Research on Key Technologies of Coherent PON System Above 100 Gbit/s

LI Ming; HU Rong

doi:10.13756/j.gtxyj.2024.230167

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Research on Key Technologies of Coherent PON System Above 100 Gbit/s

更新时间：2024-02-19

- Research on Key Technologies of Coherent PON System Above 100 Gbit/s
- Study on Optical Communications Issue 1, Pages: 23016701-23016704(2024)
- 作者机构：
  
  烽火通信科技股份有限公司　宽带业务产出线，武汉　430074
- 作者简介：
- 基金信息：
- DOI：10.13756/j.gtxyj.2024.230167
  CLC： TN915.6
- Published：10 February 2024，
  
  Received：22 November 2023，
  
  Revised：29 November 2023，
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李明，胡荣. 超100 Gbit/s相干PON系统关键技术研究[J]. 光通信研究，2024(1)：230167.

Li M，Hu R. Research on Key Techniques of Beyond-100 Gbit/s Coherent PON System, 2024(1)：230167.
李明，胡荣. 超100 Gbit/s相干PON系统关键技术研究[J]. 光通信研究，2024(1)：230167. DOI： 10.13756/j.gtxyj.2024.230167.

Li M，Hu R. Research on Key Techniques of Beyond-100 Gbit/s Coherent PON System, 2024(1)：230167. DOI： 10.13756/j.gtxyj.2024.230167.

摘要

50 Gbit/s无源光网络（PON）标准已趋于完善，后50 Gbit/s PON时代的技术标准尚属空白，亟待开展相关研究以推动整个产业链从系统、模块和芯片等方面提前进行布局。文章判断单波长200 Gbit/s速率和相干技术将会是继50 Gbit/s PON之后下一代PON系统的两大关键特征。单波长200 Gbit/s速率对运营商具备更大的吸引力，而强度调制/直接检测（IM/DD）技术难以持续满足200 Gbit/s速率下系统对Class C＋等级功率预算的要求，需要采用灵敏度更高的相干技术。然而PON系统是一种典型的点对多点（P2MP）拓扑架构，将相干技术下沉到PON还有许多关键技术需要攻克，其中，涉及PON系统设备和媒体访问控制（MAC）芯片的架构重构、相干PON光模块的单纤双向（Bi-Di）技术改造、突发模式的相干发送与接收技术以及相干PON系统的波长管控技术。时分复用（TDM）仍然是实现P2MP传输的推荐方式，在TDM基础之上可以叠加新的复用维度，例如子载波复用（SCM）。新复用维度的引入给PON系统带来了灵活性，但同时也增加了设计的复杂度，将会颠覆当前的PON系统架构。叠加了SCM的相干PON系统将不再采用数字化接口方式与光模块进行连接，光模块本身需要具备高度线性驱动和调制能力。此外，用户侧光模块需要具备瞬时开关能力，以避免对其他用户造成干扰，因此需要开发新型的支持突发控制功能的相干光芯片。考虑到上行P2MP的突发相干接收环境，需要从系统层面实现对多个用户激光器的波长管控，避免上行方向因多用户波长快速切换造成的局端频偏估算偏差问题。综上，将相干技术应用于PON将会是一个全新的复杂系统工程，难以直接继承现有相干系统架构，需要匹配P2MP的应用需求，从芯片、模块和设备多个方面实现技术创新。

Abstract

The standards for 50 Gbit/s Passive Optical Network (PON) are nearly complete

but the standards for the post-50 Gbit/s PON era are still blank. It is necessary to carry out relevant research to guide the industry’s strategic planning in system

optical module and chips. Experts predict that single-wavelength 200 Gbit/s rate and coherent technology will be the two key features of the next-generation PON system after 50 Gbit/s PON. Firstly

the single-wavelength 200 Gbit/s rate is particularly attractive to operators. However

Intensity Modulation and Direct Detection (IM/DD) technology struggles to meet the Class C+ power budget requirements at this speed. Therefore

it is necessary to use a coherent technology which is more sensitive than IM/DD technology. However

some technical challenges need to be overcome if coherent technology is applied to PON. As the PON system shows a typical Point-to-MultiPoint (P2MP) topology

key challenges include the architecture reconstruction of PON Media Access Control (MAC) chips and system equipment

the Bi-Di technology and the burst-mode technology of coherent PON optical modules

and the wavelength management in PON system. Time Division Multiplexing (TDM) remains the best way to achieve P2MP transmission. New multiplexing dimensions

such as Sub-Carrier Multiplexing (SCM) can enhance this method. The introduction of new multiplexing dimension adds flexibility but also complicates the design

potentially overhauling the entire PON system architecture. With SCM

digital interfaces are no longer used to connect optical modules. Instead

optical modules will need to use highly linear driver and modulator. The user-side optical modules need the ability to switch instantly to avoid interference with other users

necessitating the development of new coherent optical chips with burst-mode control functionality. Considering the uplink P2MP burst-mode coherent reception

it is necessary to control the wavelength of multiple lasers at the system level to avoid errors from frequency offset estimation

caused by rapid wavelength switching among users. In summary

applying coherent technology to PON is a completely new and complex task

which cannot directly inherit the existing coherent system architecture. It needs to match the requirement of P2MP system application

through technological innovation in chips

modules

and equipment.

关键词

相干技术50 Gbit/s无源光网络时分复用突发模式

Keywords

coherent technology50 Gbit/s PONTDMburst mode

references

Li J, Zhang X, Luo M, et al. SOA Pre-Amplified 200 Gb/s/λ PON Using High-bandwidth TFLN Modulator[C]//2022 European Conference on Optical Communication (ECOC). Basel, Switzerland: IEEE, 2022: 254930813.

Che D, Iannone P, Raybon G, et al. 200 Gb/s Bi-directional TDM-PON with 29 dB Power Budget[C]//2021 European Conference on Optical Communication (ECOC). Bordeaux, France: IEEE, 2021: 9606049.

Li G Q, Xing S Z, Li Z Y, et al.200 Gb/s/λ Coherent TDM-PON with Wide Dynamic Range of >30 dB based on Local Oscillator Power Adjustment[C]//2022 Optical Fiber Communications Conference and Exhibition (OFC). San Diego, CA, USA: IEEE, 2022: Th3E.3.

Hraghi A, Rizzelli G, Pagano A, et al.Analysis and Experiments on C Band 200 G Coherent PON based on Alamouti Polarization-insensitive Receivers[J]. Optics Express, 2022, 30(26):46782-46797.

Zhang J W, Li G Q, Xing S Z, et al.Flexible and Adaptive Coherent PON for Next-generation Optical Access Network[J]. Optical Fiber Technology, 2023, 75: 103190.

狄晗, 陈新桥, 刘晓蕊, 等. 基于反射滤波器实现载波重用无源光网络设计[J]. 光通信研究, 2021(5):31-35.

Di H, Chen X Q, Liu X R, et al.SCM/WDM-PON Design based on Reflection Filter for Carrier Reuse[J]. Study on Optical Communications, 2021(5):31-35.

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