基于快速平行因子分解的声矢量传感器阵二维DOA估计

将声矢量传感器阵列参数估计问题与平行因子(Parallel factor,PARAFAC)模型相结合,提出了一种基于快速PARAFAC分解的二维波达方向(Direction of arrival,DOA)估计算法。该算法首先将接收信号构建为PARAFAC模型,然后在数据域对参数矩阵进行初估计,最后利用PARAFAC分解获得信号二维DOA估计。该算法能够应用于任意结构的声矢量传感器阵列,同时能够得到和信源一一匹配的仰角和方位角估计。借助于参数矩阵的初始估计,所提算法收敛速度较快,其计算复杂度大大降低。该算法角度估计性能接近于PARAFAC算法,同时优于借助旋转不变性进行信号参数估计(Estimation of signal parameters via rotational invariance technique,ESPRIT)算法和传播算子(Propagator method,PM)算法。     

多径信道中多用户检测和DOA估计联合处理方法

提出了一种基于三线性模型的多径信道中多用户检测和波达方向(Directionofarrival,DOA)估计联合处理方法。对阵列接收到的信号分析表明,阵列接收信号具有三线性模型特征。在分析单径信道中的三线性模型的基础上,研究了多径信道中阵列接收信号三线性模型,提出了一种改进的三线性交替最小二乘(Improvedtrilinearalternatingleastsquare,ITALS)算法,它可对多用户检测和DOA估计进行联合处理。该算法利用方向矩阵的Vandermonde特征、基于最小二乘法对方向矩阵进行重构和DOA估计。仿真结果说明,该方法具有较好的误码率性能、较快的收敛性能和精确的DOA估计性能。当DOA靠近90°时,DOA估计性能下降。     

声矢量传感器阵中基于Kalman滤波和OPASTd的DOA跟踪算法

研究了声矢量传感器阵动目标角度跟踪问题,并提出了声矢量传感器阵中 一种基于Kalman滤波和正交压缩近似投影子空间跟踪(Orthonormal projection approximation and subspace tracking of deflation, OPASTd)的波达方向(Direction of arrival,DOA)跟踪算法。该算法通过OPASTd算法来进行DOA的跟踪,从而克服了PASTd算法由于在某些情况下振荡但不收敛进而压缩数据、在迭代更新中由特征向量的不准确性产生误差累积等原因引起破坏信号子空间正交性的缺陷。Kalman滤波和OPASTd相结合算法可在估计角度的同时进行数据关联,与传统的PASTd算法相比,角度跟踪性能更好。该算法的优越性均可在文中得到验证。     

大时延扩展CDMA信道下空时多用户检测

提出了基于平行因子分析的大时延扩展CDMA信道下空时多用户检测算法.文中建立了大时延扩展CD-MA信道下接收信号新模型,它将接收信号看成是2个三线性模型之和,并提出了广义三线性交替最小二乘的算法(TALS-G)进行空时多用户检测.仿真结果说明:TALS-G算法具有较好误码率性能,且该方法在阵列扰动情况下仍有较好的性能.它无需信道衰落系数和DOA信息,是盲信号检测方法,具有鲁棒性.     

均匀面阵中高效率的二维波达方向估计方法：降维求根MUSIC算法（英文）

波达方向估计是阵列信号处理研究的重要方向之一。本文在降维求根技术和MUSIC算法的基础上,研究了均匀平面阵列的二维波达方向估计问题。首先基于噪声子空间和方向矢量之间的正交关系构造二维求根多项式,并证明该多项式包含无限多个解。为获取这些解中包含的真实目标参数,提出了一种新的低复杂度、计算效率高的算法,即降维求根MUSIC算法。所提算法应用降维求根技术目标的真实解,其中二维求根方程被转换为两次一维求根,该过程有效降低了求根难度。最后,通过一次配对过程获取目标角度参数的估计值。数值模拟验证了该方法的有效性和优越性。     

一维与二维信号的快速内插算法

一维信号的快速内插在语音处理、数字波束形成、雷达实时仿真等方面有重要应用。图象处理中则常需对二维信号进行内插。文中首先提出了一种利用ＦＦＴ的一维信号内插的子序列算法。去除了Ａｄａｍｓ算法的额外补偿项ｅｒ（ｍ）与其他冗余运算，所需实乘数只有Ａｄａｍｓ算法的２０％左右，实加数约为Ａｄａｍｓ算法的３０％。然后本文又提出了一种基于子序列ＦＦＴ的二维信号快速内插算法。该算法不仅解决了Ｓａｔｈｙａｎａｒａｙａ     

基于方向调制的无线安全传输基本原理、关键技术与未来展望

方向调制(Directional modulation,DM)作为无线物理层安全传输的关键技术能够很好地提升系统的安全性能。然而,由于在角度测量过程中存在误差,因此需要在设计有用信号波束成形向量和人工噪声(Artificial noise,AN)投影矩阵时考虑角度误差,从而提升系统安全性能。本文首先描述了DM系统模型,然后介绍了到达角(Direction of arrival,DOA)估计技术、稳健波束成形设计的3种算法及功率分配技术。仿真表明:稳健波束成形合成方法的性能明显要优于非稳健合成方法,且有用信号和AN之间最优功率分配能明显提高安全速率性能。最后,对DM未来新的发展方向与所面临的挑战性等开放问题进行展望与总结。     

基于频偏校正的正弦波频率估计算法

提出了一种新的正弦信号频率估计方法。利用FFT对信号频率作粗估计,然后对原信号下变频至基带。对基带信号作相位差分,估计频偏。最后对粗估计进行频率校正,使估计性能得到提高。在整个频段上该方法与R ife算法性能互补,在此基础上又提出了综合方法。仿真结果表明,该频率校正算法实现简单,运算量小,且性能不随被估计信号的频率分布而产生波动,在适度信噪比条件下均方根误差小于1.5倍的CRLB,具有广阔的应用前景。     

极化敏感均匀圆阵中PARAFAC信号检测算法

分析了极化敏感均匀圆阵接收到的信号，该信号具有三线性模型特征。提出了极化敏感均匀圆阵中平行因子信号检测算法。该算法利用三线性交替最小二乘（TALS）算法估计出信源矩阵，然后对其进行判决。仿真结果表明；该算法误码率性能接近于非盲解相关方法;与非盲解相关方法相比，在较高的SNR情况下误码率相差不到2dB；且在阵列扰动情况下仍具有较好的误码率性能。该算法无需空域信息和极化信息，是一种盲鲁棒方法。     

ESPRIT算法在单快拍阵列信号中的应用

ESPRIT算法利用旋转不变技术估计信号参数,是近年来提出的阵列信号处理理论的一个新领域,它具有高分辨率、高精度、不需空间搜索等优点。单快拍总被当作相干信号处理,本文采用了Teoplitz结构协方差矩阵估计,起了空间平滑作用,所以可以估计相于信号源的波达方向(DOA),与标准空间平滑协方差矩阵估计相比较,Teoplitz协方差阵估计在总体上提高了信噪比,并且不牺牲阵列孔径。 计算机模拟结果表明,基于Teoplitz结构协方差矩阵的TLS-ESPRIT算法在20dB信噪比下,可以分辨出相隔0.2瑞利波束宽度的空间信号。     

A Real-Valued 2D DOA Estimation Algorithm of Noncircular Signal via Euler Transformation and Rotational Invariance Property

The problem of two-dimensional(2 D)direction of arrival(DOA)estimation for double parallel uniform linear arrays is investigated in this paper.A real-valued DOA estimation algorithm of noncircular(NC)signal is proposed,which combines the Euler transformation and rotational invariance(RI)property between subarrays.In this work,the effective array aperture is doubled by exploiting the noncircularity of signals.The complex arithmetic is converted to real arithmetic via Euler transformation.The main contribution of this work is not only extending the NC-Euler-ESPRIT algorithm from uniform linear array to double parallel uniform linear arrays,but also constructing a new 2 Drotational invariance property between subarrays,which is more complex than that in NCEuler-ESPRIT algorithm.The proposed 2 DNC-Euler-RI algorithm has much lower computational complexity than2 DNC-ESPRIT algorithm.The proposed algorithm has better angle estimation performance than 2 DESPRIT algorithm and 2 D NC-PM algorithm for double parallel uniform linear arrays,and is very close to that of 2 D NC-ESPRIT algorithm.The elevation angles and azimuth angles can be obtained with automatically pairing.The proposed algorithm can estimate up to 2(M-1)sources,which is two times that of 2 D ESPRIT algorithm.Cramer-Rao bound(CRB)of noncircular signal is derived for the proposed algorithm.Computational complexity comparison is also analyzed.Finally,simulation results are presented to illustrate the effectiveness and usefulness of the proposed algorithm.     

Low-Complexity DOA Estimation of Noncircular Signals for Coprime Sensor Arrays

This paper presents a low-complexity method for the direction-of-arrival(DOA)estimation of noncircular signals for coprime sensor arrays. The noncircular property is exploited to improve the performance of DOA estimation. To reduce the computational complexity,the rotational invariance propagator method(RIPM)is included in the algorithm. First,the extended array output is reconstructed by combining the array output and its conjugated counterpart. Then,the RIPM is utilized to obtain two sets of DOA estimates for two subarrays. Finally,the true DOAs are estimated by combining the consistent results of the two subarrays. This illustrates the potential gain that both noncircularity and coprime arrays provide when considered together. The proposed algorithm has a lower computational complexity and a better DOA estimation performance than the standard estimation of signal parameters by the rotational invariance technique and Capon algorithm. Numerical simulation results illustrate the effectiveness and superiority of the proposed algorithm.     

Computationally Efficient MUSIC-Based Algorithm for Joint Direction of Arrival (DOA) and Doppler Frequency Estimation in Monostatic MIMO Radar

The problem of joint direction of arrival (DOA) and Doppler frequency estimation in monostatic multiple-input multiple-output (MIMO) radar is studied and a computationally efficient multiple signal classification (CE-MUSIC) algorithm is proposed.Conventional MUSIC algorithm for joint DOA and Doppler frequency estimation requires a large computational cost due to the two dimensional (2D) spectral peak searching.Aiming at this shortcoming,the proposed CE-MUSIC algorithm firstly uses a reduced-dimension transformation to reduce the subspace dimension and then obtains the estimates of DOA and Doppler frequency with only one-dimensional (1D) search.The proposed CE-MUSIC algorithm has much lower computational complexity and very close estimation performance when compared to conventional 2D-MUSIC algorithm.Furthermore,it outperforms estimation of signal parameters via rotational invariance technique (ESPRIT) algorithm.Meanwhile,the mean squared error (MSE) and Cramer-Rao bound (CRB) of joint DOA and Doppler frequency estimation are derived.Detailed simulation results illustrate the validity and improvement of the proposed algorithm.     

A Generalized Propagator Algorithm for Localization of Non-circular Sources Using Arbitrary Array Geometry

A propagator-based algorithm for direction of arrival(DOA)estimation of noncoherent one-dimensional(1-D) non-circular sources is presented such as binary phase shift keying(BPSK) and amplitude modulation(AM). The algorithm achieves DOA estimation through searching a 1-D spectrum,which is newly formed on the basis of the rank reduction criterion,and works well without knowledge of the non-circular phases. And then,a searchfree implementation of the algorithm is also developed by using the polynomial rooting technique. According to the noncircular property,the algorithm can virtually enlarge the array aperture,thus significantly improving its estimation accuracy and enabling it to handle more sources than the number of sensors. Moreover,the algorithm requires no rotational invariance,so it can be applied to arbitrary array geometry and dispense with the high-complexity procedure of the eigen-decomposition of the correlation sample matrix. Finally,numerical simulations verify the performance and effectiveness of the proposed algorithm.     

Computationally Efficient Direction of Arrival Estimation for Improved Nested Linear Array

Nested linear array enables to enhance localization resolution and achieve under-determined direction of arrival(DOA)estimation. In this paper,the traditional two-level nested linear array is improved to achieve more degrees of freedom(DOFs)and better angle estimation performance. Furthermore,a computationally efficient DOA estimation algorithm is proposed. The discrete Fourier transform(DFT)method is utilized to obtain coarse DOA estimates,and subsequently,fine DOA estimates are achieved by spatial smoothing multiple signals classification(SS-MUSIC)algorithm. Compared to SS-MUSIC algorithm,the proposed algorithm has the same estimation accuracy with lower computational complexity because the coarse DOA estimates enable to shrink the range of angle spectral search. In addition,the estimation of the number of signals is not required in advance by DFT method. Extensive simulation results testify the effectiveness of the proposed algorithm.     

虚拟阵列测向性能分析

针对相干信号源测向以及模糊的实际问题,提出一种基于任意形状平面阵列的测向方法。经计算机仿真,证明该方法的有效性。     

Threshold Selection Method Based on Reciprocal Gray Entropy and Artificial Bee Colony Optimization

Since the logarithmic form of Shannon entropy has the drawback of undefined value at zero points,and most existing threshold selection methods only depend on the probability information,ignoring the within-class uniformity of gray level,a method of reciprocal gray entropy threshold selection is proposed based on two-dimensional（2-D）histogram region oblique division and artificial bee colony（ABC）optimization.Firstly,the definition of reciprocal gray entropy is introduced.Then on the basis of one-dimensional（1-D）method,2-D threshold selection criterion function based on reciprocal gray entropy with histogram oblique division is derived.To accelerate the progress of searching the optimal threshold,the recently proposed ABC optimization algorithm is adopted.The proposed method not only avoids the undefined value points in Shannon entropy,but also achieves high accuracy and anti-noise performance due to reasonable 2-D histogram region division and the consideration of within-class uniformity of gray level.A large number of experimental results show that,compared with the maximum Shannon entropy method with 2-D histogram oblique division and the reciprocal entropy method with 2-D histogram oblique division based on niche chaotic mutation particle swarm optimization（NCPSO）,the proposed method can achieve better segmentation results and can satisfy the requirement of real-time processing.     

一种目标散射中心特征快速提取算法

首先用基于几何绕射理论的GTD(Geometrical theory of diffraction)模型来精确描述雷达目标的高频电 磁散射特性;同时,提出一种可应用于目标识别的散射中心特征提取快速算法:基于传播算子(Propagator)的 多重信号特征算法(PM-MUSIC).其核心思想是利用传播算子法快速计算出噪声子空间,取代了原MUSIC方法中利用特征值分解获取噪声子空间的矩阵分解步骤.通过计算量的比较,说明PM-MUSIC算法较原MUSIC方法有效提高了运算效率.最后.仿真实验表明,PM-MUSIC算法在快速估计的基础上,仍具有良好的精度和较高的分辨率,可有效地提取以边缘绕射等为主要散射形式的隐身目标的散射中心.     

互耦补偿的神经网络算法用于均匀圆阵波达方向估计

径向基函数神经网络方法在阵列信号处理中得到广泛应用。但是，阵列天线单元间耦合对基函数中心的影响会降低波达方向估计的精度，因此有必要对神经网络的输入数据进行互耦补偿，以生成正确的基函数中心。本文首先利用矩量法计算天线阵的广义阻抗矩阵，再使用直接数据域算法对神经网络的训练数据进行互耦补偿，神经网络训练完成后，神经网络用于实现波达方向估计。仿真结果表明，神经网络算法和直接数据域算法结合具有补偿效果好，计算量小的特点。