CLOSED-FORM ERROR RATES OF STBC SYSTEMS AND ITS PERFORMANCE ANALYSIS

The closed-form solutions for error rates of Space-Time Block Code (STBC) Multiple Phase Shift Keying (MPSK) systems are derived in this paper. With characteristic function based method and the partial integration based respectively, the exact expressions of error rates are obtained for (2,1) STBC with and without channel estimation error. Simulations show that the practical error rates accord with the theoretical ones, so closed-form error rates are accurate references for STBC performance evaluation. For the error of pilot assisted channel estimation, the performance of a (2,1) STBC system is deteriorated about 3dB.

Low complexity suboptimal decode algorithms for quasi- orthogonal space time block codes

Due to the high complexity of the pairwise decoding algorithm and the poor performance of zero forcing（ ZF） /minimum mean square error（ MMSE） decoding algorithm, two low-complexity suboptimal decoding algorithms, called pairwisequasi-ZF and pairwise-quasi-MMSE decoders, are proposed. First,two transmit signals are detected by the quasi-ZF or the quasiMMSE algorithm at the receiver. Then, the two detected signals as the decoding results are substituted into the two pairwise decoding algorithm expressions to detect the other two transmit signals. The bit error rate（ BER） performance of the proposed algorithms is compared with that of the current known decoding algorithms.Also, the number of calculations of ZF, MMSE, quasi-ZF and quasi-MMSE algorithms is compared with each other. Simulation results showthat the BER performance of the proposed algorithms is substantially improved in comparison to the quasi-ZF and quasiMMSE algorithms. The BER performance of the pairwise-quasiZF（ pairwise-quasi-MMSE） decoder is equivalent to the pairwiseZF（ pairwise-MMSE） decoder, while the computational complexity is significantly reduced.

Differential modulation based on space-time block codes

A differential modulation scheme using space-time block codes is put forward. Compared with other schemes, our scheme has lower computational complexity and has a simpler decoder. In the case of three or four transmitter antennas, our scheme has a higher rate a higher coding gain and a lower bit error rate for a given rate. Then we made simulations for space-time block codes as well as group codes in the case of two, three, four and five transmit antennas. The simulations prove that using two transmit antennas, one receive antenna and code rate of 4 bits/s/Hz, the differential STBC method outperform the differential group codes method by 4 dB. Useing three, four and five transmit antennas, one receive antenna, and code rate of 3 bits/s/Hz are adopted, the differential STBC method outperform the differential group codes method by 5 dB, 6. 5 dB and 7 dB, respectively. In other words, the differential modulation scheme based on space-time block code is better than the corresponding differential modulation scheme

Arbitrary Decode-Forward Relaying with Re-Encoded Bits Selection Strategy for Polar Codes

In this paper,we propose an arbitrary decode-forward single-relay scheme for finite blocklength polar codes,which can be applied to the general symmetric discrete memoryless relay channel with orthogonal receiver components.The relay node decodes the received message.The relay node selectively re-encodes the message and transmits it to the destination node.Furthermore,in order to minimize the upper-bound of the block error probability,we propose a selection strategy to decide the proper re-encoded bit set by the relay.Simulation results are presented to illustrate the improvement in decoding performance of the proposed scheme compared to conventional relay schemes in both additive white Gaussian noise(AWGN)channel and Rayleigh fading channel(RFC).

Adaptive Decoding Algorithm Based on Multiplicity of Candidate Sequences for Block Turbo Codes

It is known that Block Turbo Codes （BTC） can be nearly optimally decoded by Chase-II algorithm, in which the Least Reliable Bits （LRBs） are chosen empirically to keep the size of the test patterns （sequences） relatively small and to reduce the decoding complexity. While there are also other adaptive techniques, where the decoder＇s LRBs adapt to the external parameter of the decoder like SNR （Signal Noise Ratio） level, a novel adaptive algorithm for BTC based on the statistics of an internal variable of the decoder itself is proposed in this paper. Different from the previous reported results, it collects the statistics of the multiplicity of the candidate sequences, i.e., the number of the same candidate sequences with the same minimum squared Euclidean distance resulted from the decoding of test sequences. It is shown by Monte Carlo simulations that the proposed adaptive algorithm has only about 0.02dB coding loss but the average complexity of the proposed algorithm is about 42% less compared with Pyndiah＇s iterative decoding algorithm using the fixed LRBs parameter.

基于IRS-NOMA辅助的短包通信系统性能分析

为了揭示短包数据在智能反射面(intelligent reflecting surface,IRS)和非正交多址接入(non-orthgonal multiple access,NOMA)技术辅助的通信系统中的传输性能,对短包通信系统性能进行深入研究.针对IRS具有理想相移和存在1 bit相位误差两种情况,借助短包通信相关理论和一阶黎曼积分法,获得近用户和远用户处平均误块率(block error rate,BLER)的解析结果;基于BLER的表达式,进一步分析系统吞吐量性能;利用蒙特卡洛仿真实验验证理论分析的正确性.结果表明:增加反射单元数目或增大信噪比都可显著改善短包传输的可靠性;相位误差对BLER和吞吐量的影响不容忽视.

Application of maximum rank distance codes in designing of STBC-OFDM system for next-generation wireless communications

Space-Time Block Coded(STBC)Orthogonal Frequency Division Multiplexing(OFDM)satisfies higher data-rate requirements while maintaining signal quality in a multipath fading channel.However,conventional STBCs,including Orthogonal STBCs(OSTBCs),Non-Orthogonal(NOSTBCs),and Quasi-Orthogonal STBCs(QOSTBCs),do not provide both maximal diversity order and unity code rate simultaneously for more than two transmit antennas.This paper targets this problem and applies Maximum Rank Distance(MRD)codes in designing STBCOFDM systems.By following the direct-matrix construction method,we can construct binary extended finite field MRD-STBCs for any number of transmitting antennas.Work uses MRD-STBCs built over Phase-Shift Keying(PSK)modulation to develop an MRD-based STBC-OFDM system.The MRD-based STBC-OFDM system sacrifices minor error performance compared to traditional OSTBC-OFDM but shows improved results against NOSTBC and QOSTBC-OFDM.It also provides 25%higher data-rates than OSTBC-OFDM in configurations that use more than two transmit antennas.The tradeoffs are minor increases in computational complexity and processing delays.

Polar码在图像传输中的性能研究

文中研究Polar码在图像传输系统中的应用,讨论Polar码的译码迭代次数、码长、码率等因素对恢复图像的影响,并与等同条件下的低密度奇偶校验码(Low Density Parity Check Code,LDPC)在图像传输中的性能进行比较。数值仿真表明:随着Polar码译码迭代次数增加、码长增长和码率减小,图像传输的误块率(Block Error Rate,BER)减小,峰值信噪比(Peak Signal to Noise Ratio,PSNR)增大。同时在码长为2 048,码率为0.5时,Polar码在图像传输中的性能比LDPC码的性能有明显地提高,在输入信噪比为3 dB时,Polar码的误块率有102增强,PSNR值有4倍的提高。

一种基于平均互信息的预编码矩阵选择方法

在长期演进系统下行链路闭环传输模式中,当子载波数较大时,会造成计算量和反馈量过大。为解决该问题,提出一种基于平均互信息的预编码矩阵选择方法。将K个子载波划分成D个子载波组,对每一个子载波组的信道矩阵进行算术平均,利用信道均值选择一个预编码矩阵,使K个子载波上的和速率最大。仿真结果表明,该方法与已有的预编码矩阵选择方法相比,在误块性能和容量性能基本不变的前提下,计算复杂度明显降低。

协作发射分集系统及其误码性能分析

协作分集(cooperative diversity)技术通过使网络中各单天线用户共享彼此天线,形成虚拟的多天线阵列来实现发射或接收分集,并结合一定的编码方式,可以有效地提高系统性能。多载波码分多址(MC-CDMA,multi-carrier code division multiple access)技术将数据调制到各个子载波上发送,可以有效地抵抗信道频率选择性衰落的影响。由此提出了无线网络中频率选择性衰落信道环境下的一种基于分布式空时分组码(DSTBC,distributed space time block code)和MC-CDMA的协作发射分集方案,建立了协作用户间的误码表示模型,基于该模型推导了在协作条件下整个系统误码性能的理论表达式。分析了协作用户间的平均解码差错概率对系统误码性能的影响,并给出了仿真结果。结果表明,本系统相对于未编码的MC-CDMA系统获得了明显的性能增益,同时仿真也较好地验证了理论结果。

卫星移动通信信道LR^2模型及系统性能分析

在对卫星移动通信信道传播特性进行分析的基础上 ,综合目前提出的各种卫星移动信道传播模型 ,提出了一种新的Lognormal Rice Rayleigh模型 (简称LR2 模型 )。从该模型可以推导到其它各种经典的卫星移动信道传播模型 ,并且具有良好的全波段特性 (从UHF到Ka)和实际逼真度。还给出了LR2 模型从UHF到Ka各个波段的仿真效果和参数优化公式 ,全面分析了与信道模型有关的各种参数如电平通过率 (LCR)、平均衰落时长 (AFD)、相位分布、误码率、块差错率等 。

一种改进的大规模MIMO预编码算法

大规模MIMO(Multiple-Input Multiple-Output)是基站装有大量天线,同时服务多个用户的通信方式,其用户间的干扰十分严重。文中通过结合迫零预编码和块对角化预编码算法,提出一种优化的块对角化算法。在大规模MIMO系统中,利用文中提出的新的预编码算法,可以较好地降低用户间的干扰,提高系统整体性能。通过仿真结果可以看出,文中算法比块对角化算法的误码率性能有显著提高。

结合率失真代价预测的HEVC快速CU划分

针对高效率视频编码(high efficiency video coding,HEVC)标准编码复杂度较高的问题,提出了一种快速编码单元(coding unit,CU)划分方法。首先,结合拉格朗日率失真优化理论及相关实验数据分析得到相邻CU深度对应的失真及码率分别满足线性关系,并利用此关系,建立了率失真代价的预测模型。利用此模型,可以在编码当前CU深度后快速预测得到下一CU深度的率失真代价,并最终通过代价比较,判断是否需要继续进行CU划分。实验结果表明,相比于HEVC测试模型HM12.0,针对低时延与随机接入编码结构,提出的方法的BD-rate分别增加了0.2%与0.6%,同时,编码时间分别减少了33.2%和38.9%。

基于矩阵模型的线性分组码及分组交织识别

针对通信系统中错误不可避免的现状,在矩阵分析法的基础上,提出反向纠错思想。利用穷举法,穷举条件规定范围内所有可能的分组码和分组交织模式,在纠错译码后再进行判定,得出正确的交织参数。对该方法在不同的误码率条件下进行仿真,得出能够正确识别的误码范围。

Nakagami-m衰落信道下空时分组码的性能估计

基于等效单输入单输出SISO(Single-inputSingle-output)模型,利用矩量母函数(MGF)分析法,空时分组码STBC(Space-TimeBlockCoding)的误符号率是可以得到其准确闭式表达式的。对于独立同分布Nakagami-m衰落信道下的空时分组码的性能进行了研究,给出了采用M-PSK和M-QAM调制方案的不同空时分组编码矩阵误符号率的闭式解以及基于闭式解的解析性能结果,通过蒙特卡洛仿真验证了闭式解的准确性。还从调制方案的角度对于几种新的空时分组码的性能进行了一些新的讨论。

基于四元素准正交设计的空时分组码

提出了一种基于四元素准正交设计的空时分组码,该种码满足准正交设计关系,可以通过极化天线进行满码率发射和接收.首先建立了信道模型,然后设计出发射天线数为4的四元素准正交空时分组码,采用快速最大似然译码算法进行译码,最后将其与天线数为4的传统准正交设计空时分组码分别进行了性能仿真.结果表明,所设计的四元素准正交设计空时分组码在不增加发射天线和接收天线的情况下,可以降低系统误码率,提高系统性能.分别采用BPSK,QPSK和8PSK,当SNR=10dB时,新码的误码率比准正交码分别降低0.5-1个数量级,而在SNR=15dB时,则分别降低约2个数量级.

基于互满正交设计的差分空时分组码

本文针对多天线系统提出了基于互满正交设计的差分空时分组码(Amicable-orthogonal-design-based Dif-ferential Space-Time Block Code,ADSTBC).与已有的差分空时调制方法相比,ADSTBC对信号星图无任何限制,因而可采用高效的调制技术(如QAM、APSK等)提高频谱效率.基于平坦Rayleigh衰落信道,给出了具有线性复杂度的最大似然差分译码器(Maximum-Likelihood Differential Decoder,MLDD).若在ADSTBC中采用QAM星图,MLDD可进一步简化成独立地检测每一数据符号的实部和虚部,降低了实现代价;并且,随着QAM星图阶数的增加,MLDD用于检测单个数据符号的计算量将保持不变.

基于直接序列扩频和频域均衡的满多径分集块传输系统

为了获得信道的满多径分集增益,基于直接序列扩频和线性频域均衡,提出了一种单载波块传输系统。发射信号在时域的直接序列扩频,造成了信号在频域的重复和交织。接收端通过最大比合并频域均衡,均衡和解扩同时在频域内完成。理论分析表明,对于多径数目为L的多径信道,系统可以获得分集阶数为L的满多径分集增益。与传统的线性频域均衡系统相比,系统具有更低的误码率和更低的计算复杂度。理论分析的结果通过计算机仿真进行了验证。

一种改进的块对角化预编码算法

为进一步提高块对角化预编码算法的性能,提出一种多用户多输入多输出下行链路中基于Givens变换的正交三角(QR)分解改进块对角化算法(QR-Givens-BD)。在块对角化预编码算法中,首先需要求出预编码矩阵的前半部分来解决多用户干扰问题,然后求出预编码矩阵的后半部分来降低用户自身天线间的数据干扰。在求解预编码矩阵的前半部分时,使用的核心算法是矩阵的正交化算法,矩阵的正交性的强弱将直接影响块对角化预编码算法的误码率性能的好坏。因此,针对块对角化预编码算法中的矩阵正交化算法,使用基于Givens变换的QR分解正交化算法替换原有正交化算法,求解预编码矩阵的前半部分,从而获得信道干扰矩阵零空间的正交基。通过对矩阵采用本方法进行正交分解,可以获得正交性更好的正交矩阵,从而进一步降低系统误码率。仿真结果表明,本文所提出的算法与传统的块对角化算法相比,在降低了计算复杂度的同时大幅提高了系统的误码率性能;与基于Gram-schmidt正交化的改进块对角化算法相比,在略微增加复杂度的前提下可以提高3~5 dB的误码率性能。