微分代数

In the chapter7 and 8, the numerical algorithm for the variable delay differential algebraic system is studied.

在第七、八章，本文就变延迟微分代数系统的数值算法展开了研究。

And the further research is carried out for stability of differential algebraic hybrid system. And the stability theory put forward in the dissertation is used in the analysis and control of voltage stability of power system.

针对微分代数混杂系统的稳定性分析进行深入研究，并将其应用于电力系统电压稳定性的分析和控制。

To construct canonical equation for the constrained Hamiltonian systems dynamics

在最后，介绍了一般的微分/代数方程组的一些重要概念，如指标等

All these results provide some theoretical foundation and justification for the DAE control system design.

这些工作一定程度上为电力系统基于微分代数模型的几何控制设计提供了理论基础。

In recent years, some new research methods such as mordern geometric method and differential algebra method have been applied to the study of control theory according to the development of nonlinear science, and it is possible for us to solve complicated enginering systems with the development of computer science, which promotes the investigation of complicated control systems.

近年来，非线性科学的发展，特别是现代微分几何，微分代数理论的出现，为非线性控制理论的研究提供了新的工具。

Based on the flexible multibody dynamics model, that establish, a group of the algebra—differential hybrid equations which is made up of kinematics differential equation and spatial constraint algebra equations is listed by leading into the Lagrange multiplier to release the constraint of the system.

根据上述建立的多柔体动力学模型，通过引入Lagrange乘子释放系统的约束，列出了由系统的运动微分方程和空间约束代数方程组成的一组微分—代数混合方程组。

In most situations, the polysome system dynamic equation is the non-linearity the ordinary differential equation or the differential - algebra system of equations, it is generally obtains the equation through the computer value simulation then get the numerical solution, then through to numerical solution analysis, understanding polysome system dynamics characteristic.

多数情况下，多体系统的动力学方程是非线性常微分方程或微分-代数方程组，一般是通过计算机数值仿真得到方程的数值解，然后通过对数值解的分析，了解多体系统的动力学特性。

The solution can't already behalf the real movement of the constraint multibody system so the default of the constraint equation must be restrained; On the other hand is how to turn the differential — algebra hybrid equations into the pure differential equations effectively.

得到的解已经不能表示约束多体系统的真实运动，所以必须对约束方程的违约进行抑制；另一方面是怎样有效地将微分—代数混合方程组化为纯微分方程组，运用求解微分方程组的计算方法求解。

Here pis 1 or 2.In chapter 8. we extend the Runge-Kutta methods to variable delay differentialalgebraic system. It is proved that if the Runge-Kutta method which is algebraicallystable and diagonally stable is consistent with order p , the extended Runge-Kuttamethod with Lagrange interpolation procedure is D_A-convergence with order M. HereM=min{p, u + q + 1 }, and u + q is the degree of Lagrange interpolation polynomial.

第八章将求解常微分方程的Runge-Kutta方法改造后用于求解变延迟微分代数系统，并且证明如果代数稳定且对角稳定的Runge-Kutta方法对于常微分方程初值问题在经典意义下是p阶相容的，那么具有Lagrange插值过程的该方法是M阶D_A-收敛的，M=min{p，u+q+1}，u+q为Lagrange插值多项式的次数。

Fundamental concepts in power system differential-algebraic equations model, like singular point and multiple energy function sheets defined on constraint manifolds, are studied.

所得研究成果揭示了微分代数模型与奇异扰动模型的本质区别、奇异性与系统模型和系统负载的联系、结构保持能量函数法可能具有的内在保守性等，这对深入理解电力系统微分代数方程模型的拓扑结构、结构保持能量函数法和暂态电压稳定及其与功角稳定的关系具有一定的价值。

differential algebra：微分代数

differential 微分 | differential algebra 微分代数 | differential analyzer 微分分析仪

differential graded algebra：微分分次代数

微分方程解析理论|analytic theory of differential equation | 微分分次代数|differential graded algebra | 微分环|differential ring

Linear Algebra Differential Equation：线性代数微分方程

线性代数 Linear Algebra | 线性代数微分方程 Linear Algebra Differential Equation | 线性规划 Linear Programming

Linear Algebra and Differential Equation：线性代数微分方程

线性代数 Linear Algebra | 线性代数微分方程 Linear Algebra and Differential Equation | 线性规划 Linear Programming

Linear Algebra & Differential Equation：线性代数微分方程

制冷技术 Refrigeration Technique | 线性代数微分方程 Linear Algebra & Differential Equation | 计算方法与算法语言 Computational Method & Algorithmic Language

Linear Algebra %26amp; Differential Equation：线性代数微分方程

1986. 制冷技术 Refrigeration Technique | 1987. 线性代数微分方程 Linear Algebra %26amp; Differential Equation | 1988. 计算方法与算法语言 Computational Method %26amp; Algorithmic Language

differential form：微分形式

微分形式(differential form) 是多变量微积分,微分拓扑和张量分析领域的一个数学概念. 现代意义上的微分形式,及其以楔积和外微分结构形成外代数的想法,都是由著名法国数学家埃里.卡当(Elie...

Lie Algebra：代数

李的主要贡献在以他的名字命名的李群(Lie Group)和李代数(Lie Algebra)方面. 1870年 他从求解微分方程入手 依靠微分几何方法和射影几何方法建立起一种变换 将空间直缐簇和球面一一对应. 不久他发现 这种对应是连续的 能将微分方程的解表示出来并加以分类.

algebraically independent：代数无关[的]

代数微分方程|algebraic differential equation | 代数无关[的]|algebraically independent | 代数系统|algebraic system

Interpolative algebraic reconstruction：插值代数重建算法

非线性代数方程组:nonlinear algebraic equations | 插值代数重建算法:Interpolative algebraic reconstruction | 微分代数混杂系统:Differential-Algebraic Hybrid System