V-BLAST OFDM系统的频率选择性信道盲估计

研究下行频率选择性衰落环境中垂直分层空时正交频分复用(V-BLAST OFDM)系统的信道盲估计问题。为V-BLAST OFDM系统提出了一种新颖的贴标签型延迟分集结构。该结构能够巧妙赋予V-BLAST OFDM系统以旋转不变性性质。利用上述旋转不变性，进一步为下行V-BLAST OFDM系统提出了一种多输入多输出(MIMO)频率选择性无线信道的盲估计方法。仿真结果表明了新颖贴标签型延迟分集结构的有效性和信道盲估计方法的性能。     

多载波垂直分层空时系统的移不变性编码及其解码

该文将多载波(MultiCarrier,MC)技术引入垂直型贝尔实验室分层空时(Vertical Bell Labs lAyered Space-Time,V-BLAST)结构,所形成的MC V-BLAST系统能更好地利用宽带移动无线多媒体通信条件下频率选择性所产生的频域分集能力。该文着重研究MC V-BLAST系统在下行频率选择性衰落环境中的解码问题。该文首先为MC V-BLAST系统提出了一种新颖的移不变性编码方法。利用上述移不变性性质,该文进一步为MC V-BLAST系统提出了一种无需了解信道状态信息(Channel State Information,CSI)的解码算法。仿真结果表明了该文新颖移不变性编码方法的有效性和解码算法的性能。     

空时旋转不变性编码技术及其频率选择性信道盲估计方法

针对处于频率选择性衰落环境中的垂直型贝尔实验室分层空时(Vertical Bell iabs LAyered Space-Time,V-BLAST)结构,该文首先对其进行联合空时符号分组,然后提出了一种新颖的空时旋转不变性编码技术(Space-Time Rotational-Invariance Coding Technique,STRICT)。通过巧妙利用上述编码技术中的旋转不变性性质,该文继续为V-BLAST结构提出了一种多输入多输出(Multiple-Input Multiple-Output,MIMO)频率选择性无线信道的盲估计方法。仿真结果表明了该文新颖STRICT的有效性及其信道盲估计方法的性能。     

频率选择性OFDM V-BLAST系统的直接解码算法

作为正交频分复用(OFDM)技术与垂直型贝尔实验室分层空时(V-BLAST)结构的结合,OFDM V-BLAST系统能更好地满足新一代宽带移动无线多媒体通信的需求.本文研究OFDM V-BLAST系统在下行频率选择性衰落环境中的解码问题.在阐述了OFDM V-BLAST系统中的联合空频解复用操作之后,本文为OFDM V-BLAST系统提出了一种新颖的半速率旋转不变性联合空频编码方法.通过利用上述旋转不变性,本文为下行频率选择性OFDM V-BLAST系统建立了一种无需了解信道状态信息(CSI)的直接解码算法.大量仿真结果表明了半速率旋转不变性联合空频编码方法的有效性和直接解码算法的性能.     

DSSS-MIMO结构的标签延迟发射分集方法

针对频率选择性衰落多输入多输出(Multiple-Input Multiple-Output,MIMO)结构,提出在各发射天线通道引入直接序列扩频(Direct-Sequence Spread-Spectrum,DSSS)操作以便实现信道的矢量化,然后提出了一种标签延迟发射分集方法和相应的实现频率选择性衰落无线信道估计的盲方法.仿真结果表明了上述标签延迟发射分集方法的有效性及其信道盲估计方法的性能.     

基于PSAM的MIMO时间-频率双选择性信道的信道估计

数据的高速率传输以及终端的高速移动,导致无线通信信道具有时间选择性与频率选择性两个特征.本文主要研究了数据分组传输方式下,基于导频符号辅助调制(PSAM)的多输入多输出(MIMO)时间-频率双选择性信道的信道估计问题.首先,将时间-频率双选择性MIMO信道,建模为一个随时间变化的多项式内插信道模型;然后,根据信道Doppler衰落速率、多项式模型中的误差项,确定出模型的阶数以及整个数据块的长度;最后,基于该多项式内插信道模型,提出了采用PSAM的MIMO双选择性信道估计方法.实验结果表明本文的算法在时间-频率双选择性衰落信道下具有较好的性能.     

CDMA系统中的空时发射分集方案及其 在MIMO MC-CDMA中应用的研究

 本文结合了空时发射分集技术能够有效地对抗信道衰落、提高系统容量和多载波码分多址(MC CDMA)具有高效频谱利用率、对频率选择性信道鲁棒性的优点,提出了CDMA系统中两种新的空时发射分集方法,研究了这两种空时发射分集方法在MIMO MC-CDMA系统中的应用,并与基于空时分组编码的发射分集方法分别在MIMO CDMA和MIMO MC-CDMA两种系统下进行了仿真比较.     

MIMO HSDPA系统中分数采样的空时均衡接收方案

为了解决第三代移动通信系统下行链路容量瓶颈问题，在HSDPA的解决方案中，多输入多输出(MIMO)天线系统的提案越来越受到重视。然而，频率选择性衰落信道下多天线和多码扩频传输会产生严重的码间干扰和共信道间干扰。本文提出了一种频率选择性衰落环境下MIMO HSDPA系统中分数采样的空时均衡接收方案，并进行了详细的理论推导。给出了ITU Pedestrian A信道环境下的仿真结果。     

基于多项式内插的MIMO时间-频率双选择性信道的信道估计

数据的高速率传输以及终端的高速移动,导致无线通信信道具有时间选择性与频率选择性两个特征。该文主要研究了数据分组传输方式下,基于导频符号辅助调制(PSAM)的多输入多输出(MIMO)时间-频率双选择性信道的信道估计问题。首先,将时间-频率双选择性MIMO信道,建模为一个随时间变化的多项式内插信道模型;然后,根据信道Doppler衰落速率、多项式模型中的误差项,确定出模型的阶数以及整个数据块的长度;最后,基于该多项式内插信道模型,提出了采用PSAM的MIMO双选择性信道估计方法。实验结果表明该算法在时间-频率双选择性衰落信道下具有较好的性能。     

空时编码多载波码分多址MIMO系统下行频率选择性信道盲估计

基于子空间方法的无线信道盲估计由于其算法的固有特性,使得估计结果与实际信道之间存在一个不确定复系数,无法得到无线信道的精确估计。在利用子空间分解方法对空时编码多输入多输出MC-CDMA系统下行频率选择性信道盲估计的基础上,利用发射符号的有限码集特性,将单载波系统下的模糊复系数盲辨识方法推广到多载波多输入多输出系统,从而得到信道的精确估计。Monte-Carlo仿真表明,在信噪比较低的情况下,本方法的信道估计误差仍然较小。     

An adaptive spatio-temporal coding scheme for indoor wireless communication

Systems that employ multiple antennas in both the transmitter and the receiver of a wireless system have been shown to promise extraordinary spectral efficiency. With full channel knowledge at the transmitter and receiver, Raleigh and Cioffi (1998) proposed a spatio-temporal coding scheme, discrete matrix multitone (DMMT), to achieve asymptotically optimum multiple-input-multiple-output (MIMO) channel capacity. The DMMT can be regarded as an extension of the discrete multitone for a digital subscriber lines (DSL) system to the MIMO wireless application. However, the DMMT is basically impracticable in nonstationary wireless environments due to its high-computational complexity. Exploring second-order statistics, we develop an efficient adaptive blind coding scheme for a high-capacity time-division duplexing (TDD) system with slow time-varying frequency-selective MIMO channels. With this method, neither a training sequence nor feedback of channel information is required in the proposed blind approach. Besides, the computational complexity of the proposed scheme is significantly lower than that of the coding scheme described by Raleigh and Cioffi. Simulation results show that the proposed architecture works efficiently in indoor wireless local area network applications.     

Iterative detection and decoding with an improved V-BLAST for MIMO-OFDM systems

Multiple-input-multiple-output (MIMO) systems provide a very promising means to increase the spectral efficiency for wireless systems. By using orthogonal frequency-division multiplexing (OFDM), wideband transmission can be achieved over frequency-selective fading radio channels. First, in this paper, we introduce an improved vertical Bell Labs layered space-time (V-BLAST) receiver which takes the decision errors into account. Second, we propose an iterative detection and decoding (IDD) scheme for coded layered space-time architectures in MIMO-OFDM systems. For the iterative process, a low-complexity demapper is developed by making use of both nonlinear interference cancellation and linear minimum mean-square error filtering. Also, a simple cancellation method based on hard decision is presented to reduce the overall complexity. Simulation results demonstrate that the proposed IDD scheme combined with the improved V-BLAST performs almost as well as the optimal turbo-MIMO approach, while providing tremendous savings in computational complexity.     

A MIMO-OFDM prototype for next-generation wireless WANs

Coupled with a robust and efficient OFDM air interface, MIMO technologies lead to a very compelling high-speed data downlink solution for future wireless systems. This article presents Nortel Networks' MIMO-OFDM concept prototype and measured performance results. This prototype has been developed in the framework of a Nortel Networks system concept for 3G evolution systems and next-generation wide area wireless networks. The prototype is based on a shared access MIMO-OFDM physical layer in the downlink, supporting adaptive modulation and coding, with peak rates up to 37 Mb/s. The uplink is based on an enhanced UMTS WCDMA physical layer. Performance for the high-speed downlink has been measured under various emulated fading conditions. The measured performance illustrates the robustness of OFDM in frequency-selective channels and high-speed mobility channels, supporting speeds as high as 200 km/h. The prototype can also be used for over-the-air assessment of the technology.     

Interference Cancellation with Space Diversity for Downlink MC-CDMA Systems

Modern wireless communications require an efficient spectrum usage and high channel capacity and throughput. Multiple-input and multiple-output (MIMO), Linear equalizers, multi-user detection and multicarrier code-division multiple access (MC-CDMA) are possible solutions to achieve spectral efficiency, high channel capacity, eliminate multiple access interference (MAI), eliminate Inter symbol interference (ISI) and robustness against frequency selective fading. In this paper, we combine all these techniques and investigate BER performance. We propose a low complexity receiver structure for Single-input Multiple-output (SIMO) downlink MC-CDMA systems. It employs an interference cancellation scheme to suppress the interference caused by the multipath fading channel. Also, the proposed scheme is developed for MIMO MC-CDMA system. The performance analysis of Downlink MIMO MC-CDMA systems with V-BLAST over frequency selective fading channel is investigated under various number of transmit and receive antennas. The simulation results show proposed SIMO equalization with parallel interference cancellation scheme is effective in reducing the ISI and the MAI. It improves the performance significantly and the simulation results show that MIMO MC-CDMA with V-BLAST multi-user detection provides high data rate and the BER significant improvement.