Hybrid Predictive Control Based on High-Order Differential State Observers and Lyapunov Functions for Switched Nonlinear Systems

In this paper, a hybrid predictive controller is proposed for a class of uncertain switched nonlinear systems based on high-order differential state observers and Lyapunov functions. The main idea is to design an output feedback bounded controller and a predictive controller for each subsystem using high-order differential state observers and Lyapunov functions, to derive a suitable switched law to stabilize the closed-loop subsystem, and to provide an explicitly characterized set of initial conditions. For the whole switched system, based on the high-order differentiator, a suitable switched law is designed to ensure the whole closed-loop’s stability. The simulation results for a chemical process show the validity of the controller proposed in this paper.

Introducing the nth-Order Features Adjoint Sensitivity Analysis Methodology for Nonlinear Systems (nth-FASAM-N): II. Illustrative Example

This work highlights the unparalleled efficiency of the “nth-Order Function/ Feature Adjoint Sensitivity Analysis Methodology for Nonlinear Systems” (nth-FASAM-N) by considering the well-known Nordheim-Fuchs reactor dynamics/safety model. This model describes a short-time self-limiting power excursion in a nuclear reactor system having a negative temperature coefficient in which a large amount of reactivity is suddenly inserted, either intentionally or by accident. This nonlinear paradigm model is sufficiently complex to model realistically self-limiting power excursions for short times yet admits closed-form exact expressions for the time-dependent neutron flux, temperature distribution and energy released during the transient power burst. The nth-FASAM-N methodology is compared to the extant “nth-Order Comprehensive Adjoint Sensitivity Analysis Methodology for Nonlinear Systems” (nth-CASAM-N) showing that: (i) the 1st-FASAM-N and the 1st-CASAM-N methodologies are equally efficient for computing the first-order sensitivities;each methodology requires a single large-scale computation for solving the “First-Level Adjoint Sensitivity System” (1st-LASS);(ii) the 2nd-FASAM-N methodology is considerably more efficient than the 2nd-CASAM-N methodology for computing the second-order sensitivities since the number of feature-functions is much smaller than the number of primary parameters;specifically for the Nordheim-Fuchs model, the 2nd-FASAM-N methodology requires 2 large-scale computations to obtain all of the exact expressions of the 28 distinct second-order response sensitivities with respect to the model parameters while the 2nd-CASAM-N methodology requires 7 large-scale computations for obtaining these 28 second-order sensitivities;(iii) the 3rd-FASAM-N methodology is even more efficient than the 3rd-CASAM-N methodology: only 2 large-scale computations are needed to obtain the exact expressions of the 84 distinct third-order response sensitivities with respect to the Nordheim-Fuchs model’s parameters when applying the 3rd-FASAM-N methodology, while the application of the 3rd-CASAM-N methodology requires at least 22 large-scale computations for computing the same 84 distinct third-order sensitivities. Together, the nth-FASAM-N and the nth-CASAM-N methodologies are the most practical methodologies for computing response sensitivities of any order comprehensively and accurately, overcoming the curse of dimensionality in sensitivity analysis.

Signal Classification Method Based on Support Vector Machine and High-Order Cumulants

In this paper, a classification method based on Support Vector Machine (SVM) is given in the digital modulation signal classification. The second, fourth and sixth order cumulants of the received signals are used as classification vectors firstly, then the kernel thought is used to map the feature vector to the high dimensional feature space and the optimum separating hyperplane is constructed in space to realize signal recognition. In order to build an effective and robust SVM classifier, the radial basis kernel function is selected, one against one or one against rest of multi-class classifier is designed, and method of parameter selection using cross- validation grid is adopted. Through the experiments it can be concluded that the classifier based on SVM has high performance and is more robust.

Lattice Boltzmann simulations of high-order statistics in isotropic turbulent flows

The lattice Boltzmann method （LBM） is coupled with the multiple-relaxation- time （MRT） collision model and the three-dimensional 19-discrete-velocity （D3Q19） model to resolve intermittent behaviors on small scales in isotropic turbulent flows. The high- order scaling exponents of the velocity structure functions, the probability distribution functions of Lagrangian accelerations, and the local energy dissipation rates are investi- gated. The self-similarity of the space-time velocity structure functions is explored using the extended self-similarity （ESS） method, which was originally developed for velocity spatial structure functions. The scaling exponents of spatial structure functions at up to ten orders are consistent with the experimental measurements and theoretical results, implying that the LBM can accurately resolve the intermittent behaviors. This valida~ tion provides a solid basis for using the LBM to study more complex processes that are sensitive to small scales in turbulent flows, such as the relative dispersion of pollutants and mesoscale structures of preferential concentration of heavy particles suspended in turbulent flows.

探地雷达正演的间断伽辽金法影响因素分析

时域间断伽辽金(discontinuous Galerkin time-domain, DGTD)算法具有守恒性、稳定性、高精度性和间断性等优点,现已成为一种有效的探地雷达(Ground penetrating radar, GPR)正演方法.为了提高DGTD算法的计算效率和精度,作者详细分析了数值通量、时间离散格式、单元大小与局部基函数阶次、网格剖分方式等影响因素.数值实验表明,局部Lax-Friedrichs中τ=1/2的补偿数值通量既可以消除伪解,又可以提高计算精度;在精度相同的情况下,低存储显式Runge-Kutta方案(low-storage explicit Runge-Kutta, LSERK)的稳定性条件和低存储优势要明显优于其它两种时间离散格式,尤其是在大型复杂模型和三维正演模拟中更有优势.而提高基函数的阶次或增大网格数,均可以提高其误差的收敛性,局部基函数阶次N和单元大小d与电磁波波长λ的适用关系为d/N约等于λ/15;当单元数目大致相等时,网格剖分方式对于高阶DGTD算法的影响较小,说明DGTD算法对网格具有较好的适应性.最后,采用DGTD算法对火星乌托邦平原模型进行正演,验证了基于最优参数的DGTD算法模拟精度高,可为火星乌托邦平原GPR实测数据的解译奠定理论基础.

一种基于TRT-SKT-HAF的变加速目标快速相参积累算法

在雷达高速机动目标的检测中,目标的运动特性会带来距离走动和多普勒徙动现象,不利于后续进行相参积累。传统算法为解决目标运动造成的影响,需要对目标的运动参数进行搜索,加大了计算量。针对上述问题,文中提出了一种基于慢时间序列反转变换(TRT)-二阶keystone变换(SKT)-高阶模糊函数(HAF)的变加速目标快速相参积累算法。该算法通过TRT和SKT校正距离走动,利用HAF估计目标加速度并构建相位补偿函数以校正多普勒徙动。与广义Radon-Fourier变换相比,所提方法无需进行任何参数搜索,计算复杂度减少了3个数量级。仿真结果表明,所提方法在检测门限上相比于Radon分数阶模糊函数算法降低了5 dB,在低信噪比下有更好的检测性能。

G-L分数导数高阶逼近算法的鲁比希生成函数系数的求解

考察G-L分数导数的逼近阶,引出高精度的数值算法,提出三种求解鲁比希高阶逼近生成函数系数的方法 .从信号处理的角度出发,采用拉格朗日插值逼近法首次在理论上严格推导出鲁比希生成函数系数的解析表达式.构造了任意阶次的生成函数,通过不同形式的生成函数等价,用数学归纳和矩阵方程两种方法对生成函数系数进行求解,验证了结果的正确性.

MCI患者高阶动态功能连接的图论网络构建方法及分类

针对在低阶脑网络应用图论忽视了功能连接高阶动态性的问题,提出了一种基于高阶动态功能连接的图论网络构建方法(GNC-HodFC),提取高阶FC网络的图论特征以对轻度认知障碍患者和健康被试者进行差异性分析及分类。首先定义了表征高阶动态脑网络连接的图论节点和边;然后利用滑动窗相关技术提取低阶功能连接信息,提出平稳性判据,选取最优特征子集以构建图论的节点;最后提出自适应阈值策略对高阶动态功能连接信息进行选取以构建图论的边,最终完成高阶动态脑网络的图构建。实验结果表明,GNC-HodFC的平均分类准确率可以达到70.5%,优于其他三种对比方法,且患者组和健康组的图论特征中存在显著性差异,GNC-HodFC方法可以为轻度认知障碍的诊断提供新的辅助手段。

高次旋转多项式的夹爪驱动盘设计分析

针对机械夹爪驱动盘运动轨迹平滑性设计问题,提出转盘类时间指数的高次多项式与一次旋转方程相融合的方法。在平面坐标系中对时间类指数高次多项式函数进行参数矩阵(基圆半径、联动圆盘类时间指数、运动行程角、运动行程)设定。将平面坐标系中相关高次多项式离散点带入旋转坐标系中实现偏转,得到高次旋转多项式轨迹方程。采用一次到八次多项式分别对机械夹爪驱动盘运动轨迹曲线的位移、类速度、类加速度、类超加速度进行分析,得知二次以上旋转多项式的机械夹爪驱动盘运动轨迹基本处于平滑状态。实验证明:机械夹爪驱动盘运动的平稳性与次数有关。

基于神经网络的机械臂高阶滑模控制

针对多关节机械臂控制系统的设计中机械臂模型参数未知和外在干扰的抖振问题,提出一种基于神经网络的机械臂高阶滑模控制,并在快速终端滑模面的基础上,利用饱和函数解决了奇异问题,采用径向基神经网络(RBFNN)近似估计系统参数,增加了误差估计器补偿估计误差和外部干扰。同时,设计了一种具有适当更新律的自适应有限时间控制律。实验表明:该控制方法在机械臂轨迹跟踪表现更优,具有可行性和优越性。

基于全驱系统方法的高阶严反馈系统时变输出约束控制

针对输出受不对称时变约束的不确定高阶严反馈系统,提出一种基于全驱系统方法的高阶自适应动态面输出约束控制方法.所研究的高阶严反馈系统,每个子系统都是高阶形式,通过非线性转换函数将原输出约束系统转换为新的无约束系统,从而将原系统输出约束问题转化为新系统输出有界的问题.进一步结合全驱系统方法和自适应动态面控制,直接将每个高阶子系统作为一个整体进行控制器设计,而不需要将其转化为一阶系统形式,有效简化了设计步骤;同时通过引入一系列低通滤波器来获得虚拟控制律的高阶导数,以代替复杂的微分运算.基于Lyapunov稳定性理论证明闭环系统所有信号是一致最终有界的,系统输出在满足约束的条件下能有效跟踪期望的参考信号,且可通过调整参数使得系统跟踪误差收敛到零附近的足够小的邻域内.最后,通过对柔性关节机械臂系统进行仿真,验证了所提出控制方法的有效性.

Estimating Functional Brain Network with Low-Rank Structure via Matrix Factorization for MCI/ASD Identification

Functional brain networks (FBNs) provide a potential way for understanding the brain organizational patterns and diagnosing neurological diseases. Due to its importance, many FBN construction methods have been proposed currently, including the low-order Pearson’s correlation (PC) and sparse representation (SR), as well as the high-order functional connection (HoFC). However, most existing methods usually ignore the information of topological structures of FBN, such as low-rank structure which can reduce the noise and improve modularity to enhance the stability of networks. In this paper, we propose a novel method for improving the estimated FBNs utilizing matrix factorization (MF). More specifically, we firstly construct FBNs based on three traditional methods, including PC, SR, and HoFC. Then, we reduce the rank of these FBNs via MF model for estimating FBN with low-rank structure. Finally, to evaluate the effectiveness of the proposed method, experiments have been conducted to identify the subjects with mild cognitive impairment (MCI) and autism spectrum disorder (ASD) from norm controls (NCs) using the estimated FBNs. The results on Alzheimer’s Disease Neuroimaging Initiative (ADNI) dataset and Autism Brain Imaging Data Exchange (ABIDE) dataset demonstrate that the classification performances achieved by our proposed method are better than the selected baseline methods.

并网变换器的多频率耦合等幅振荡分析

电压源型并网变换器与交流电网相互作用会引发新型电磁振荡现象。受控制器非线性环节的影响,该振荡不能持续发散,最终将形成等幅振荡。目前,已有研究多利用描述函数法对系统的限幅环节进行建模,从而计算振荡的幅值和频率。但是这些模型都忽略了非线性环节导致的高阶振荡分量。对现有方法进行了改进,提出了一种计及高阶振荡分量的并网变换器等幅振荡分析方法,推导了考虑高阶振荡分量后非对称限幅的描述函数,及考虑高阶分量后等幅振荡频率和幅值的计算方法,并将该方法应用于单轴限幅和双轴限幅的振荡分析。最后,利用仿真验证了所提改进方法的准确性。理论分析和仿真验证表明,所提方法提高了并网变换器等幅振荡的分析精度,并且能够计算高阶振荡分量的幅值。

水平轴风力机三维全尾流模型推导及验证

为进一步了解整个尾流区域的速度衰减空间分布特征,提出一种三维全尾流模型。首先,采用高阶高斯函数预测尾流剖面,其在近尾流区由顶帽形演变为远尾流区的高斯形;其次,考虑风切变效应,引入风切变入流与均匀入流的风速差;此外,考虑到尾流膨胀的各向异性,在垂直方向和水平方向采用不同的尾流膨胀系数;最后,通过风场实验验证所提三维全尾流模型的准确性,结果表明所提出的全尾流模型预测的相对误差基本在5%以内,能够较好地预测整个尾流区域的三维分布。

具有高阶扰动的Oregonator模型的平稳分布研究

为了探究随机不确定因素对化学振荡反应动力学行为的影响,建立了一个具有高阶扰动的Oregonator模型,并通过构造合适的Lyapunov函数得到了系统存在遍历平稳分布的充分条件.数值模拟结果表明,小噪声能够促进系统反应的持续进行(即有利于促进系统的平稳分布),而大噪声则不利于系统反应的持续进行.

HIGH ORDER NUMERICAL METHODS TO TWO DIMENSIONAL HEAVISIDE FUNCTION INTEGRALS

In this paper we design and analyze a class of high order numerical methods to two dimensional Heaviside function integrals. Inspired by our high order numerical methods to two dimensional delta function integrals [19], the methods comprise approximating the mesh cell restrictions of the Heaviside function integral. In each mesh cell the two dimen- sional Heaviside function integral can be rewritten as a one dimensional ordinary integral with the integrand being a one dimensional Heaviside function integral which is smooth on several subsets of the integral interval. Thus the two dimensional Heaviside function inte- gral is approximated by applying standard one dimensional high order numerical quadra- tures and high order numerical methods to one dimensional Heaviside function integrals. We establish error estimates for the method which show that the method can achieve any desired accuracy by assigning the corresponding accuracy to the sub-algorithms. Numerical examples are presented showing that the in this paper achieve or exceed the expected second to fourth-order methods implemented accuracy.

三维高阶数值流形方法研究

将三维流形单元的位移函数从一阶拓展为二阶,基于最小势能原理建立了有限单元覆盖的高阶流形方法分析格式,详细推导了三维流形单元的刚度矩阵、等效节点荷载列阵以及位移约束矩阵。计算结果表明,提高物理覆盖函数的阶次可有效提高流形方法的计算精度。

微弱信号长时间积累的检测方法

提出一种微弱信号长时间积累的检测方法 .对雷达回波信号采用时域分帧处理 ,每帧进行门限预处理 ,剔除大部分干扰噪声 ,仅保留包含目标在内的部分 HAF谱成分以作后续的帧间累加 .仿真结果表明 ,该方法可以有效地进行信号积累 ,只需 1 / 4或 1 / 8的存储量 ,就可以取得与

基于CCSDS高级在轨系统的MPDU复用效率研究

MPDU包信道复用作为CCSDS两级多路复用机制的第一级,其复用效率直接影响CCSDS高级在轨系统的高效性和有效数据的承载能力。在泊松分布固定包长成帧模型的基础上,提出了高阶剩余函数的概念,并给出了MPDU复用效率递推公式。仿真结果表明,随着阶数的增加,理论与仿真曲线呈逼近趋势,对4阶递推公式最小相对误差可达1.3329%。

高低阶覆盖函数混合的数值流形方法

在数值流形方法中混合使用高、低阶覆盖函数可以使求解精度和求解效率之间得到协调。同时,高低阶覆盖函数混合使用也体现了数值流形方法本身的灵活性和对复杂问题的适应性。本文详细推导了混合使用高、低阶覆盖函数的流形单元的数值计算格式,有利于数值流形方法的程序实现和工程应用,并通过岩土工程中地基变形的计算证明了方法的可靠性和有效性。