MIMO-OFDM系统中V-BLAST检测算法的比较

V-BLAST是一种基于多输入多输出传输的空时码系统，其检测算法是MIMO—OFDM系统的有效检测方法。本文介绍了应用于MIMO—OFDM信号检测的多种V-BLAST检测算法，并根据MATLAB仿真结果对各种算法的性能和优缺点进行了分析和比较。     

垂直分层空时码系统信号检测算法的研究

主要介绍了基于多输入多输出（MIMO）传输方式的垂直分层空时码系统（V—BLAST）空时码系统的检测算法,并把它与传统的MIMO信号检测算法进行了分析和比较,仿真得出相关结论。     

基于Golden检测算法的V-BLAST性能仿真分析

垂直分层空时码系统(V-BLAST)是贝尔实验室提出的一种基于多输入多输出(MIMO)传输方式的空时码系统。本文介绍了V-BLAST的系统模型、信道容量和Golden检测算法,并把该算法的仿真结果和单发单收系统的性能进行了比较。仿真结果显示V-BLAST系统比传统通信系统的频谱利用率要高。     

FSO MIMO系统中分层空时码检测算法

多输入多输出(MIMO)系统可以有效提高频谱效率和系统容量。基于MIMO系统重点研究了无线光通信垂直分层空时系统(V-BLAST)检测算法。首先分析了最大似然、线性迫零、最小均方误差以及排序干扰抵消等典型的传统检测算法,基于OOK调制和4PPM调制对采用不同检测算法的系统差错性能进行了仿真对比,最后对Turbo码与BLAST技术相结合构成的新系统采用了软输入软输出(SISO)迭代检测译码方案。仿真结果表明,分层空时检测算法中性能最优的是ML,其次是SISO-MAP,ZF算法性能最差;Turbo-BLAST系统可以有效提高无线光通信系统的抗干扰性能。     

基于串行干扰消除的V—BLAST检测

贝尔实验室分层空时结构（BLAST）是实现多输入多输出（MIMO）无线通信系统空时复用并获得容量增益的一种重要技术．本文将以垂直BLAST（V-BLAST）为主要对象，综述基于串行干扰消除的V-BLAST检测算法及相应的复杂度和误码性能，并对其发展作了有关展望。     

基于MIMO的垂直分层空时码检测算法

分层空时码(BLAST)是贝尔实验室提出的一种基于多入多出(MIMO)传输方式的空时码系统。本文着重研究了BLAST系统中一类垂直分层空时码的检测算法,依据信号模型,分析推导了基于迫零准则和最小均方误差准则的估计算法,并在此基础上采用了以上算法与判决反馈及最佳排序思想结合的方法,使系统的误码率性能得到了提高。最后通过仿真实验比较了各种算法的性能和特点,结果表明分层空时码用于无线通信具有极大优势。     

LTE下行链路信道采用扩展单环MIMO信道模型进行建模的研究

本文主要研究如何对LTE下行链路中的信道采用扩展的单环多入多出（Multiple Input Multiple Output,MIMO）信道模型进行建模,并进行性能的研究。在假设信道状态信息（Channel State Information,CSI）已知的情况下研究该扩展的单环MIMO模型的系统误符号率（Symbol Error Ratio,SER）性能,进而讨论天线的相关性对性能的影响,并分别针对采用空时块码（Space Time Block Code,STBC）、垂直分层空时码（Vertical-BLAST,V-BLAST）以及空频块码（Space Frequency Block Code,SFBC）编码的系统误符号（SER）性能进行比较。仿真结果显示,通过增加在eNodeB(eNB)端的天线元间距,能够得到比增加用户设备（UE）端天线元间距更优异的性能。从空时块码、垂直分层空时码、空频块码三种编码方式的比较中可以发现,空频块码（SFBC）的性能最优,垂直分层空时码（V-BLAST）的性能最差。     

V—BLAST系统检测算法的比较

垂直分层空时码系统(V-BLAST)是贝尔实验室提出的一种基于多入多出(M IMO)传输方式的空时码系统。本文主要介绍了它的系统结构和检测算法,并对各种检测算法进行了分析和比较,仿真得出相关的结论。     

分组空时块编码结构及其信号检测算法

本文提出一种可用于宽带数字移动通信系统的多输入多输出(MIMO)无线传输系统架构———分组的空时块编码(G-STBC)MIMO结构,即发送天线被分成若干组,组内的多根天线进行STBC编码,而各组发送的数据流相互独立。针对这一系统架构,提出了基于迫零检测的最优排序串行干扰消除(OZFSIC)接收信号检测算法的实现方案。计算机仿真结果表明,这种空时编码MIMO结构在等数据率的情况下能获得比相应的V-BLAST系统更优的性能。G-STBC-MIMO结构可以使发送天线多于接收天线,因此,对于无线通信系统下行链路以及大数据量广播业务系统(如数字高清晰度电视地面传输系统)都较V-BLAST更具有优势。     

基于垂直分层空时编码的光纤MIMO系统研究

垂直分层空时编码(V-BLAST)将空间复用和空间分集结合起来,能够提高系统的传输速率,因此,提出一种基于V-BLAST的光纤MIMO系统.光纤MIMO技术主要是利用MIM0技术将多模光纤(MMF)的模式色散加以利用,改善MMF的容量.构建光纤信道模型,在接收端,采用最小均方误差算法进行检测,仿真分析基于V-BLAST...     

Fuzzy adaptive partial parallel multistage detection for MIMO systems

Vertical Bell Laboratories Layered Space-Time (V-BLAST) detection followed by a full parallel interference cancellation (full PIC) or a constant-weight partial parallel interference cancellation (CW-PPIC) scheme has been proposed. However, its performance degrades when the received power of the antenna is unbalanced and/or the system is heavily loaded. Therefore, V-BLAST is proposed, followed by fuzzy adaptive partial parallel multistage detection for MIMO systems. The simulation results show that the error probability of this proposed method is better than that of V-BLAST followed by full PIC or CW-PPIC schemes     

On the relation between V-BLAST and the GDFE

This letter shows that the receiver processing of the Vertical Bell Labs Layered Space-Time (V-BLAST) architecture may he viewed as a generalized decision feedback equalizer (GDFE) as applied to a multiple-input-multiple-output (MIMO) channel. It is proven that, depending on the criterion chosen to reduce the interference, the receiver operations of the V-BLAST system are fundamentally equivalent to either a zero-forcing (ZF) or a minimum-mean-square-error (MMSE) GDFE     

VLST系统中ZF检测算法的研究

垂直分层空时码(VLST)是贝尔实验室提出的一种基于MIMO传输方式的空时码系统,其中,迫零检测算法(ZF)、最小均方误差检测算法(MMSE)和最大似然检测算法(ML)是常用的3种检测算法。着重对经典的ZF检测算法进行了深入的数学分析,并通过matlab仿真试验,给出了该算法在不同的调制方法、不同的信道估计误差下的性能分析,为构造实际VLST系统给出了理论依据     

MIMO系统中一种改进的迭代串行干扰消除算法

多输入多输出(MIMO)系统中,串行干扰消除(SIC)算法复杂度相对较低,但干扰消除时存在差错传播问题。针对独立编码的垂直分层空时(V-BLAST)系统,提出一种联合译码的SIC算法,将译码完成的码字反馈给解调器,从接收信号中消除。引入一种码字排序准则,利用软信息对码字排序,优先对高可靠性码字译码。通过码字排序和联合译码提高检测符号的准确性,减少差错传播。仿真结果表明,与已存在的接收方法相比,该算法能有效地抑制差错传播,大幅提升误码率性能。      

V-BLAST系统的新型混合检测

Based on the new discrete particle swarm op-timization(NDPSO) and the mutation operation of the genetic algorithm,a hybrid discrete particle swarm op-timization(HDPSO) algorithm is proposed and applied to the signal detection of the Vertical Bell-Labs Layered Space-Time(V-BLAST)system.Then two detection ap-proaches that employ the HDPSO and parallel interfer-ence cancellation(PIC) algorithms in V-BLAST system are proposed.One of approaches is that the HDPSO algorithm is used as the first stage of the PIC to...     

V-BLAST系统中的迭代软判决干扰抵消检测算法

分层空时结构(BLAST)是一种通过使用多根发射天线和接收天线,以及在接收端使用先进的信号处理技术来获得高频谱效率的技术。主要研究了基于MMSE的迭代软判决干扰抵消(ISDIC)算法在V BLAST系统中的应用。仿真结果表明,相对于传统的检测算法,其性能至少有1 dB的增益。     

Transmit power allocation for a modified V-BLAST system

In this letter, we present a modification of Vertical Bell Laboratories Layered Space-Time (V-BLAST), and propose an effective transmit power allocation (TPA) scheme for the modified system. The proposed TPA scheme minimizes the uncoded bit-error rate (BER) averaged over all detection stages, and requires small feedback overhead. Simulation results show that the modified V-BLAST system with the proposed TPA scheme provides a significant reduction in the uncoded BER compared with the conventional V-BLAST system. When the minimum mean-square error ing is adopted, the modified V-BLAST system is found to achieve the uncoded BER performance comparable to that of the maximum-likelihood detection for the conventional V-BLAST architecture.     

New transmit schemes and simplified receivers for MIMO wireless communication systems

In this paper, optimized transmit schemes for multiple-input multiple-output (MIMO) systems with simplified receivers are proposed for the downlink of high-speed wireless communication systems. In these systems, MIMO signal preprocessing is performed at the transmitter or base station with the receiver at the mobile station having a simplified structure that requires only limited signal processing. An important potential application for our transmit MIMO techniques is in the downlink of high-speed wireless communication systems with Vertical Bell Laboratories Layered Space-Time (V-BLAST) or a similar technique utilized in the uplink, creating a high-speed duplex system with a simplified mobile station transceiver structure. Two approaches are introduced and these depend on whether or not receive diversity is employed at the receiver. Both methods require that channel state information be available at the transmitter. In addition, some important associated issues such as peak-to-average power ratio requirements at the transmitter and robustness to downlink channel errors are also investigated and various solutions are proposed. Simulation results are provided and these show that performance improvement can be achieved when compared with other MIMO transmit schemes.