Equalization Reconstruction Algorithm Based on Reference Signal Frequency Domain Block Joint for DTMB-Based Passive Radar

Channel equalization plays a pivotal role within the reconstruction phase of passive radar reference signals.In the context of reconstructing digital terrestrial multimedia broadcasting(DTMB)signals for low-slow-small(LSS)target detection,a novel frequency domain block joint equalization algorithm is presented in this article.From the DTMB signal frame structure and channel multipath transmission characteristics,this article adopts a unconventional approach where the delay and frame structure of each DTMB signal frame are reconfigured to create a circular convolution block,facilitating concurrent fast Fourier transform(FFT)calculations.Following equalization,an inverse fast Fourier transform(IFFT)-based joint output and subsequent data reordering are executed to finalize the equalization process for the DTMB signal.Simulation and measured data confirm that this algorithm outperforms conventional techniques by reducing signal errors rate and enhancing real-time processing.In passive radar LSS detection,it effectively suppresses multipath and noise through frequency domain equalization,reducing false alarms and improving the capabilities of weak target detection.

Linear and Nonlinear Time Domain Block Equalizers on MIMO Frequency Selective Channels

Single-Carrier (SC) transmission with the same bandwidth as Multi-Carrier (MC) transmission (such as OFDM) may have far shorter symbol duration and is considered to be more robust against time selective fading. In this paper, we proposed the novel equalization and signal separation schemes in time domain for short block length transmission, i.e., Block Linear Equalization (BLE) and Block Nonlinear Equalization (BNLE) on MIMO frequency selective fading channels. The proposed BLE uses the MMSE based inverse matrix in time domain and the BNLE utilizes the QRD-M (QR Decomposition with M algorithm) with appropriate receiver complexity. We compared the computational complexity among the conventional SC-FDE (Frequency Domain Equalization) scheme and the proposed equalizers. We also used the Low-Density Parity Check (LDPC) decoder concatenated to the proposed BLE and BNLE.

Simulation Research of IEEE802.16a Single Carrier Frequency Domain Equalization Scheme

IEEE 802.16a is a wideband wireless access standard of the new generation,which is submitted by ITU on Apr. 2002.The standard advises to use OFDM or Single Carrier Frequency Domain Equalization in physical layer.As a part of the national 863 research project,this paper investigates SC-FDE scheme of wideband wireless access systems.We set up an integrate simulation platform and put forward a SC-FDE scheme combining with MIMO and RS-CC to improve the system performance further.

基于时频域联合数据辅助MIMO均衡算法的多维度复用千公里级相干传输系统

基于少模光纤的模式复用系统利用单根纤芯中的正交模式实现各独立信道的并行传输,能够有效提升系统容量,解决单模光纤系统的容量危机.本文联合使用模式复用、波分复用与偏振复用技术,基于六模渐变型光纤实现了80个波长通道下32 Gbaud四模双偏振16阶正交振幅调制信号的1000 km相干传输,并在接收端使用时频域联合数据辅助8×8多输入多输出最小均方算法,以补偿由光纤传输导致的模式耦合及模间色散等线性损伤.与传统的纯时域或纯频域多输入输出最小均方均衡算法相比,该算法分别实现了57.1%的收敛速度提升与25.1%的收敛误差下降.经过1000 km少模光纤传输后,80通道每个模式及偏振态的误码率均低于开销为20%的软判决前向纠错编码阈值2.4×10^(-2),系统净速率达68.2 Tbit/s.

基于循环前缀的空分复用系统均衡技术研究

【目的】在空分复用系统中,为了实现模式解复用,需要在接收端采用多入多出(MIMO)的均衡方案。随着传输模式数或者传输容量的上升,MIMO的计算复杂度急剧升高,致使对应的硬件模块功耗过大,必须降低MIMO均衡的计算复杂度。【方法】针对少模光纤短距传输系统,文章提出了用基于循环前缀(CP)的频域联合均衡技术来代替基于块卷积且带有独立色散补偿模块的频域均衡技术以降低MIMO均衡计算复杂度。【结果】基于VPI仿真软件中的少模光纤模型,搭建了6×6少模光纤仿真平台验证所提技术的性能与计算复杂度。仿真结果表明,在训练符号长度有限的前提下,不同CP占比的均衡性能和计算复杂度降低也有所差异。相同仿真条件下,CP占比越大,计算复杂度降低越大;CP占比越小,计算复杂度降低越小。在保持均衡性能一致的前提下,CP占比为11.11%的频域均衡方案的计算复杂度仅为传统的基于块卷积的频域均衡方案的15.29%。【结论】在均衡性能保持一致的前提下,相较于传统的基于块卷积且带有单独的色散补偿模块的频域均衡方案,文章所提出的添加CP的频域均衡方案具有更低的计算复杂度。

基于5G的低轨道卫星通信系统传输技术研究

传输是低轨道卫星通信系统运行过程中的重要环节,但是现行传输技术应用效果并不理想,不仅误码率比较高,而且传输吞吐量较低。针对现行技术存在的不足,提出基于5G的低轨道卫星通信系统传输技术。利用频域均衡方法对低轨道卫星通信上行链路用户信号进行检测,补偿误差信号,利用5G技术估计通信系统下行链路信道,消除信号干扰,实现基于5G的低轨道卫星通信系统传输。实验证明:该技术低轨道卫星通信系统传输误码率不足1%,系统吞吐量超过40 Mbps。该技术在低轨道卫星通信领域具有良好的应用前景。

SYSTEMATIC DESIGN OF SINGLE CARRIER OVERLAP FREQUENCY DOMAIN EQUALIZATION

This paper proposes a systematic design method of overlap frequency domain equalization(FDE) for single carrier (SC) transmission without a guard interval (GI).Based on the analysis of signal-to-interference-plus-noise ratio (SINR) of the equalizer output for each symbol,the authors adaptivelydetermine the block of the overlap FDE,where the block is defined as a set of symbols at the equalizeroutput with sufficiently low error rate,for a certain fixed sliding window size,which corresponds toa fast Fourier transform (FFT) window size.The proposed method takes advantage of the fact thatthe utility part of the equalized signal is localized around the center of the FFT window.In addition,the authors also propose to adjust the block size in order to control the computational complexity ofthe equalization per processed sample associating with the average bit error rate (BER) of the system.Simulation results show that the proposed scheme can achieve comparable BER performance to theconventional SC-FDE scheme with sufficient GI insertion for both the coded and uncoded cases withvarious modulation levels,while requiring lower computational complexity compared to the SC overlapFDE transmission with the fixed block.

Fast frequency-domain equalization for single-carrier V-BLAST systems over multipath channel

A low complex minimum mean-square error frequency-domain decision feedback （MMSE-FDDF） equalization algorithm is proposed in this paper for the single-carrier V-BLAST systems. Exploiting the factor that the discrete Fourier transform （DFT） is unitary, the proposed receiver can equalize the signals by the MMSE detecting to the spectrums in the frequency domain instead of the waveforms in the time domain. In order to obtain the right decisions, the detector must be able to equalize the overall spectrum with regard to each layer. This work can be performed very efficiently since the system matrix has been designed as a special block-circulant-block matrix. Similar to other V-BLAST-like systems, the detecting order has strong impact on the performance of MMSE-FDDF. Therefore, we further give a fast optimally sorting scheme for the MMSE-FDDF architecture. By using the newly constructed matrix, the coefficients computation and the sorting can be combined into one process, and then we employ the modified Gram-Schmidt （MGS） to simplify the process. The simulation results and the computational complexity analysis show that the proposed MMSE-FDDF has better tradeoff between the performance and the complexity than the existing algorithms. In addition, MMSE-FDDF can avoid the performance floor caused by the overlap-and-save technique in the severe dispersive channel.

用于MIMO SC-FDE系统逼近分集接收界的迭代检测算法

为了提高MIMO SC-FDE系统的检测可靠性、降低系统复杂度,提出一种新的迭代干扰消除检测算法,并推导出分集接收界作为评价算法性能优劣的依据.该检测算法采用基本的线性均衡算法提供初始值,在迭代中尽量消除层间干扰,利用空间分集增益逐步提高检测可靠性.结果表明,该算法在4QAM调制方式下,E b/N 0为9 dB时逼近分集接收界;在16QAM调制方式下,E b/N 0为16 dB时逼近分集接收界.该算法一轮迭代的计算复杂度与发射天线的数目成线性关系,天线规模为3×3以上时算法复杂度低于V-BLAST.因此,所提算法适用于天线规模数大于等于3、调制进制数大于等于4的系统中,在倾向于采用large MIMO系统的5G及后5G时代具有高效性和实用性.

被动窃听环境中基于信道状态信息的物理层安全预编码设计

在被动窃听的多径信道场景下,窃听者(EaVEsdropper,Eve)仅被动窃听,不发射任何无线电信号,发射端(Alice)无法确定Eve的任何信息,给信息的安全传输带来了极大挑战。为了保障信息的安全传输,在Alice已知合法接收者(Bob)的信道状态信息(CSI)但是未知Eve的CSI的情况下,提出一种保障Bob的物理层安全的预编码方案,通过提高Bob接收信号的质量来提高系统的安全性能。首先,在不考虑Eve的情况下,仅根据已知的Bob的CSI给出可达Bob信道容量上界的预编码方案;利用Alice-Bob和Alice-Eve链路之间的信道特异性获得稳定的安全容量;然后,在瑞利平坦衰落环境下,通过Bob的中断概率推导出Bob的平均误码率(BER)准确的闭合表达式。仿真实验结果表明,所提方案在不改变接收机复杂度的基础上,能够保证Bob的信道容量始终优于Eve的信道容量。同时,所提方案能够在Eve的BER性能受到较大抑制的条件下,有效改善Bob的BER性能,即使Eve位置条件优于Bob也能保证安全容量始终存在。

基于KNN信道识别算法的无前后缀频域均衡技术

为了提高单载波频域均衡(SC-FDE)系统的频带利用率和通信速率,提出了一种基于KNN信道识别算法的无前后缀频域均衡技术;该技术通过构建不同信道环境下带有导频的训练数据集,根据训练数据通过不同信道条件下的特征并使用KNN算法进行分类,进而确定信道类型及信道最大多径时延,通过信道最大多径时延合理确定无前后缀重叠剪切频域均衡算法的最优重叠剪切长度,进而消除多径干扰对无前后缀频域均衡数据的影响,达到最优解调性能;仿真表明:基于KNN的重叠剪切算法与文献推荐的50%重叠剪切法相比,性能基本一致,即在误码率为10^(-3)的情况下,信噪比恶化不大于0.5 dB;此算法准确确定了最优重叠长度,减少了大量无效的重叠长度,保证了多径信道下系统的误码性能,达到性能和复杂度的平衡。

音频响度控制器的设计与实现

设计一款音频响度控制器,该响度控制器支持对多声道AES3数字音频和数字分量串行接口(Serial Digital Interface,SDI)嵌入音频进行响度监测控制。该响度控制器根据设定的不同类型的音频信号目标响度值,由响度测量计算方法逆推,对音频信号进行频域均衡,按频率划分为几个子带,再经过限幅器输出符合目标响度的音频信号,解决了音频响度控制问题,使音频响度可测可控。在节目制播和传输过程中,通过合理有效地控制节目音频响度,提高用户的响度舒适度。

一种抗频偏的频域均衡及信号解调算法

针对无线信号传输过程中多径干扰和多普勒频偏并存的问题,提出了一种均衡和解调一体化的频率补偿的单载波频域均衡(SC-FDE)算法,对接收信号下变频和捕获后,先进行频率精确估计和补偿,再进行基于训练序列的插值法信道估计,然后通过均衡系数的计算、快速傅里叶变换(FFT)和快速傅里叶逆变换(IFFT)运算以完成频域均衡和符号判决,补偿了多径带来的影响,最终恢复出了发射端的原始符号。仿真结果表明,在信号接收端,该算法能够克服多普勒效应和多径衰落信道的影响,将散乱错误的星座图纠正为正常状态并最终正确解调出原始信号,因此有着较高的应用价值。

基于稀疏贝叶斯联合估计的多天线信号判决反馈频域均衡方法

相比于经典解耦处理的前馈均衡方法,判决反馈均衡具有更优的性能,但现有方法主要针对收发静止或理想载波同步的情形.本文提出了一种针对未理想载波同步多天线信号的判决反馈频域均衡方法.文中首先基于最小均方误差准则推导了多天线联合判决反馈频域均衡优化模型,针对模型中残余频偏、信道系数、噪声方差等参数难以直接求解问题,给出了基于稀疏贝叶斯的迭代估计方法,并通过近似计算,给出了所有参数估计式的闭式解,避免了网格搜索带来的计算量负担.所提方法综合考虑多天线信号接收处理不同环节之间的关联性,采用迭代处理方法进行联合寻优.仿真实验表明,所提方法能够有效抑制信道衰落的影响,与现有方法相比,在接收单元数目较少和信噪比较高时优势体现更加明显.

数字电视地面传输单载波频域均衡设计及仿真分析

本研究主要探究了面向数字电视地面传输的单载波频域均衡系统的设计方法,并通过系统仿真验证均衡效果。单载波频域均衡系统采用了插入循环前缀的方式消除码间干扰达到补偿均衡目的,信道估计和迫零均衡是实现这一功能的关键。针对线性均衡器存在的弊端,本研究提出了一种非线性的判决-反馈均衡器,利用PN完成信道训练与跟踪后,可以实现对输入数据的均衡处理。使用SPW5.0信号处理仿真软件对单载波频域均衡系统进行了仿真,结果表明,在信道深度衰落的情况下,系统的均衡性能仍然保持良好,达到了理想的均衡效果,对提高数字电视地面传输信号质量有积极帮助。

基于OFDM系统信号处理方式的高速单载波系统

在介绍正交频分复用 (OFDM)多载波系统实现原理的基础上 ,针对多载波系统对同步比较敏感和大的峰均功率比 (PAPR)两个问题 ,将多载波系统发送端的反傅立叶变换 (IFFT)模块移至接收端 ,提出了一种基于OFDM系统信号处理方式的高速单载波系统实现方案 .基于ITUM .1 2 2 5信道A模型 ,选用BPSK ,QPSK和 1 6QAM等调制方式 ,根据下一代移动通信系统信息速率要求对提出的单载波系统进行了仿真 .结果表明 :该方案具有多载波系统的优点 。

少模光纤通信系统中的自适应频域均衡算法

少模光纤模式复用存在模式耦合和差分模式时延,必须通过自适应均衡算法补偿。为了降低长距离少模光纤通信系统中自适应均衡算法的复杂度,采用基于变步长-频域块最小均方算法的多输入多输出均衡器对2×2模分复用系统解复用。利用频域块最小均方自适应算法修正均衡器权系数,并通过变步长函数调整步长因子,兼顾算法收敛速度和收敛性能。算法可通过快速傅里叶变换降低计算复杂度。在112Gbit/s的1000km少模光纤高速通信仿真系统中,保证相同收敛速度情况下,提高信号Q2因子3.7d B,并在可编程现场门阵列上验证了100km少模光纤通信系统时的算法性能。结果表明,该算法能够实现模分复用系统的信号解复用,达到快速收敛、低稳态失调的目的。

High-performance channel estimation and compensation scheme for OFDMreceivers with IQ imbalances

A pilot pattern across two orthogonal frequency division multiplexing OFDM symbols with a special structure is designed for the channel estimation of OFDM systems with inphase and quadrature IQ imbalances at the receiver.A high-efficiency time-domain TD least square LS channel estimator and a low-complexity frequency-domain Gaussian elimination GE equalizer are proposed to eliminate IQ distortion.The former estimator can significantly suppress channel noise by a factor N/L＋1 over the existing frequency-domain FD LS where N and L＋1 are the total number of subcarriers and the length of cyclic prefix and the proposed GE requires only 2N complex multiplications per OFDM symbol.Simulation results show that by exploiting the TD property of the channel the proposed TD-LS channel estimator obtains a significant signal-to-noise ratio gain over the existing FD-LS one whereas the proposed low-complexity GE compensation achieves the same bit error rate BER performance as the existing LS one.

基于EM-SBL迭代的稀疏SIMO信道频域盲均衡算法

针对单输入多输出系统下稀疏信道均衡问题,提出了一种新的基于最大似然准则的频域迭代均衡算法.首先将多天线联合均衡问题建模为非完整观测数据集下频域信号序列的最大似然估计问题,利用期望最大化算法进行近似迭代求解,最终得到各个单频信号加权求和形式的均衡输出表达式.在每次迭代过程中,算法依次完成均衡输出的更新和信道参数联合条件后验分布的更新.考虑到信道固有的稀疏特性,在求解信道参数联合条件后验时,引入具有稀疏促进作用的先验分布对信道系数加以约束,使用稀疏贝叶斯学习迭代求解信道参数联合条件后验.仿真结果表明,本文算法具有较好的收敛特性和稳态性能,在中高信噪比条件下可以获得接近信道已知条件下的稳态系统误符号率性能.

单载波频域均衡系统中的PN信道估计算法

提出了一种基于伪噪声(PNPseudoNoise)序列循环相关的信道估计算法,并将之应用于单载波频域均衡系统中。将新信道估计算法与2种典型的频域信道估计算法进行对比研究发现新算法可更好的兼顾性能与计算复杂度。将新算法用于SC-FDE系统时,研究了基于干扰消除的接收处理流程,并提出了发送的所有PN导频序列都相同时的简化接收处理步骤。仿真表明干扰消除流程和新的信道估计算法可以使系统性能接近信道完全已知时的系统性能。