Litcius/Paper detail

A Fiber-Transmission-Assisted Fast Digital Self-Interference Cancellation for Overcoming Multipath Effect and Nonlinear Distortion

Congrui Gao, Zihang Zhu, He Li, Guodong Wang, Tao Zhou, Xuan Li, Qingqing Meng, Yixiao Zhou, Shanghong Zhao

2023Journal of Lightwave Technology13 citationsDOI

Abstract

Self-interference (SI) influenced the recovery of the signal of interest (SOI) in In Band Full Duplex (IBFD) radio-over-fiber (ROF) links. The multipath effect and nonlinear distortion aggravate the difficulty of the SI signal elimination. A fiber-transmission-assisted digital self-interference cancellation (DSIC) scheme is proposed to solve the problem at a low time complexity. The key to removing the impact of harmful factors is combined with the advantages of photonics architecture and digital filter algorithm. A fiber-transmission-assisted scheme achieves the transmission of reference signals with all the linear and nonlinear features which transform the nonlinear problem into a linear question for DSIC subsequently. In DSIC, a fast transversal recursive least-squares (FTRLS) algorithm realizes a fast-channel estimating process when the SOI is involved. For 10 km fiber transmission, exceeding 38 dB and 34 dB cancellation depth over 50 MHz bandwidth in the X band and Ku band are experimentally demonstrated, and 25 Mbaud 16-quadrature amplitude modulation (16-QAM) SOI is successfully recovered after SIC. In addition, FTRLS merely consumed 7N + 14 multiplication times at each iteration (filter order N) in the channel estimating process, which saves multiplications amount above 86% than RLS, DNN, Volterra-RLS algorithm, when N is equal to 80.

Topics & Concepts

Electronic engineeringSingle antenna interference cancellationMultipath propagationQuadrature amplitude modulationComputer scienceNonlinear distortionQAMTransmission (telecommunications)Bandwidth (computing)Distortion (music)TelecommunicationsBit error rateChannel (broadcasting)EngineeringAmplifierFull-Duplex Wireless CommunicationsAdvanced Photonic Communication SystemsMagneto-Optical Properties and Applications