Ultrastable optical frequency dissemination over a branching passive optical network using CDMA

TL;DR

This paper presents a CDMA-based protocol for ultrastable optical frequency dissemination in passive optical networks, enabling multiple users with high stability and reduced noise interference, suitable for complex time-frequency networks.

Contribution

The paper introduces a novel CDMA technique for optical frequency dissemination that improves capacity, noise rejection, and operational simplicity over previous methods.

Findings

Achieved frequency instability better than 10^{-18} with over 100 users.

Demonstrated rejection of phase noise caused by optical back scattering.

Showed no fundamental limit to the stability of the protocol.

Abstract

We demonstrate a technique for ultrastable optical frequency dissemination in a branching passive optical network using code-division multiple access (CDMA). In our protocol, each network user employs a unique pseudo-random sequence to rapidly change the optical frequency among many distinct frequencies. After transmission through the optical network, each user correlates the received sequence with the transmitted one, thus establishing a frequency-hopping spread spectrum technique that helps reject optical signals transmitted by other users in the network. Our method, which builds on the work by Schediwy et al. [Opt. Lett. {\bf 38}, 2893 (2013)], improves the frequency distribution network's capacity, helps reject phase noise caused by intermediate optical back scattering, and simplifies the operational requirements. Using this protocol, we show that a frequency instability better than ~$10^{-18}$ while having more than 100 users operating in the network should be possible. Finally, we theoretically explore the limits of this protocol and show that the demonstrated stability does not suffer from any fundamental limitation. In the future, the CDMA method presented here could be used in complex time-frequency distribution networks, allowing more users while, at the same time, reducing the network's complexity.