标题：Front-End Narrowband Interference Mitigation for DS-UWB Receiver
作者：Xiong, Hailiang;Zhang, Wensheng;Du, Zhengfeng;He, Bo
作者机构：[Xiong, H] School of Information Science and Engineering, Shandong University, JiNan, 250100, China, School of Information Science and Engineering, Ce 更多
通讯作者地址：[Xiong, HL]Shandong Univ, Sch Informat Sci & Engn, Jinan 250100, Peoples R China.
来源：IEEE transactions on wireless communications
关键词：Ultra-wideband (UWB);adaptive filter;interference elimination;narrowband interference
摘要：Narrow band interference (NBI) suppression is one of major issues for ultra wideband (UWB) wireless communication system operating over huge spectrum occupied by narrow band wireless systems. In this paper, we propose an interference mitigation scheme based on complex-valued adaptive notch filter, which smartly exploits the substantial correlation difference of signals and removes the NBIs in UWB signal with noise by estimating the corresponding central frequencies. To obtain high speed convergence and maintain small signal distortion, a low complexity gradient algorithm for one-order basic adaptive notch filter cell is deduced. Considering that the data rate prior to despreading is extremely high, a novel time-division multiplexing (TDM) parallel approach for eliminating a single NBI is presented, which effectively simplify the hardware design especially in high speed digital signal processing. Based on the one-order basic adaptive notch filter cell, three different implementations including direct forms, linear cascade forms and TDM parallel cascade forms to eliminate multiple NBIs are developed and discussed. Theoretical analysis and simulation results indicate that the proposed scheme possesses the advantages of high convergence speed, small distortion and high stability. Furthermore, the propose scheme utilized as a preprocessing unit prior to despreading can considerably improve the interference tolerance margin of UWB systems, leading to it\'s suitable for the low complexity direct sequence (DS)-UWB receiver.