Quaternion Approach to Solve Coupled Nonlinear Schrdinger Equation and Crosstalk of Quarter-Phase-Shift-Key Signals in Polarization Multiplexing Systems

The quaternion approach to solve the coupled nonlinear Schrodinger equations （CNSEs） in fibers is proposed, converting the CNSEs to a single variable equation by using a conception of eigen-quaternion of coupled quater- nion. The crosstalk of quarter-phase-shift-key signals caused by fiber nonlinearity in polarization multiplexing systems with 100 Cbps bit-rate is investigated and simulated. The results demonstrate that the crosstalk is like a rotated ghosting of input constellation. For the 50 km conventional fiber link, when the total power is less than 4roW, the crosstalk effect can be neglected; when the power is larger than 20roW, the crosstalk is very obvious. In addition, the crosstalk can not be detected according to the output eye diagram and state of polarization in Poincare sphere in the trunk fiber, making it difficult for the monitoring of optical trunk link.

基于OAM复用信号高效调制解调的声学超表面

轨道角动量(Orbital Angular Momentum,OAM)复用是提高声学通信系统数据容量的一种潜在解决方案,提出一种利用声学超表面对OAM复用信号进行调制和解调的方法,利用该方法对独立声轨道角动量(Acoustic Orbital Angular Momentum,AOAM)信号的幅度和相位进行分析,并通过仿真实现对AOAM信号的调制和解调.AOAM信号的相位和幅度提供正交自由度,通过设计合适的声学超表面并将其与二进制差分相位编码技术相结合,证明其可以实现AOAM复用信号的有效调制和解调.正交声学螺旋模态可防止模式耦合和串扰,从而增强声学多路复用.基于谐振的结构提供信号频率选择性,提高了交互效率,简化了终端设备,便于实现大容量声学通信系统的创建.

PSO算法下GP-周期随机共振的微弱OFDM信号检测

为了解决传统随机共振系统在微弱正交频分复用(Orthogonal Frequency Division Multiplexing,OFDM)信号解调应用中存在的人工选择参数困难、解调效果差的问题,提出一种基于粒子群优化(Particle Swarm Optimization,PWO)算法的GP(Gaussian Potential)-周期随机共振系统的微弱OFDM信号检测方法。该方法利用GP-周期随机系统对OFDM信号经正交变换后的两路高频信号分别进行随机共振,同时运用阻尼参数与信号频率之间的关系对两路信号进行降频处理,使得上下两路信号都能够发生随机共振;然后使用PWO算法对随机共振的系统参数进行优化处理,以使得上下两路信号达到最优的共振效果;最后,将上下两路共振之后的信号合成完成OFDM信号解调,得到最终的数字序列。本文探讨了优化前后GP-周期随机共振系统的共振效果,研究了优化前后GP-周期随机共振诱导下的OFDM系统星座图的聚集程度以及误码率情况,对比分析了经典双稳随机共振、经典三稳随机共振和所提模型对OFDM信号检测的影响。仿真结果表明:相比常用的传统随机共振模型,该方法用于OFDM信号检测的星座图中信号点的聚集程度更高,同时OFDM系统误码率在同样的信噪比下降低50%左右。

Dual-assisted high-precision tracking technique for wideband multiplexed signals in new generation GNSS

With the evolution of Global Navigation Satellite System(GNSS),new generation GNSS signals have adopted the dual-frequency multiplexing modulation techniques,which jointly modulate multiple signals located on multiple sub-frequencies into a Wideband Multiplexed Signal(WMS).Although WMSs were proposed initially to reduce the complexity of satellite transmitters and improve the transmission efficiency of signals,their multi-component structures and wide root mean square bandwidths introduced by high-frequency subcarriers also provide the possibility to improve the GNSS ranging precision.Therefore,this paper proposes a Dual-assisted Multi-component Tracking(DMT)technique,which can not only fully use high-frequency subcarriers in WMSs,but also effectively track carrier,subcarrier,and code by jointly utilizing all components in WMS.In this paper,the tracking and ranging performances of DMT are comprehensively analyzed theoretically and by simulation and real experiments.The results show that compared with existing WMS tracking methods,DMT can achieve tracking results with lower tracking jitters and ranging results with higher precision,providing a highly advantageous solution for new generation GNSS signal processing.

基于优化CCSK调制的低轨卫星通信导航一体化信号设计方法

给出了一种基于优化循环码移键控(cyclic code shift keying,CCSK)方式的通信导航一体化信号设计方法,使通信信号的互相关函数的正值与导航信号自相关函数的峰值一致,从而克服互相关干扰,提高通信速率。通过频分复用的方式划分通信信号和导航信号的频带,基于正交频分复用(orthogonal frequency division multiplexing,OFDM)技术提出连续分配、交替分配和随机分配3种子载波分配方案。对优化CCSK调制和CCSK调制的一体化信号的自相关峰值性能进行仿真和分析,结果表明,在3种子载波分配方案下,采用优化CCSK调制的一体化信号的自相关峰值性能均优于CCSK调制的一体化信号,且采用优化CCSK调制的通信信号的互相关特性对相应的导航信号的自相关峰值有增强作用,可提升通信导航一体化信号体制下导航信号的码相位同步性能。

Coarse-fine joint target parameter estimation method based on AN-RSC in OFDM passive radar

In this paper,we study the accuracy of delay-Doppler parameter estimation of targets in a passive radar using orthogonal frequency division multiplexing(OFDM)signal.A coarse-fine joint estimation method is proposed to achieve better estimation accuracy of target parameters without excessive computational burden.Firstly,the modulation symbol domain(MSD)method is used to roughly estimate the delay and Doppler of targets.Then,to obtain high-precision Doppler estimation,the atomic norm(AN)based on the multiple measurement vectors(MMV)model(MMV-AN)is used to manifest the signal sparsity in the continuous Doppler domain.At the same time,a reference signal compensation(RSC)method is presented to obtain highprecision delay estimation.Simulation results based on the OFDM signal show that the coarse-fine joint estimation method based on AN-RSC can obtain a more accurate estimation of target parameters compared with other algorithms.In addition,the proposed method also possesses computational advantages compared with the joint parameter estimation.

基于多特征融合的MIMO-OFDM系统单-混信号调制识别算法

为解决非协作通信中多输入多输出正交频分复用(multiple-input multiple-output orthogonal frequency division multiplexing, MIMO-OFDM)系统的单-混信号调制识别问题,提出一种基于多特征融合和决策融合的调制识别方法。首先,利用特征矩阵的联合近似对角化(joint approximate diagonalization of eigenvalue matrix, JADE)算法从接收端恢复发送信号;然后,提取恢复后信号的四次方谱、循环谱和高阶累积量作为输入样本,利用多特征融合网络对输入样本进行训练;最后,使用决策融合策略根据每条支路输出得到最终判决结果。仿真实验结果表明,所提方法可以对MIMO-OFDM系统中的7种信号进行有效识别,在信噪比为10 dB时识别精度可达99.4%。

基于轨道角动量谱分解的多通道水声通信及系统实现

水声通信能够实现信息的长距离传输,在深海探索和军事领域发挥重要作用.然而,由于换能器带宽和声波波长的影响,水声通信的发展与应用受到传输衰减大和信道容量低以及频谱利用率不足的限制.本文结合复用涡旋声束(AV)和轨道角动量(OAM)谱分解技术,研究了基于环形收发阵列的多通道水声通信方法,并系统实现.基于发送数据的ASCII编码,利用全息信号的幅度和相位调制,驱动环形换能器阵列发射沿轴传输的多通道OAM复用涡旋声束,并通过环形换能器阵列的信号采样和OAM谱分解完成复用涡旋声束的OAM模态解码,实现了高效的并行数据传输.构建了8声源环形收发阵列和全息相控系统,开展了6通道水声通信研究,成功实现了复用涡旋声场的实验测量和OAM解码,并与传统单通道二进制串行数据通信进行性能比较.理论和实验结果证明,基于OAM谱分解的通信通道数由发射阵列的阵元数N决定,其解码精度由发射信号的相位精度和接收阵列的阵元数决定;阵元数N≥1的大阵列系统在满OAM模式复用条件下的传输速率约为传统水声通信的N倍.本研究表明基于OAM谱分解的多通道通信可大幅提高信道容量和频谱利用率,为其在水声通信中的实际应用提供了一种实用方案.

采用CNN的MIMO-OFDM可见光通信接收机

为了克服多输入多输出(MIMO)-正交频分复用(OFDM)可见光通信(VLC)系统中存在的信号串扰、高峰均功率比、发光二极管(LED)的带宽受限和非线性效应等问题,提出一种基于卷积神经网络(CNN)的VLC接收机.该接收机通过对接收端失真信号和发射端原始信号的学习,能够实现MIMO-OFDM可见光通信系统的信号解调,有效提升系统对非线性失真的抑制能力并具有较低的复杂度.实验结果表明,与最小二乘法接收机相比,CNN接收机能有效补偿信号受到的线性和非线性失真以及不同用户间的信号串扰,平均误码率提升超过一个数量级,同时有效克服LED带宽受限问题,比特传输速率提升53%.

Linux中多种IO机制及应用探究

Linux操作系统在软件工程中的应用比较广泛,各种商业发行版本广泛地存在于PC桌面、后端服务器和个人移动终端中。而Linux中数据输入输出的效率直接决定了操作系统的应用执行效率。就硬件的读写速度来看,CPU的数据处理速度远大于磁盘IO的数据处理速度。因此在Linux中,IO性能的优化一直是Linux效率优化的重点。在Linux操作系统中一共存在非阻塞、阻塞、多路复用、信号驱动和异步5种IO模型。这5种IO模型优缺点各不相同,分别对应着不同的应用场景。

基于多窗口识别的多波长光信号峰值实时检测系统

波分复用(Wavelength Division Multiplexing,WDM)作为光纤通信系统的核心技术之一,为多个波长光信号的复用和传输提供了强有力的解决方案,对复用光信号的解复用和识别是WDM系统需解决的重要问题之一。文中研制了一种针对多波长光信号峰值的实时检测系统,用于实时检测多波长光信号的峰值功率。首先,设计并研制了光纤法布里-珀罗可调谐滤波器(FFP-TF)的驱动控制器和微弱光信号探测器,分别控制FFP-TF的驱动电压使其滤出特定波长的光信号和对滤出光信号的功率进行实时探测;其次,对于光电探测器中实时探测的光信号功率,设计了一种基于多窗口识别的峰值检测方法,使用三个针对波形不同位置的数据筛选窗口,根据实时检测数据来识别波形的变化趋势从而得到峰值强度与位置,进而计算出对应的光信号峰值强度。实验结果显示,所研制的实时检测系统实现了对多波长光信号的实时检测以及峰值的识别,光信号检测强度范围为0~-60 dBm,识别速度较快,对于准周期或周期的多波长光信号的识别具有良好的识别效果。

High Speed Polarization-Division Multiplexing Transmissions Based on the Nonlinear Fourier Transform

Polarization-division multiplexing(PDM)with modulation in the nonlinear frequency domain consisting of the discrete and/or continuous spectrum has been recently regarded as a useful method to be utilized in optical fiber communication system.It can compensate the optical fiber nonlinearity based on the nonlinear Fourier transform(NFT).In this paper,we combine PDM with the method of nonlinear frequency division multiplexing(NFDM)and demonstrate the achievable transmission rate by increasing the number of multiplexing nonlinear channels.For the selected subcarriers(i.e.32,64,and 128),the transmission rates are 64 Gbit/s,76.8 Gbit/s,and 109.7 Gbit/s respectively by applying 64-quadrature amplitude modulation(64-QAM)on the nonlinear continuous spectrum.For the transmission distance shorter than 1200 km,the transmission rate of 128-NFDM PDM system can even reach up to 153.6 Gbit/s.

Exploiting the Faster-Than-Nyquist Concept in Wavelength-Division Multiplexing Systems Using Duobinary Shaping

This paper begins with Nyquist wavelengthdivision multiplexing （WDM） and then introduces fasterthanNyquist. In fasterthanNyquist a certain amount of intersymbol interference （ISI） is accepted, which violates the fundamental principle of Nyquist WDM. This results in muchrelaxed transceiver bandwidth and simpler spectral design. However, in fasterthanNyquist, implementation complexity is shifted from the transmitter side to the receiver side. Therefore, successful application of fasterthanNyquist depends on innovation in the receiver structure. In this paper, we discuss the guidelines for implementing suboptimum, lowcomplexity receivers based on fasterthanNyquist. We suggest that duobinary shaping is a good technique for trading off achievable spectral efficiency, detection performance, and implementation complexity and might be preferable to Nyquist WDM. Experiments are conducted to verify robustness of the proposed technique.

Performance Evaluation of Wavelength Division Multiplexing Photonic Analogue-to-Digital Converters for High-Resolution Radar Systems

The performance of the wavelength division multiplexing (WDM) photonic analogue-to-digital converter (ADC) used for digitization of high-resolution radar systems is evaluated numerically by using the peak signal-to-noise ratio (SNR) metric. Two different WDM photonic ADC architectures are considered for the digitization of radar signals with 5 GHz of bandwidth (spatial resolution of 3 cm), in order to provide a comprehensive study of the compromises present when deploying radar signals with high-resolution: 1) a four-channel architecture with each channel employing an ADC with 5 GSamples/s, and 2) an eight-channel architecture with each channel employing an ADC with 2.5 GSamples/s. For peak powers of the pulsed source between 10 and 20 dBm and a distance between the radar antenna and the sensing object of 2.4 meters, peak SNR levels between 29 and 39 dB are achieved with the eight-channel architecture, which shows higher peak SNR levels when compared with the four-channel architecture. For the eight-channel architecture and for the same peak powers of the pulsed source, peak SNR levels between 11 and 16 dB are obtained when the distance increases to 13.5 meters. With this evaluation using the peak SNR, it is possible to assess the performance limits when choosing a specific radar range, while keeping the same resolution.

一种基于神经网络的OFDM信号识别与符号估计改进方法

针对正交频分复用(OFDM)信号调制识别与符号估计问题,提出了一种基于深度学习神经网络(DNN)的新方法。该方法通过深入分析OFDM信号的实际传输模型,同时采用优化的Dropout策略防止过度拟合,可适用于多种调制类型数据集的训练,增强了网络学习的泛化能力;另一方面,基于改进的OFDM导频数据训练结构,提高计算效率。该新思路增强了抗噪性能,无需大量的数据先验需求,具有良好的稳健性和工程实用性。仿真结果表明新方法的识别及估计性能比起过去传统思路更优,且可在低信噪比情况下成功实现识别及估计。

基于频分复用φ-OTDR的高频振动检测与解调

相位敏感光时域反射计(φ-OTDR)是一种借助光纤为传感媒介,检测外部振动信息的可靠方案。为提高系统的探测频率,设计了一种双脉冲频分复用结构的φ-OTDR系统。通过对双脉冲信号中的其中一路采用频分复用技术处理,产生用于检测动态相位变化的不同频率载波信号,使更多的探测脉冲可以同时在光纤中传输。并针对振动信号的解调,提出一种微分自交叉相除的反正切(PGC-DSD-Arctan)算法,解决了传统算法中解调效果受调制深度影响的问题,具有更好的适用性和更高的稳定性。通过搭建系统平台,可以有效地在10 km传感范围内检测并解调出20 kHz振动信号的相位和频率信息。

基于时分复用的四通道光纤旋转连接器设计与性能测试

针对高速旋转设备分布式测量需求,设计了一种单通道光纤旋转连接器(FROJ),并进行了性能测试。以此单通道FROJ为基础,采用磁光开关通过时分复用方式设计了四通道FROJ,在静态和动态条件下分别测试了其插入损耗。实验结果表明:该四通道FROJ的插入损耗小于4.5 d B,旋转变化量小于2 d B,在转速不超过600 r/min时可以实现光信号的可靠传输。

光子辅助太赫兹通信技术研究进展

面对互联网时代呈指数增长的全球数据流量,超高速通信的发展需求日益迫切,太赫兹通信因拥有巨大的可用带宽资源,成为下一代超高速无线通信关键技术之一。太赫兹通信系统分为电子学与光子辅助两种类型,其中后者在通信速率、频率灵活调控、与光纤接入网无缝融合等方面具有独特优势。首先介绍了典型光子辅助太赫兹通信系统的基本原理,在此基本原理框架下,梳理了系统中信号生成与接收、多维复用以及概率整形等技术的研究进展,并探讨了该类通信系统需要进一步解决的问题。

光子灯笼模分复用系统MIMO-free高速传输实验

为考察无需多输入多输出模分复用系统的高速信号传输能力,采用模式选择光子灯笼型模式复用/解复用器构建了2×100 Gb/s双偏振正交相移键控模分复用通信实验系统,系统中用到的少模偏振控制器状态可由LP_(01)和LP_(11b)两个模式信道的信串比参数准确表征。测试了系统误码率与信串比关系,实现两个信道纠后无误码传输的条件为信串比约大于8 dB。当两个信道的信串比分别为14.25 dB和13.81 dB时,与背对背收发系统相比,纠后无误码阈值(10^(-2))的接收光功率代价分别为1.40 dB和4.76 dB。分析了光纤衰减、偏振模色散和模式串扰对高速传输系统的影响,估算了串扰受限系统可支持的少模光纤传输距离约为30 km。

雷达通信一体化5G信号设计方法

随着第五代(Fifth Generation, 5G)通信技术的发展,利用雷达通信一体化5G信号实现低空目标探测具有广泛的应用前景。本文提出一种雷达通信一体化5G信号设计方法,首先建立了雷达通信一体化正交频分复用(Orthogonal Frequency Division Multiplexing,OFDM)信号发射接收模型,并提出一种区间线性相位压缩(Interval Linear Phase Compression,ILPC)通信信息调制方法来降低通信加入对信号探测性能的影响;接着以峰均功率比(Peak to Average Power Ratio, PAPR)、雷达脉压后的信噪比(Signal to Noise Ratio, SNR)恢复因子以及通信误码率(Bit Error Rate,BER)为优化目标,以发射信号循环前缀置零和时/频域序列恒模为约束,建立多目标优化问题模型;为了兼顾雷达性能和通信性能,本文提出一种时/频域迭代Clipping加滤波算法求解该优化问题。最后,在典型5G通信工作场景下验证了所提方法的有效性。