Point-to-point intensity modulation and direct detection flexible transceivers incorporating cascaded inverse fast fourier transform/fast fourier transform-based multi-channel aggregation/de-aggregation techniques
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In: IET Optoelectronics, Vol. 18, No. 1-2, 27.02.2024, p. 41-47.
Research output: Contribution to journal › Article › peer-review
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T1 - Point-to-point intensity modulation and direct detection flexible transceivers incorporating cascaded inverse fast fourier transform/fast fourier transform-based multi-channel aggregation/de-aggregation techniques
AU - Chen, Lin
AU - Wang, Xinyu
AU - Jin, Wei
AU - Huang, Xiaoyu
AU - Yang, Gang
AU - Jiang, Mingyang
AU - Tang, Jianming
PY - 2024/2/27
Y1 - 2024/2/27
N2 - AbstractPoint‐to‐point (P2P) flexible transceivers are the key technical enabler to cost‐effectively offer fast, dynamic, and ‘just‐the‐right‐size’ ultra‐dense P2P connectivity for various applications including remote equipment control and distributed fibre networks. However, existing flexible transceivers originally designed for hub‐and‐spoke traffic patterns are sub‐optimal. To effectively address such technical issue, a P2P flexible transceiver incorporating a cascaded inverse fast fourier transform/fast fourier transform‐based multi‐channel aggregation/de‐aggregation technique and analogue in‐phase and quadrature (IQ) mixers is proposed and numerically evaluated in a 56Gbps@20 km intensity modulation and direct detection transmission system. The proposed P2P flexible transceivers not only support adaptive and flexible variations in both channel count and channel line rate but also offer additional physical layer network security.
AB - AbstractPoint‐to‐point (P2P) flexible transceivers are the key technical enabler to cost‐effectively offer fast, dynamic, and ‘just‐the‐right‐size’ ultra‐dense P2P connectivity for various applications including remote equipment control and distributed fibre networks. However, existing flexible transceivers originally designed for hub‐and‐spoke traffic patterns are sub‐optimal. To effectively address such technical issue, a P2P flexible transceiver incorporating a cascaded inverse fast fourier transform/fast fourier transform‐based multi‐channel aggregation/de‐aggregation technique and analogue in‐phase and quadrature (IQ) mixers is proposed and numerically evaluated in a 56Gbps@20 km intensity modulation and direct detection transmission system. The proposed P2P flexible transceivers not only support adaptive and flexible variations in both channel count and channel line rate but also offer additional physical layer network security.
KW - Atomic and Molecular Physics, and Optics
KW - Electrical and Electronic Engineering
U2 - 10.1049/ote2.12115
DO - 10.1049/ote2.12115
M3 - Article
VL - 18
SP - 41
EP - 47
JO - IET Optoelectronics
JF - IET Optoelectronics
SN - 1751-8768
IS - 1-2
ER -