

Alamouti-coding receiver achieves lowest photons per bit (15.5 PPB) in ideal simulations.

It requires hardware complexity similar to direct-detection receivers.

Demonstrated longest transmission distance and highest spectral efficiency in full system tests.

Abstract

It is predicted that demand in optical access networks will reach multi-Gb/s per user. However, the limited performance of the direct detection receiver technology currently used in the optical network units at the customers' premises restricts data rates/user. Therefore, the concept of coherent-enabled access networks has attracted attention in recent years, as this technology offers high receiver sensitivity, inherent frequency selectivity, and linear field detection enabling the full compensation of linear channel impairments. However, the complexity of conventional (dual-polarisation digital) coherent receivers has so far prevented their introduction into access networks. Thus, to exploit the benefits of coherent technology in the ONUs, low complexity coherent receivers, suitable for implementation in ONUs, are needed. In this paper, the recently proposed low complexity coherent (i.e., polarisation-independent Alamouti-coding heterodyne) receiver is, for the first time, compared in terms of its minimum receiver sensitivity with five previously reported receiver designs, including a detailed discussion on their advantages and limitations. It is shown that the Alamouti-coding based receiver approach allows the lowest number of photons per bit (PPB) transmitted (with a lower bound of 15.5 PPB in an ideal system simulations) whilst requiring the lowest optical receiver hardware complexity. It also exhibits comparable complexity to the currently deployed direct-detection receivers, which typically require >1000 PPB. Finally, a comparison of experimentally achieved receiver sensitivities and transmission distances using these receivers is presented. The highest spectral efficiency and longest transmission distance at the highest bit rate reported using the Alamouti-coding receiver, which is also the only one, to date, to have been demonstrated in a full system bidirectional transmission.