Ultra-scalable clock and carrier sychronisation for optical and wireless networks using sequentially-locked optical frequency combs

使用顺序锁定光学频率梳实现光学和无线网络的超可扩展时钟和载波同步

• 批准号: 10089417
• 金额: $ 14.38万
• 依托单位: BRITISH TELECOMMUNICATIONS PUBLIC LIMITED COMPANY
• 依托单位国家: 英国
• 项目类别: Collaborative R&D
• 财政年份: 2024
• 资助国家: 英国
• 起止时间: 2024 至 无数据
• 项目状态: 未结题
• 来源: https://gtr.ukri.org/projects?ref=10089417
• 关键词: Ultra; scalable; clock; carrier; sychronisation

_All telecommunications systems, which transmit data from device to device, whether through optical fibre between continents or through the air between mobile phones and radio masts, fundamentally rely on 1\. carrier synchronisation, determining the frequency used to send the data (whether that be visible, microwaves, or radio waves), and 2\. clock synchronisation, determining the data transmission rate. Consequently, both types of synchronisation are critical to modern telecommunications system performance. Additionally, clock and carrier synchronisation is key to accurate time synchronisation - essential for synchronising the UK's critical national infrastructure (CNI), including power stations in the National Grid, our railways and our mobile and broadband networks.__Our proposal aims to address a key issue impacting the UK's CNI: our CNI is currently clock synchronised by global satellite navigation systems (GNSSs), such as GPS and Galileo. This is a major vulnerability: synchronisation provided by GNSSs may be lost due to solar storms, cyberattacks, jamming or volcanic ash obstruction. An alternative is to distribute highly accurate clocks through our existing optical fibre infrastructure. However, this brings two major research challenges: 1\. scalability: a single highly accurate clock can currently only reach up to about 1000 endpoints, 2\. optical fibre variation: distribution of clocks through optical fibre introduces inaccuracy due to variation of the fibre medium due to e.g. temperature change. There is also a major commercial challenge: how to address research challenges 1 & 2 at low cost.__To address these challenges, we propose using coupled optical frequency combs, which each output a 'comb' of light of different frequencies, all synchronised together. In this approach, thousands of comb frequencies from a central extremely high clock accuracy but expensive comb each synchronise a downstream inexpensive optical frequency comb through \>100 km optical fibre. These downstream optical frequency combs each have thousands of comb frequencies of their own, each of which clock synchronise an endpoint, allowing synchronisation of millions of endpoints from the central highly accurate frequency comb, addressing the scalability challenge. We address the optical fibre variation challenge by exploring new digital methods of measuring and compensating for the optical fibre medium variation. We address the cost challenge by exploring the miniaturisation of ultra-fast laser-based optical frequency combs. We would demonstrate our approach in a field trial optical fibre link between an extremely accurate optical frequency comb hosted by BT and low-cost ultra-fast laser-based frequency combs hosted at UCL and developed by Menhir Photonics._

无论是通过大陆之间的光纤还是通过移动的电话和无线电天线杆之间的空气，所有从设备到设备传输数据的电信系统都基本上依赖于1。载波同步，确定用于发送数据的频率（无论是可见光、微波还是无线电波），以及2.时钟同步，确定数据传输速率。因此，这两种类型的同步对于现代电信系统性能都是至关重要的。此外，时钟和载波同步是实现准确时间同步的关键，这对于同步英国关键的国家基础设施（CNI）至关重要，包括国家电网中的发电站、我们的铁路以及我们的移动的和宽带网络。我们的提案旨在解决影响英国CNI的一个关键问题：我们的CNI目前由全球卫星导航系统（GNSS）（如GPS和伽利略）进行时钟同步。这是一个重大漏洞：GNSS提供的同步可能会因太阳风暴、网络攻击、干扰或火山灰阻塞而丢失。另一种方法是通过我们现有的光纤基础设施分发高度精确的时钟。然而，这带来了两个主要的研究挑战：1。可扩展性：单个高精度时钟目前最多只能到达大约1000个端点，2\。光纤变化：通过光纤的时钟分布由于光纤介质的变化（例如温度变化）而引入不准确性。还有一个主要的商业挑战：如何以低成本解决研究挑战1和2。为了解决这些挑战，我们建议使用耦合光频梳，每个光频梳输出不同频率的光的“梳”，所有这些光都同步在一起。在这种方法中，来自中心极高时钟精度但昂贵的梳的数千个梳频率各自通过100 km光纤同步下游廉价的光频率梳。这些下游光频率梳各自具有数千个自己的梳频率，每个梳频率都与一个端点时钟同步，允许从中央高精度频率梳同步数百万个端点，从而解决可扩展性挑战。我们通过探索测量和补偿光纤介质变化的新数字方法来解决光纤变化的挑战。我们通过探索基于超快激光的光频梳的封装来解决成本挑战。我们将在现场试验光纤链路中展示我们的方法，该光纤链路由BT托管的极其精确的光学频率梳和由UCL托管并由Menhir Photonics开发的低成本超快激光频率梳之间。