本文提出了微分代数系统无源的定义以及kvp特性的定义。
In this paper, Passive definition of differential algebraic systems and KVP property definition were proposed.
描述许多轨道控制问题的方程通常构成非线性半显式的微分代数系统。
The equations which describe many trajectory control problems naturally form nonlinear semiexplicit differential algebraic systems.
将连接与阻尼分配?无源控制方法进行从常微分方程到微分代数方程的拓展,求解一类仿射非线性微分代数系统的调节问题。
The interconnection and damping assignment passivity-based control (IDA-PBC) methodology is extended to solve the regulation problem of affine nonlinear differential algebraic system.
利用类似微分几何理论的方法,通过引入微分代数系统的m导数,利用微分代数系统无源性定义以及kvp特性的等价定理。
Similar to methods of differential geometry theory, equivalent theorem between differential algebraic systems passivation and KVP property was used by introducing m derivative.
为了求解这两个微分差分方程,给出一个系统的代数算法。
In order to solve the two differential-difference equations, a systematic algebraic algorithm is given.
利用完全笛卡尔坐标描述多刚体系统,建立多刚体系统动力学微分-代数方程。
Based on the fully Cartesian coordinates, a differential/algebraic equation system of multibod.
对系统应用第一类拉格朗日方程,得到系统位形坐标的微分—代数方程组。
Apply Lagrange equation of the first kind to the system, and get a set of the differential - algebraic equations (DAEs) of its absolute coordinates.
标准奇异点是微分代数方程系统区别于常微分方程系统的一个标志性的拓扑结构,具有重要的理论研究意义。
The standard singular point is an important structure of the differential-algebraic equation systems(DAEs), by which DAEs are differentiated from the ordinary different equation systems (ODEs).
讨论了非线性微分-代数系统的并行迭代算法所涉及的理论和具体算例的实现。
This paper discusses the theoretical models and numerical experiments of parallel iteration methods for solving non-linear differential-algebraic systems.
为研究多体系统小位移或振动问题,从多体系统动力学方程出发,讨论微分-代数方程线性化计算机代数问题。
To study vibration systems or the multibody systems with small displacements efficiently, a computerized algebraic method for linearizing the equations of multibody system is discussed in this paper.
本文探讨非线性指标- 3微分-代数系统的波形松弛算法所涉及的理论模型和具体算例的求解。
This paper discusses theoretical models and numerical experiments of waveform relaxation methods for solving nonlinear differential-algebraic systems of index-3.
微分代数采用动态反馈控制实现一类非线性系统的控制,平滑性是微分代数的重要概念。
Differential algebraic strategy can be applied to address the dynamic feedback control problems effectively in the nonlinear systems, with Flatness an important concept in the differential algebra.
热力系统分析分别经历了代数运算、矩阵计算、矩阵微分等阶段。
It has been pointed out that the thermodynamic system analysis has gone through phases such as algebraic, matrix, and matrix differential calculations etc.
多体系统进行数值仿真时,很多选择了微分代数混合方程作为多体系统动力学数学模型。
The differential-algebraic equations are often chosen as the mathematical models of the dynamics of multibody systems in order to achieve the numerical emulation for the multibody systems.
时域仿真法利用系统非线性微分代数方程为数学模型,可以充分考虑系统的非线性性质。
Time Domain Simulation USES the dynamic and algebraic equations which are definitely non-linear. This method can take all the non-linear proprieties of the power system into consideration.
本文研究非线性时滞大系统的稳定性问题,通过微分不等式分析,建立起一些简洁、实用的稳定性代数充分准则。
In this paper, we study the stability of nonlinear large scale systems with time lag. Some simple stability criterion are obtained.
最后针对微分代数模型的励磁系统构造了存储函数,使得系统无源而保持内部稳定。
In the end the storage function was constructed for excitation system with differential algebraic model.
最后针对微分代数模型的励磁系统构造了存储函数,使得系统无源而保持内部稳定。
In the end the storage function was constructed for excitation system with differential algebraic model.
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