{"title":"采用 InP 聚合物混合光子集成技术的 800 Gb/s O 波段波分复用集成光收发器","authors":"Efstathios Andrianopoulos;Konstantinos Tokas;David de Felipe;Michael Theurer;Madeleine Weigel;Annachiara Pagano;Kostantina Kanta;Martin Kresse;Giorgos Megas;Christos Tsokos;Christos Kouloumentas;Anna Chiado Piat;Zerihun Tegegne;Maria Massaouti;Paraskevas Bakopoulos;Martin Moehrle;Patrick Runge;Norbert Keil;Panos Groumas;Hercules Avramopoulos","doi":"10.1364/JOCN.522903","DOIUrl":null,"url":null,"abstract":"We propose and demonstrate a novel O-band wavelength division multiplexing (WDM) optical transceiver enabled by the hybrid photonic integration of indium phosphide (InP) components into a polymer-based photonic motherboard called PolyBoard. The optical engine hosts an eight-fold InP electro-absorption modulated laser (EML) array at the transmitter part exhibiting \n<tex>${\\gt}{{35}}\\;{\\rm{GHz}}$</tex>\n electro-optical bandwidth and an eight-fold InP photodiode (PD) array at the receiver part with 50 GHz bandwidth, butt-end coupled to the PolyBoard motherboard, which accommodates passive arrayed waveguide gratings (AWGs) at the transmitter and receiver sides, responsible for performing the wavelength multiplexing and demultiplexing functionalities, respectively. What we believe to be a novel thin-film-based O-band half-wave plate is placed at the receiver side AWG, ensuring the polarization insensitivity of the prototype. The optical engine’s design is discussed in the manuscript, demonstrating experimental results from its static and dynamic evaluation. Individual characterization of the transmitter and receiver sides of the optical engine is presented before evaluating the optical engine as a whole in a loopback configuration. The obtained results underscore the potential of the proposed hybrid photonic integrated transceiver for supporting 800 Gb/s capacity in intra-datacenter optical interconnects for transmission distances up to 2 km.","PeriodicalId":50103,"journal":{"name":"Journal of Optical Communications and Networking","volume":"16 8","pages":"D44-D52"},"PeriodicalIF":4.0000,"publicationDate":"2024-06-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Integrated 800 Gb/s O-band WDM optical transceiver enabled by hybrid InP-polymer photonic integration\",\"authors\":\"Efstathios Andrianopoulos;Konstantinos Tokas;David de Felipe;Michael Theurer;Madeleine Weigel;Annachiara Pagano;Kostantina Kanta;Martin Kresse;Giorgos Megas;Christos Tsokos;Christos Kouloumentas;Anna Chiado Piat;Zerihun Tegegne;Maria Massaouti;Paraskevas Bakopoulos;Martin Moehrle;Patrick Runge;Norbert Keil;Panos Groumas;Hercules Avramopoulos\",\"doi\":\"10.1364/JOCN.522903\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"We propose and demonstrate a novel O-band wavelength division multiplexing (WDM) optical transceiver enabled by the hybrid photonic integration of indium phosphide (InP) components into a polymer-based photonic motherboard called PolyBoard. The optical engine hosts an eight-fold InP electro-absorption modulated laser (EML) array at the transmitter part exhibiting \\n<tex>${\\\\gt}{{35}}\\\\;{\\\\rm{GHz}}$</tex>\\n electro-optical bandwidth and an eight-fold InP photodiode (PD) array at the receiver part with 50 GHz bandwidth, butt-end coupled to the PolyBoard motherboard, which accommodates passive arrayed waveguide gratings (AWGs) at the transmitter and receiver sides, responsible for performing the wavelength multiplexing and demultiplexing functionalities, respectively. What we believe to be a novel thin-film-based O-band half-wave plate is placed at the receiver side AWG, ensuring the polarization insensitivity of the prototype. The optical engine’s design is discussed in the manuscript, demonstrating experimental results from its static and dynamic evaluation. Individual characterization of the transmitter and receiver sides of the optical engine is presented before evaluating the optical engine as a whole in a loopback configuration. 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引用次数: 0
摘要
我们提出并演示了一种新型 O 波段波分复用(WDM)光收发器,该收发器通过将磷化铟(InP)元件混合光子集成到名为 PolyBoard 的聚合物基光子主板中来实现。该光学引擎在发射器部分安装了一个八倍 InP 电吸收调制激光器(EML)阵列,具有 ${\gt}{35}}\;{\rm{GHz}}$电光带宽,接收器部分有一个带宽为50 GHz的八倍InP光电二极管(PD)阵列,对接端耦合到PolyBoard主板上,该主板在发射器和接收器一侧安装了无源阵列波导光栅(AWG),分别负责执行波长复用和解复用功能。我们认为,接收器侧的波导光栅采用了一种基于薄膜的新型 O 波段半波板,确保了原型的偏振不敏感性。手稿中讨论了光学引擎的设计,并展示了其静态和动态评估的实验结果。在对环回配置中的整个光学引擎进行评估之前,先介绍了光学引擎发射端和接收端的单独特性。所获得的结果证明了所提出的混合光子集成收发器在数据中心内部光互连中支持 800 Gb/s 容量的潜力,其传输距离可达 2 千米。
We propose and demonstrate a novel O-band wavelength division multiplexing (WDM) optical transceiver enabled by the hybrid photonic integration of indium phosphide (InP) components into a polymer-based photonic motherboard called PolyBoard. The optical engine hosts an eight-fold InP electro-absorption modulated laser (EML) array at the transmitter part exhibiting
${\gt}{{35}}\;{\rm{GHz}}$
electro-optical bandwidth and an eight-fold InP photodiode (PD) array at the receiver part with 50 GHz bandwidth, butt-end coupled to the PolyBoard motherboard, which accommodates passive arrayed waveguide gratings (AWGs) at the transmitter and receiver sides, responsible for performing the wavelength multiplexing and demultiplexing functionalities, respectively. What we believe to be a novel thin-film-based O-band half-wave plate is placed at the receiver side AWG, ensuring the polarization insensitivity of the prototype. The optical engine’s design is discussed in the manuscript, demonstrating experimental results from its static and dynamic evaluation. Individual characterization of the transmitter and receiver sides of the optical engine is presented before evaluating the optical engine as a whole in a loopback configuration. The obtained results underscore the potential of the proposed hybrid photonic integrated transceiver for supporting 800 Gb/s capacity in intra-datacenter optical interconnects for transmission distances up to 2 km.
期刊介绍:
The scope of the Journal includes advances in the state-of-the-art of optical networking science, technology, and engineering. Both theoretical contributions (including new techniques, concepts, analyses, and economic studies) and practical contributions (including optical networking experiments, prototypes, and new applications) are encouraged. Subareas of interest include the architecture and design of optical networks, optical network survivability and security, software-defined optical networking, elastic optical networks, data and control plane advances, network management related innovation, and optical access networks. Enabling technologies and their applications are suitable topics only if the results are shown to directly impact optical networking beyond simple point-to-point networks.