EG3001 - 统计代写答疑辅导

标签： EG3001

数学代写|有限元方法代写Finite Element Method代考|Fluid Mechanics

Posted on 2023年5月26日2023年5月26日 by statistics-lab

如果你也在怎样代写有限元方法finite differences method 这个学科遇到相关的难题，请随时右上角联系我们的24/7代写客服。有限元方法finite differences method在数值分析中，是一类通过用有限差分逼近导数解决微分方程的数值技术。空间域和时间间隔（如果适用）都被离散化，或被分成有限的步骤，通过解决包含有限差分和附近点的数值的代数方程来逼近这些离散点的解的数值。

有限元方法finite differences method有限差分法将可能是非线性的常微分方程（ODE）或偏微分方程（PDE）转换成可以用矩阵代数技术解决的线性方程系统。现代计算机可以有效地进行这些线性代数计算，再加上其相对容易实现，使得FDM在现代数值分析中得到了广泛的应用。今天，FDM与有限元方法一样，是数值解决PDE的最常用方法之一。

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数学代写|有限元方法代写Finite Element Method代考|Fluid Mechanics

The equations governing flows of viscous incompressible fluids under isothermal conditions are listed here (listing the conservation principles that give rise to the equations). Further, all nonlinear terms are omitted. In addition to the vector form, only the Cartesian component form is listed, and the summation convention of Section 2.2.1.2 is adopted.
Conservation of mass (Continuity equation)
$$
\operatorname{div}(\rho \mathbf{v})=0, \quad \rho \frac{\partial v_i}{\partial x_i}=0
$$
Conservation of linear momentum (equations of motion): $\left(\sigma_{i j}=\sigma_{j i}\right)$
$$
\boldsymbol{\nabla} \cdot \boldsymbol{\sigma}+\mathbf{f}=\rho \frac{\partial \mathbf{v}}{\partial t}, \quad \frac{\partial \sigma_{j i}}{\partial x_j}+f_i=\rho \frac{\partial v_i}{\partial t}
$$
Constitutive relations
$$
\sigma=2 \mu \mathbf{D}-P \mathbf{I}, \quad \sigma_{i j}=2 \mu D_{i j}-P \delta_{i j}
$$
Kinematic relations
$$
\mathbf{D}=\frac{1}{2}\left[\boldsymbol{\nabla} \mathbf{v}+(\boldsymbol{\nabla} \mathbf{v})^{\mathrm{T}}\right], \quad D_{i j}=\frac{1}{2}\left(\frac{\partial v_i}{\partial x_j}+\frac{\partial v_j}{\partial x_i}\right)
$$
Here $\mathbf{v}$ is the velocity vector, $\sigma$ is the Cauchy stress tensor, $\mathbf{D}$ is the symmetric part of the velocity gradient tensor, $P$ is the hydrostatic pressure, $\mathbf{f}$ is the body force vector, $\rho$ is the density, and $\mu$ is the viscosity of the fluid. The boundary conditions involve specifying a velocity component $v_i$ or stress vector component $t_i \equiv n_j \sigma_{j i}$ at a boundary point, where $n j$ denote the direction cosines of a unit normal vector on the boundary
$$
\mathbf{v}=\hat{\mathbf{v}} \text { or } \hat{\mathbf{n}} \cdot \sigma=\hat{\mathbf{t}} ; \quad v_i=\hat{v}i \text { or } n_j \sigma{j i}=\hat{t}_i
$$

数学代写|有限元方法代写Finite Element Method代考|Solid Mechanics

Here we summarize the governing equations of a linearized, isotropic, elastic solid.
Momentum equations $\left(\sigma_{j i}=\sigma_{i j}\right)$
$$
\boldsymbol{\nabla} \cdot \boldsymbol{\sigma}+\mathbf{f}=\rho \frac{d \mathbf{v}}{d t}, \quad \frac{\partial \sigma_{j i}}{\partial x_j}+f_i=\rho \frac{d \mathbf{v}}{d t}
$$
Constitutive relations
$$
\sigma=2 \mu \varepsilon+\lambda(\operatorname{tr} \varepsilon) \mathrm{I}, \quad \sigma_{i j}=2 \mu \varepsilon_{i j}+\lambda \varepsilon_{k k} \delta_{i j}
$$
Kinematic relations
$$
\varepsilon=\frac{1}{2}\left[\nabla \mathbf{u}+(\nabla \mathbf{u})^{\mathrm{T}}\right], \quad \varepsilon_{i j}=\frac{1}{2}\left(\frac{\partial u_i}{\partial x_j}+\frac{\partial u_j}{\partial x_i}\right)
$$
Here $\mathbf{u}$ is the displacement vector, $\sigma$ is the Cauchy stress tensor, $\varepsilon$ is the symmetric part of the displacement gradient tensor, $\mathbf{f}$ is the body force vector, $\rho$ is the density, and $\mu$ and $\lambda$ are the Lamé (material) parameters. The boundary conditions involve specifying a displacement component $u_i$ or stress vector component $t_i \equiv n_j \sigma_{j i}$ at a boundary point
$$
\mathbf{u}=\hat{\mathbf{u}} \text { or } \hat{\mathbf{n}} \cdot \sigma=\hat{\mathbf{t}} ; \quad u_i=\hat{u}i \text { or } n_j \sigma{j i}=\hat{t}_i
$$

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|Fluid Mechanics

这里列出了在等温条件下控制粘性不可压缩流体流动的方程(列出了产生这些方程的守恒原理)。此外，所有非线性项都被省略。除矢量形式外，只列出笛卡尔分量形式，采用2.2.1.2节的求和约定。
质量守恒(连续性方程)
$$
\operatorname{div}(\rho \mathbf{v})=0, \quad \rho \frac{\partial v_i}{\partial x_i}=0
$$
线性动量守恒(运动方程):$\left(\sigma_{i j}=\sigma_{j i}\right)$
$$
\boldsymbol{\nabla} \cdot \boldsymbol{\sigma}+\mathbf{f}=\rho \frac{\partial \mathbf{v}}{\partial t}, \quad \frac{\partial \sigma_{j i}}{\partial x_j}+f_i=\rho \frac{\partial v_i}{\partial t}
$$
本构关系
$$
\sigma=2 \mu \mathbf{D}-P \mathbf{I}, \quad \sigma_{i j}=2 \mu D_{i j}-P \delta_{i j}
$$
运动学关系
$$
\mathbf{D}=\frac{1}{2}\left[\boldsymbol{\nabla} \mathbf{v}+(\boldsymbol{\nabla} \mathbf{v})^{\mathrm{T}}\right], \quad D_{i j}=\frac{1}{2}\left(\frac{\partial v_i}{\partial x_j}+\frac{\partial v_j}{\partial x_i}\right)
$$
这里$\mathbf{v}$是速度矢量，$\sigma$是柯西应力张量，$\mathbf{D}$是速度梯度张量的对称部分，$P$是静水压力，$\mathbf{f}$是体力矢量，$\rho$是密度，$\mu$是流体的粘度。边界条件包括在边界点指定速度分量$v_i$或应力矢量分量$t_i \equiv n_j \sigma_{j i}$，其中$n j$表示边界上单位法向量的方向余弦
$$
\mathbf{v}=\hat{\mathbf{v}} \text { or } \hat{\mathbf{n}} \cdot \sigma=\hat{\mathbf{t}} ; \quad v_i=\hat{v}i \text { or } n_j \sigma{j i}=\hat{t}_i
$$

数学代写|有限元方法代写Finite Element Method代考|Solid Mechanics

本文总结了线性化、各向同性、弹性固体的控制方程。
动量方程$\left(\sigma_{j i}=\sigma_{i j}\right)$
$$
\boldsymbol{\nabla} \cdot \boldsymbol{\sigma}+\mathbf{f}=\rho \frac{d \mathbf{v}}{d t}, \quad \frac{\partial \sigma_{j i}}{\partial x_j}+f_i=\rho \frac{d \mathbf{v}}{d t}
$$
本构关系
$$
\sigma=2 \mu \varepsilon+\lambda(\operatorname{tr} \varepsilon) \mathrm{I}, \quad \sigma_{i j}=2 \mu \varepsilon_{i j}+\lambda \varepsilon_{k k} \delta_{i j}
$$
运动学关系
$$
\varepsilon=\frac{1}{2}\left[\nabla \mathbf{u}+(\nabla \mathbf{u})^{\mathrm{T}}\right], \quad \varepsilon_{i j}=\frac{1}{2}\left(\frac{\partial u_i}{\partial x_j}+\frac{\partial u_j}{\partial x_i}\right)
$$
其中$\mathbf{u}$为位移矢量，$\sigma$为柯西应力张量，$\varepsilon$为位移梯度张量的对称部分，$\mathbf{f}$为体力矢量，$\rho$为密度，$\mu$和$\lambda$为lam(材料)参数。边界条件包括在边界点指定位移分量$u_i$或应力矢量分量$t_i \equiv n_j \sigma_{j i}$
$$
\mathbf{u}=\hat{\mathbf{u}} \text { or } \hat{\mathbf{n}} \cdot \sigma=\hat{\mathbf{t}} ; \quad u_i=\hat{u}i \text { or } n_j \sigma{j i}=\hat{t}_i
$$

数学代写|有限元方法代写Finite Element Method代考请认准statistics-lab™

统计代写请认准statistics-lab™. statistics-lab™为您的留学生涯保驾护航。

金融工程代写

金融工程是使用数学技术来解决金融问题。金融工程使用计算机科学、统计学、经济学和应用数学领域的工具和知识来解决当前的金融问题，以及设计新的和创新的金融产品。

非参数统计代写

非参数统计指的是一种统计方法，其中不假设数据来自于由少数参数决定的规定模型；这种模型的例子包括正态分布模型和线性回归模型。

广义线性模型代考

广义线性模型（GLM）归属统计学领域，是一种应用灵活的线性回归模型。该模型允许因变量的偏差分布有除了正态分布之外的其它分布。

术语广义线性模型（GLM）通常是指给定连续和/或分类预测因素的连续响应变量的常规线性回归模型。它包括多元线性回归，以及方差分析和方差分析（仅含固定效应）。

有限元方法代写

有限元方法（FEM）是一种流行的方法，用于数值解决工程和数学建模中出现的微分方程。典型的问题领域包括结构分析、传热、流体流动、质量运输和电磁势等传统领域。

有限元是一种通用的数值方法，用于解决两个或三个空间变量的偏微分方程（即一些边界值问题）。为了解决一个问题，有限元将一个大系统细分为更小、更简单的部分，称为有限元。这是通过在空间维度上的特定空间离散化来实现的，它是通过构建对象的网格来实现的：用于求解的数值域，它有有限数量的点。边界值问题的有限元方法表述最终导致一个代数方程组。该方法在域上对未知函数进行逼近。[1] 然后将模拟这些有限元的简单方程组合成一个更大的方程系统，以模拟整个问题。然后，有限元通过变化微积分使相关的误差函数最小化来逼近一个解决方案。

tatistics-lab作为专业的留学生服务机构，多年来已为美国、英国、加拿大、澳洲等留学热门地的学生提供专业的学术服务，包括但不限于Essay代写，Assignment代写，Dissertation代写，Report代写，小组作业代写，Proposal代写，Paper代写，Presentation代写，计算机作业代写，论文修改和润色，网课代做，exam代考等等。写作范围涵盖高中，本科，研究生等海外留学全阶段，辐射金融，经济学，会计学，审计学，管理学等全球99%专业科目。写作团队既有专业英语母语作者，也有海外名校硕博留学生，每位写作老师都拥有过硬的语言能力，专业的学科背景和学术写作经验。我们承诺100%原创，100%专业，100%准时，100%满意。

随机分析代写

随机微积分是数学的一个分支，对随机过程进行操作。它允许为随机过程的积分定义一个关于随机过程的一致的积分理论。这个领域是由日本数学家伊藤清在第二次世界大战期间创建并开始的。

时间序列分析代写

随机过程，是依赖于参数的一组随机变量的全体，参数通常是时间。随机变量是随机现象的数量表现，其时间序列是一组按照时间发生先后顺序进行排列的数据点序列。通常一组时间序列的时间间隔为一恒定值（如1秒，5分钟，12小时，7天，1年），因此时间序列可以作为离散时间数据进行分析处理。研究时间序列数据的意义在于现实中，往往需要研究某个事物其随时间发展变化的规律。这就需要通过研究该事物过去发展的历史记录，以得到其自身发展的规律。

回归分析代写

多元回归分析渐进（Multiple Regression Analysis Asymptotics）属于计量经济学领域，主要是一种数学上的统计分析方法，可以分析复杂情况下各影响因素的数学关系，在自然科学、社会和经济学等多个领域内应用广泛。

MATLAB代写

MATLAB 是一种用于技术计算的高性能语言。它将计算、可视化和编程集成在一个易于使用的环境中，其中问题和解决方案以熟悉的数学符号表示。典型用途包括：数学和计算算法开发建模、仿真和原型制作数据分析、探索和可视化科学和工程图形应用程序开发，包括图形用户界面构建MATLAB 是一个交互式系统，其基本数据元素是一个不需要维度的数组。这使您可以解决许多技术计算问题，尤其是那些具有矩阵和向量公式的问题，而只需用 C 或 Fortran 等标量非交互式语言编写程序所需的时间的一小部分。MATLAB 名称代表矩阵实验室。MATLAB 最初的编写目的是提供对由 LINPACK 和 EISPACK 项目开发的矩阵软件的轻松访问，这两个项目共同代表了矩阵计算软件的最新技术。MATLAB 经过多年的发展，得到了许多用户的投入。在大学环境中，它是数学、工程和科学入门和高级课程的标准教学工具。在工业领域，MATLAB 是高效研究、开发和分析的首选工具。MATLAB 具有一系列称为工具箱的特定于应用程序的解决方案。对于大多数 MATLAB 用户来说非常重要，工具箱允许您学习和应用专业技术。工具箱是 MATLAB 函数（M 文件）的综合集合，可扩展 MATLAB 环境以解决特定类别的问题。可用工具箱的领域包括信号处理、控制系统、神经网络、模糊逻辑、小波、仿真等。

R语言代写	问卷设计与分析代写
PYTHON代写	回归分析与线性模型代写
MATLAB代写	方差分析与试验设计代写
STATA代写	机器学习/统计学习代写
SPSS代写	计量经济学代写
EVIEWS代写	时间序列分析代写
EXCEL代写	深度学习代写
SQL代写	各种数据建模与可视化代写

数学代写|有限元方法代写Finite Element Method代考|Approximation functions

Posted on 2023年5月26日2023年5月26日 by statistics-lab

数学代写|有限元方法代写Finite Element Method代考|Approximation functions

In this section we discuss the properties of the set of approximation functions $\left{\phi_i\right}$ and $\phi_0$ used in the n-parameter Ritz solution in Eq. (2.5.4). First, we note that $u_n$ must satisfy only the specified essential boundary conditions of the problem, since the specified natural boundary conditions are included in the variational problem in Eq. (2.5.1). The particular form of $u_n$ in Eq. (2.5.4) facilitates satisfaction of specified boundary conditions. To see this, suppose that the approximate solution is sought in the form
$$
u_n=\sum_{j=1}^n c_j \phi_j(x)
$$
and suppose that the specified essential boundary condition is $u\left(x_0\right)=u_0$. Then $u_n$ must also satisfy the condition $u_n\left(x_0\right)=u_0$ at a boundary point $x=x_0$
$$
\sum_{j=1}^n c_j \phi_j\left(x_0\right)=u_0
$$
Since $c_j$ are unknown parameters to be determined, it is not easy to choose $\phi_j$ (x) such that the above relation holds for all $c_j$. If $u_0=0$, then we can select all $\phi_j$ such that $\phi_j\left(x_0\right)=0$ and satisfy the condition $u_n\left(x_0\right)=0$. By writing the approximate solution $u_n$ in the form Eq. (2.5.4), a sum of a homogeneous part $\sum c_j \phi_j(x)$ and a nonhomogeneous part $\phi_0(x)$, we require $\phi_0(x)$ to satisfy the specified essential boundary conditions while the homogeneous part vanishes at the same boundary point where the essential boundary condition is specified. This follows from
$$
\begin{gathered}
u_n\left(x_0\right)=\sum_{j=1}^n c_j \phi_j\left(x_0\right)+\phi_0\left(x_0\right) \
u_0=\sum_{j=1}^n c_j \phi_j\left(x_0\right)+u_0 \rightarrow \sum_{j=1}^n c_j \phi_j\left(x_0\right)=0
\end{gathered}
$$
which is satisfied, for arbitrary $c_j$, by choosing $\phi_j\left(x_0\right)=0$.

数学代写|有限元方法代写Finite Element Method代考|The Method of Weighted Residuals

As noted in Section 2.4.3, one can always write the weighted-integral form of a differential equation, whether the equation is linear or nonlinear (in the dependent variables). The weak form can be developed if the equations are second-order or higher, even if they are nonlinear.

The weighted-residual method is a generalization of the Galerkin method in that the weight functions can be chosen from an independent set of functions, and it requires only the weighted-integral form to determine the parameters. Since the latter form does not include any of the specified boundary conditions of the problem, the approximation functions must be selected such that the approximate solution satisfies all of the specified boundary conditions. In addition, the weight functions can be selected independently of the approximation functions, but are required to be linearly independent so that the resulting algebraic equations are linearly independent.
We discuss the general method of weighted residuals first, and then consider certain special cases that are known by specific names (e.g., the Galerkin method, the collocation method, the least-squares method and so on). Although a limited use of the weighted-residual method is made in this book, it is informative to have a knowledge of this class of methods for use in the formulation of certain nonlinear problems and non-self-adjoint problems.

The method of weighted residuals can be described in its generality by considering the operator equation
$$
A(u)=f \text { in } \Omega
$$
where $A$ is an operator (linear or nonlinear), often a differential operator, acting on the dependent variable $u$, and $f$ is a known function of the independent variables. Some examples of such operators are given below.
$$
A(u)=-\frac{d}{d x}\left(a \frac{d u}{d x}\right)+c u
$$
$$
A(u)=\frac{d^2}{d x^2}\left(b \frac{d^2 u}{d x^2}\right)
$$
$$
A(u)=-\left[\frac{\partial}{\partial x}\left(k_x \frac{\partial u}{\partial x}\right)+\frac{\partial}{\partial y}\left(k_y \frac{\partial u}{\partial y}\right)\right]
$$
$$
A(u)=-\frac{d}{d x}\left(u \frac{d u}{d x}\right)
$$
$$
A(u, v)=u \frac{\partial u}{\partial x}+v \frac{\partial u}{\partial y}+\frac{\partial^2 u}{\partial x^2}+\frac{\partial}{\partial y}\left(\frac{\partial u}{\partial y}+\frac{\partial v}{\partial x}\right)
$$
For an operator $A$ to be linear in its arguments, it must satisfy the relation
$$
A(\alpha u+\beta v)=\alpha A(u)+\beta A(v)
$$
for any scalars $\alpha$ and $\beta$ and dependent variables $u$ and $v$. It can be easily verified that all operators in Eq. (2.5.52), except for those in (4) and (5), are linear. When an operator does not satisfy the condition in Eq. (2.5.53), it is said to be nonlinear.

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|Approximation functions

在本节中，我们讨论在式(2.5.4)中的n参数Ritz解中使用的近似函数集$\left{\phi_i\right}$和$\phi_0$的性质。首先，我们注意到$u_n$必须只满足问题的指定基本边界条件，因为公式(2.5.1)中的变分问题中包含了指定的自然边界条件。式(2.5.4)中$u_n$的特殊形式便于满足规定的边界条件。为了说明这一点，假设近似解是这样求的
$$
u_n=\sum_{j=1}^n c_j \phi_j(x)
$$
并设指定的基本边界条件为$u\left(x_0\right)=u_0$。那么$u_n$也必须在边界点$x=x_0$处满足条件$u_n\left(x_0\right)=u_0$
$$
\sum_{j=1}^n c_j \phi_j\left(x_0\right)=u_0
$$
由于$c_j$是待确定的未知参数，因此不容易选择$\phi_j$ (x)，使上述关系适用于所有$c_j$。如果是$u_0=0$，那么我们可以选择所有的$\phi_j$，使$\phi_j\left(x_0\right)=0$满足条件$u_n\left(x_0\right)=0$。通过将近似解$u_n$写成Eq.(2.5.4)的形式，即齐次部分$\sum c_j \phi_j(x)$与非齐次部分$\phi_0(x)$的和，我们要求$\phi_0(x)$满足规定的必要边界条件，而齐次部分在规定必要边界条件的同一边界点上消失。这是从
$$
\begin{gathered}
u_n\left(x_0\right)=\sum_{j=1}^n c_j \phi_j\left(x_0\right)+\phi_0\left(x_0\right) \
u_0=\sum_{j=1}^n c_j \phi_j\left(x_0\right)+u_0 \rightarrow \sum_{j=1}^n c_j \phi_j\left(x_0\right)=0
\end{gathered}
$$
对于任意的$c_j$，通过选择$\phi_j\left(x_0\right)=0$来满足。

数学代写|有限元方法代写Finite Element Method代考|The Method of Weighted Residuals

如第2.4.3节所述，无论微分方程是线性的还是非线性的(在因变量中)，都可以写出微分方程的加权积分形式。如果方程是二阶或更高阶的，即使它们是非线性的，也可以得到弱形式。

加权残差法是Galerkin方法的推广，它可以从一个独立的函数集合中选择权函数，并且只需要加权积分形式来确定参数。由于后一种形式不包括问题的任何指定边界条件，因此必须选择近似函数，使近似解满足所有指定边界条件。此外，权函数的选择可以独立于近似函数，但要求是线性无关的，以便得到线性无关的代数方程。
我们首先讨论了加权残差的一般方法，然后考虑了某些已知的特殊情况(如Galerkin方法、搭配方法、最小二乘法等)。虽然在这本书中有限地使用了加权残差法，但在某些非线性问题和非自伴随问题的公式中使用这类方法的知识是有益的。

加权残差法的通用性可以通过考虑算子方程来描述
$$
A(u)=f \text { in } \Omega
$$
其中$A$是一个算子(线性或非线性)，通常是一个微分算子，作用于因变量$u$, $f$是自变量的已知函数。下面给出了这类运算符的一些例子。
$$
A(u)=-\frac{d}{d x}\left(a \frac{d u}{d x}\right)+c u
$$
$$
A(u)=\frac{d^2}{d x^2}\left(b \frac{d^2 u}{d x^2}\right)
$$
$$
A(u)=-\left[\frac{\partial}{\partial x}\left(k_x \frac{\partial u}{\partial x}\right)+\frac{\partial}{\partial y}\left(k_y \frac{\partial u}{\partial y}\right)\right]
$$
$$
A(u)=-\frac{d}{d x}\left(u \frac{d u}{d x}\right)
$$
$$
A(u, v)=u \frac{\partial u}{\partial x}+v \frac{\partial u}{\partial y}+\frac{\partial^2 u}{\partial x^2}+\frac{\partial}{\partial y}\left(\frac{\partial u}{\partial y}+\frac{\partial v}{\partial x}\right)
$$
对于一个操作符$A$，它的参数是线性的，它必须满足这个关系
$$
A(\alpha u+\beta v)=\alpha A(u)+\beta A(v)
$$
对于任意标量$\alpha$和$\beta$以及因变量$u$和$v$。可以很容易地验证，除式(4)和式(5)中的算子外，式(2.5.52)中的所有算子都是线性的。当一个算子不满足式(2.5.53)中的条件时，称为非线性算子。

统计代写请认准statistics-lab™. statistics-lab™为您的留学生涯保驾护航。

金融工程代写

非参数统计代写

非参数统计指的是一种统计方法，其中不假设数据来自于由少数参数决定的规定模型；这种模型的例子包括正态分布模型和线性回归模型。

广义线性模型代考

广义线性模型（GLM）归属统计学领域，是一种应用灵活的线性回归模型。该模型允许因变量的偏差分布有除了正态分布之外的其它分布。

有限元方法代写

随机分析代写

时间序列分析代写

回归分析代写

MATLAB代写

R语言代写	问卷设计与分析代写
PYTHON代写	回归分析与线性模型代写
MATLAB代写	方差分析与试验设计代写
STATA代写	机器学习/统计学习代写
SPSS代写	计量经济学代写
EVIEWS代写	时间序列分析代写
EXCEL代写	深度学习代写
SQL代写	各种数据建模与可视化代写

数学代写|有限元方法代写Finite Element Method代考|The Principle of Minimum Total Potential Energy

Posted on 2023年5月26日2023年5月26日 by statistics-lab

数学代写|有限元方法代写Finite Element Method代考|The Principle of Minimum Total Potential Energy

The principle of virtual work discussed in the previous section is applicable to any continuous body with arbitrary constitutive behavior (e.g., linear or nonlinear elastic materials). The principle of minimum total potential energy is obtained as a special case from the principle of virtual displacements when the constitutive relations can be obtained from a potential function. Here we restrict our discussion to materials that admit existence of a strain energy potential such that the stress is derivable from it. Such materials are termed hyperelastic.
For elastic bodies (in the absence of temperature variations), there exists a strain energy potential $U_0$ such that [see Eq. (2.3.5)]
$$
\sigma_{i j}=\frac{\partial U_0}{\partial \varepsilon_{i j}}
$$
The strain energy density $U_0$ is a function of strains at a point and is assumed to be positive definite. The statement of the principle of virtual displacements, $\delta W=0$, can be expressed in terms of the strain energy density $U_0$ as
$$
\begin{aligned}
0=\delta W & =\int_{\Omega} \sigma_{i j} \delta \varepsilon_{i j} d \Omega-\left[\int_{\Omega} \mathbf{f} \cdot \delta \mathbf{u} d \Omega+\int_{\Gamma_\sigma} \hat{\mathbf{t}} \cdot \delta \mathbf{u} d s\right] \
& =\int_{\Omega} \frac{\partial U_0}{\partial \varepsilon_{i j}} \delta \varepsilon_{i j} d \Omega+\delta V_E \
& =\int_{\Omega} \delta U_0 d \Omega+\delta V_E=\delta\left(U+V_E\right) \equiv \delta \Pi
\end{aligned}
$$
where
$$
V_E=-\left[\int_{\Omega} \mathbf{f} \cdot \mathbf{u} d \Omega+\int_{\Gamma_\sigma} \hat{\mathbf{t}} \cdot \mathbf{u} d s\right]
$$
is the potential energy due to external loads and $U$ is the strain energy potential
$$
U=\int_{\Omega} U_0 d \Omega
$$

数学代写|有限元方法代写Finite Element Method代考|Residual Function

Consider the problem of solving the differential equation
$$
-\frac{d}{d x}\left[a(x) \frac{d u}{d x}\right]+c u=f(x) \text { for } 0<x<L
$$
for $u(x)$, which is subject to the boundary conditions
$$
u(0)=u_0, \quad\left[a \frac{d u}{d x}+\beta\left(u-u_{\infty}\right)\right]{x=L}=Q_L $$ Here $a(x), c(x)$, and $f(x)$ are known functions of the coordinate $x ; u_0, u{\infty}, \beta$, and $Q_L$ are known values, and $L$ is the size of the one-dimensional domain. When the specified values are nonzero $\left(u_0 \neq 0\right.$ or $\left.Q_L \neq 0\right)$, the boundary conditions are said to be nonhomogeneous; when the specified values are zero the boundary conditions are said to be homogeneous. The homogeneous form of the boundary condition $u(0)=u_0$ is $u(0)=0$, and the homogeneous form of the boundary condition $\left[a(d u / d x)+\beta\left(u-u_{\infty}\right)\right]{x=L}=Q_L$ is $[a(d u / d x)+$ $\left.\beta\left(u-u{\infty}\right)\right]_{x=L}=0$.

Equations of the type in Eq. (2.4.1) arise, for example, in the study of 1-D heat flow in a rod with surface convection (see Example 1.2.2), as shown in Fig. 2.4.1(a). In this case, $a=k A$, with $k$ being the thermal conductivity and $A$ the cross-sectional area, $c=\beta P$, with $\beta$ being the heat transfer coefficient, $P$ the perimeter of the rod, and $L$ the length of the rod; $f$ denotes the heat generation term, $u_0$ is the specified temperature at $x=0, Q_L$ is the specified heat at $x=L$, and $u_{\infty}$ is the temperature of the surrounding medium. Another example where Eqs. (2.4.1) and (2.4.2) arise is provided by the axial deformation of a bar (see Example 1.2.3), as shown in Fig. 2.4.1(b). In this case, $a=E A$, with $E$ being the Young’s modulus and $A$ the cross-sectional area, $c$ is the spring constant associated with the shear resistance offered by the surrounding medium (as discussed in Example 1.2.3), and $L$ is the length of the bar; $f$ denotes the body force term, $u_0$ is the specified displacement at $x$ $=0\left(u_0=0\right), Q_L$ is the specified point load at $x=L$, and $u_{\infty}=0$. Other physical problems are also described by the same equation, but with different meaning of the variables.

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|The Principle of Minimum Total Potential Energy

上一节讨论的虚功原理适用于任何具有任意本构行为的连续体(如线性或非线性弹性材料)。当本构关系可以由势函数求得时，作为虚位移原理的特例，得到了最小总势能原理。在这里，我们把我们的讨论限制在承认存在应变能势的材料上，这样应力就可以由它推导出来。这种材料被称为超弹性材料。
对于弹性体(在没有温度变化的情况下)，存在一个应变能势$U_0$，使得[见式(2.3.5)]
$$
\sigma_{i j}=\frac{\partial U_0}{\partial \varepsilon_{i j}}
$$
应变能密度$U_0$是某一点应变的函数，假设为正定。虚位移原理$\delta W=0$的表述可以用应变能密度$U_0$ as来表示
$$
\begin{aligned}
0=\delta W & =\int_{\Omega} \sigma_{i j} \delta \varepsilon_{i j} d \Omega-\left[\int_{\Omega} \mathbf{f} \cdot \delta \mathbf{u} d \Omega+\int_{\Gamma_\sigma} \hat{\mathbf{t}} \cdot \delta \mathbf{u} d s\right] \
& =\int_{\Omega} \frac{\partial U_0}{\partial \varepsilon_{i j}} \delta \varepsilon_{i j} d \Omega+\delta V_E \
& =\int_{\Omega} \delta U_0 d \Omega+\delta V_E=\delta\left(U+V_E\right) \equiv \delta \Pi
\end{aligned}
$$
在哪里
$$
V_E=-\left[\int_{\Omega} \mathbf{f} \cdot \mathbf{u} d \Omega+\int_{\Gamma_\sigma} \hat{\mathbf{t}} \cdot \mathbf{u} d s\right]
$$
外部载荷的势能和$U$是应变能势能吗
$$
U=\int_{\Omega} U_0 d \Omega
$$

数学代写|有限元方法代写Finite Element Method代考|Residual Function

考虑解微分方程的问题
$$
-\frac{d}{d x}\left[a(x) \frac{d u}{d x}\right]+c u=f(x) \text { for } 0<x<L
$$
对于$u(x)$，它受边界条件的约束
$$
u(0)=u_0, \quad\left[a \frac{d u}{d x}+\beta\left(u-u_{\infty}\right)\right]{x=L}=Q_L $$其中$a(x), c(x)$、$f(x)$为坐标$x ; u_0, u{\infty}, \beta$的已知函数，$Q_L$为已知值，$L$为一维域的大小。当指定值为非零$\left(u_0 \neq 0\right.$或$\left.Q_L \neq 0\right)$时，边界条件是非齐次的;当指定值为零时，边界条件称为齐次。边界条件$u(0)=u_0$的齐次形式为$u(0)=0$，边界条件$\left[a(d u / d x)+\beta\left(u-u_{\infty}\right)\right]{x=L}=Q_L$的齐次形式为$[a(d u / d x)+$$\left.\beta\left(u-u{\infty}\right)\right]_{x=L}=0$。

例如，在研究具有表面对流的杆内一维热流(见例1.2.2)时，会出现式(2.4.1)式的方程，如图2.4.1(a)所示。在这种情况下，$a=k A$, $k$为导热系数，$A$为截面积，$c=\beta P$, $\beta$为传热系数，$P$为棒的周长，$L$为棒的长度;$f$为发热量项，$u_0$为$x=L$处的规定温度，$x=0, Q_L$为处的规定热量，$u_{\infty}$为周围介质温度。另一个例子是等式。(2.4.1)和(2.4.2)的产生是由杆的轴向变形提供的(见例1.2.3)，如图2.4.1(b)所示。在这种情况下，$a=E A$, $E$是杨氏模量，$A$是截面积，$c$是与周围介质提供的剪切阻力相关的弹簧常数(如例1.2.3所述)，$L$是杆的长度;$f$为体力项，$u_0$为$x$处的规定位移，$=0\left(u_0=0\right), Q_L$为$x=L$处的规定点荷载，$u_{\infty}=0$。其他物理问题也可以用相同的方程来描述，但变量的含义不同。

统计代写请认准statistics-lab™. statistics-lab™为您的留学生涯保驾护航。

金融工程代写

非参数统计代写

非参数统计指的是一种统计方法，其中不假设数据来自于由少数参数决定的规定模型；这种模型的例子包括正态分布模型和线性回归模型。

广义线性模型代考

广义线性模型（GLM）归属统计学领域，是一种应用灵活的线性回归模型。该模型允许因变量的偏差分布有除了正态分布之外的其它分布。

有限元方法代写

随机分析代写

时间序列分析代写

回归分析代写

MATLAB代写

R语言代写	问卷设计与分析代写
PYTHON代写	回归分析与线性模型代写
MATLAB代写	方差分析与试验设计代写
STATA代写	机器学习/统计学习代写
SPSS代写	计量经济学代写
EVIEWS代写	时间序列分析代写
EXCEL代写	深度学习代写
SQL代写	各种数据建模与可视化代写

数学代写|有限元方法代写Finite Element Method代考|Matrix addition and multiplication of a matrix by a scalar

Posted on 2023年5月11日2023年5月11日 by statistics-lab

数学代写|有限元方法代写Finite Element Method代考|Matrix addition and multiplication of a matrix by a scalar

The sum of two matrices of the same size is defined to be a matrix of the same size obtained by simply adding the corresponding elements. If $\mathbf{A}$ is an $m \times n$ matrix and $\mathbf{B}$ is an $m \times n$ matrix, their sum is an $m \times n$ matrix, $\mathbf{C}$, with
$$
c_{i j}=a_{i j}+b_{i j} \text { for all } i, j
$$
A constant multiple of a matrix is equal to the matrix obtained by multiplying all of the elements by the constant. That is, the multiple of a matrix $\mathbf{A}$ by a scalar $\alpha, \alpha \mathbf{A}$, is the matrix obtained by multiplying each of its elements with $\alpha$ :
$$
\mathbf{A}=\left[\begin{array}{cccc}
a_{11} & a_{12} & \ldots & a_{1 n} \
a_{21} & a_{22} & \ldots & a_{2 n} \
\vdots & \vdots & \ldots & \vdots \
a_{m 1} & a_{m 2} & \ldots & a_{m n}
\end{array}\right], \quad \alpha \mathbf{A}=\left[\begin{array}{cccc}
\alpha a_{11} & \alpha a_{12} & \ldots & \alpha a_{1 n} \
\alpha a_{21} & \alpha a_{22} & \ldots & \alpha a_{2 n} \
\vdots & \vdots & & \vdots \
\alpha a_{m 1} & \alpha a_{m 2} & \ldots & \alpha a_{m n}
\end{array}\right]
$$
Matrix addition has the following properties:

Addition is commutative: $\mathbf{A}+\mathbf{B}=\mathbf{B}+\mathbf{A}$.
Addition is associative: $\mathbf{A}+(\mathbf{B}+\mathbf{C})=(\mathbf{A}+\mathbf{B})+\mathbf{C}$.
There exists a unique matrix $\mathbf{0}$, such that $\mathbf{A}+\mathbf{0}=\mathbf{0}+\mathbf{A}=\mathbf{A}$. The matrix $\mathbf{0}$ is called zero matrix; all elements of it are zeros.
For each matrix $\mathbf{A}$, there exists a unique matrix $-\mathbf{A}$ such that $\mathbf{A}+(-\mathbf{A})$ $=\mathbf{0}$.
Addition is distributive with respect to scalar multiplication: $\alpha(\mathbf{A}+\mathbf{B})$ $=\alpha \mathbf{A}+\alpha \mathbf{B}$.

数学代写|有限元方法代写Finite Element Method代考|Matrix transpose and symmetric and skew symmetric matrices

If $\mathbf{A}$ is an $m \times n$ matrix, then the $n \times m$ matrix obtained by interchanging its rows and columns is called the transpose of $\mathbf{A}$ and is denoted by $\mathbf{A}^{\mathrm{T}}$. An example of a transpose is provided by
$$
\mathbf{A}=\left[\begin{array}{rrr}
2 & -3 & 4 \
5 & 6 & 8 \
1 & 5 & 3 \
-2 & 9 & 0
\end{array}\right], \quad \mathbf{A}^{\mathrm{T}}=\left[\begin{array}{rrrr}
2 & 5 & 1 & -2 \
-3 & 6 & 5 & 9 \
4 & 8 & 3 & 0
\end{array}\right]
$$
The following basic properties of a transpose should be noted:

$\left(\mathbf{A}^{\mathrm{T}}\right)^{\mathrm{T}}=\mathbf{A}$

$(\mathbf{A}+\mathbf{B})^{\mathrm{T}}=\mathbf{A}^{\mathrm{T}}+\mathbf{B}^{\mathrm{T}}$
A square matrix $\mathbf{A}$ of real numbers is said to be symmetric if $\mathbf{A}^{\mathrm{T}}=\mathbf{A}$. It is said to be skew symmetric or antisymmetric if $\mathbf{A}^{\mathrm{T}}=-\mathbf{A}$. In terms of the elements of $\mathbf{A}$, these definitions imply that $\mathbf{A}$ is symmetric if and only if $a_{i j}=$ $a_{j i}$, and it is skew symmetric if and only if $a_{i j}=-a_{j i}$. Note that the diagonal elements of a skew symmetric matrix are always zero since $a_{i j}=-a_{i j}$ implies $a_{i j}=0$ for $i=j$. Examples of symmetric and skew symmetric matrices, respectively, are
$$
\left[\begin{array}{rrrr}
5 & -2 & 11 & 9 \
-2 & 4 & 14 & -3 \
11 & 14 & 13 & 8 \
9 & -3 & 8 & 21
\end{array}\right], \quad\left[\begin{array}{rrrr}
0 & -10 & 23 & 3 \
10 & 0 & 21 & 7 \
-23 & -21 & 0 & 12 \
-3 & -7 & -12 & 0
\end{array}\right]
$$

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|Matrix addition and multiplication of a matrix by a scalar

两个大小相同的矩阵的和定义为简单地将相应的元素相加得到的大小相同的矩阵。如果$\mathbf{A}$是一个$m \times n$矩阵，$\mathbf{B}$是一个$m \times n$矩阵，那么它们的和就是一个$m \times n$矩阵$\mathbf{C}$
$$
c_{i j}=a_{i j}+b_{i j} \text { for all } i, j
$$
一个常数乘以一个矩阵等于由所有元素乘以这个常数得到的矩阵。即矩阵$\mathbf{A}$与标量$\alpha, \alpha \mathbf{A}$的乘积，是矩阵的每个元素与$\alpha$相乘得到的矩阵:
$$
\mathbf{A}=\left[\begin{array}{cccc}
a_{11} & a_{12} & \ldots & a_{1 n} \
a_{21} & a_{22} & \ldots & a_{2 n} \
\vdots & \vdots & \ldots & \vdots \
a_{m 1} & a_{m 2} & \ldots & a_{m n}
\end{array}\right], \quad \alpha \mathbf{A}=\left[\begin{array}{cccc}
\alpha a_{11} & \alpha a_{12} & \ldots & \alpha a_{1 n} \
\alpha a_{21} & \alpha a_{22} & \ldots & \alpha a_{2 n} \
\vdots & \vdots & & \vdots \
\alpha a_{m 1} & \alpha a_{m 2} & \ldots & \alpha a_{m n}
\end{array}\right]
$$
矩阵加法具有以下性质:

加法是交换的:$\mathbf{A}+\mathbf{B}=\mathbf{B}+\mathbf{A}$。

加法是结合法:$\mathbf{A}+(\mathbf{B}+\mathbf{C})=(\mathbf{A}+\mathbf{B})+\mathbf{C}$。

存在一个唯一矩阵$\mathbf{0}$，使得$\mathbf{A}+\mathbf{0}=\mathbf{0}+\mathbf{A}=\mathbf{A}$。矩阵$\mathbf{0}$称为零矩阵;它的所有元素都是0。

对于每个矩阵$\mathbf{A}$，存在一个唯一的矩阵$-\mathbf{A}$，使得$\mathbf{A}+(-\mathbf{A})$$=\mathbf{0}$。

加法是关于标量乘法的分配式:$\alpha(\mathbf{A}+\mathbf{B})$$=\alpha \mathbf{A}+\alpha \mathbf{B}$。

数学代写|有限元方法代写Finite Element Method代考|Matrix transpose and symmetric and skew symmetric matrices

如果$\mathbf{A}$是一个$m \times n$矩阵，那么通过交换其行和列得到的$n \times m$矩阵称为$\mathbf{A}$的转置，用$\mathbf{A}^{\mathrm{T}}$表示。转置的一个例子是
$$
\mathbf{A}=\left[\begin{array}{rrr}
2 & -3 & 4 \
5 & 6 & 8 \
1 & 5 & 3 \
-2 & 9 & 0
\end{array}\right], \quad \mathbf{A}^{\mathrm{T}}=\left[\begin{array}{rrrr}
2 & 5 & 1 & -2 \
-3 & 6 & 5 & 9 \
4 & 8 & 3 & 0
\end{array}\right]
$$
转置的下列基本性质应注意:

$\left(\mathbf{A}^{\mathrm{T}}\right)^{\mathrm{T}}=\mathbf{A}$

$(\mathbf{A}+\mathbf{B})^{\mathrm{T}}=\mathbf{A}^{\mathrm{T}}+\mathbf{B}^{\mathrm{T}}$
实数的方阵$\mathbf{A}$如果$\mathbf{A}^{\mathrm{T}}=\mathbf{A}$是对称的。如果$\mathbf{A}^{\mathrm{T}}=-\mathbf{A}$，则称其为偏对称或反对称。就$\mathbf{A}$的元素而言，这些定义意味着$\mathbf{A}$当且仅当$a_{i j}=$$a_{j i}$是对称的，当且仅当$a_{i j}=-a_{j i}$是不对称的。注意，斜对称矩阵的对角线元素总是零，因为$a_{i j}=-a_{i j}$对于$i=j$意味着$a_{i j}=0$。对称矩阵和斜对称矩阵的例子分别是
$$
\left[\begin{array}{rrrr}
5 & -2 & 11 & 9 \
-2 & 4 & 14 & -3 \
11 & 14 & 13 & 8 \
9 & -3 & 8 & 21
\end{array}\right], \quad\left[\begin{array}{rrrr}
0 & -10 & 23 & 3 \
10 & 0 & 21 & 7 \
-23 & -21 & 0 & 12 \
-3 & -7 & -12 & 0
\end{array}\right]
$$

统计代写请认准statistics-lab™. statistics-lab™为您的留学生涯保驾护航。

金融工程代写

非参数统计代写

非参数统计指的是一种统计方法，其中不假设数据来自于由少数参数决定的规定模型；这种模型的例子包括正态分布模型和线性回归模型。

广义线性模型代考

广义线性模型（GLM）归属统计学领域，是一种应用灵活的线性回归模型。该模型允许因变量的偏差分布有除了正态分布之外的其它分布。

有限元方法代写

随机分析代写

时间序列分析代写

回归分析代写

MATLAB代写

R语言代写	问卷设计与分析代写
PYTHON代写	回归分析与线性模型代写
MATLAB代写	方差分析与试验设计代写
STATA代写	机器学习/统计学习代写
SPSS代写	计量经济学代写
EVIEWS代写	时间序列分析代写
EXCEL代写	深度学习代写
SQL代写	各种数据建模与可视化代写

数学代写|有限元方法代写Finite Element Method代考|Boundary Value, Initial Value, and Eigenvalue Problems

Posted on 2023年5月11日2023年5月11日 by statistics-lab

数学代写|有限元方法代写Finite Element Method代考|Boundary Value, Initial Value, and Eigenvalue Problems

The objective of most analysis is to determine unknown functions, called dependent variables, that are governed by a set of differential equations posed in a given domain $\Omega$ and some conditions on the boundary $\Gamma$ of the
domain $\Omega$. Often, a domain not including its boundary is called an open domain. A domain $\Omega$ with its boundary $\Gamma$ is called a closed domain and is denoted by $\bar{\Omega}=\Omega \cup \Gamma$.
A function $u$ of several independent variables (or coordinates) $(x, y, \cdots)$ is said to be of class $C^m(\Omega)$ in a domain $\Omega$ if all its partial derivatives with respect to $(x, y, \cdots)$ of order up to and including $m$ exist and are continuous in $\Omega$. Thus, if $u$ is of class $C^0$ in a two-dimensional domain $\Omega$ then $u$ is continuous in $\Omega$ (i.e., $\partial u / \partial x$ and $\partial u / \partial y$ exist but may not be continuous). Similarly, if $u$ is of class $c_1$, then $u, \partial u / \partial x$ and $\partial u / \partial y$ exist and are continuous (i.e., $\partial^2 u / \partial x^2, \partial^2 u / \partial y^2$, and $\partial^2 u / \partial y \partial x$ exist but may not be continuous).

Similarly, if $u$ is of class $c_1$, then $u, \partial u / \partial x$ and $\partial u / \partial y$ exist and are continuous (i.e., $\partial^2 u / \partial x^2, \partial^2 u / \partial y^2$, and $\partial^2 u / \partial y \partial x$ exist but may not be continuous).

When the dependent variables are functions of one independent variable (say, $x$ ), the domain is a line segment (i.e., one-dimensional) and the end points of the domain are called boundary points. When the dependent variables are functions of two independent variables (say, $x$ and $y$ ), the domain is two-dimensional and the boundary is the closed curve enclosing it. In a threedimensional domain, dependent variables are functions of three independent variables (say $x, y$, and $z$ ) and the boundary is a two-dimensional surface.

数学代写|有限元方法代写Finite Element Method代考|Boundary value problems

Steady-state heat transfer in a fin and axial deformation of a bar: Find $u(x)$ that satisfies the second-order differential equation and boundary conditions:
$$
\begin{gathered}
-\frac{d}{d x}\left(a \frac{d u}{d x}\right)+c u=f \text { for } 0<x<L \
u(0)=u_0, \quad\left(a \frac{d u}{d x}\right)_{x=L}=q_0
\end{gathered}
$$
The domain and boundary points are identified in Fig. 2.2.3.

Bending of elastic beams under transverse load: Find $w(x)$ that satisfies the fourthorder differential equation and boundary conditions:
$$
\begin{gathered}
\frac{d^2}{d x^2}\left(E I \frac{d^2 w}{d x^2}\right)+c w=f \quad \text { for } \quad 0<x<L \
w(0)=w_0, \quad\left(-\frac{d w}{d x}\right){x=0}=\theta_0 \ {\left[\frac{d}{d x}\left(E I \frac{d^2 w}{d x^2}\right)\right]{x=L}=V_0, \quad\left(E I \frac{d^2 w}{d x^2}\right)_{x=L}=M_0}
\end{gathered}
$$
The domain and boundary points for this case are the same as shown in Fig. 2.2.3. However, the physics behind the equations is different, as we shall see shortly.

Steady heat conduction in a two-dimensional region and transverse deflections of a membrane: Find $u(x, y)$ that satisfies the second-order partial differential equation and boundary conditions:
$$
\begin{aligned}
& -\left[\frac{\partial}{\partial x}\left(a_{x x} \frac{\partial u}{\partial x}\right)+\frac{\partial}{\partial y}\left(a_{y y} \frac{\partial u}{\partial y}\right)\right]+a_{00} u=f \quad \text { in } \Omega \
& u=u_0 \text { on } \Gamma_u, \quad\left(a_{x x} \frac{\partial u}{\partial x} n_x+a_{y y} \frac{\partial u}{\partial y} n_y\right)=q_0 \text { on } \Gamma_q
\end{aligned}
$$
where $\left(n_x, n_y\right)$ are the direction cosines on the unit normal vector $\hat{\mathbf{n}}$ to the boundary $\Gamma_q$. The domain $\Omega$ and two parts of the boundary $\Gamma_u$ and $\Gamma_q$ are shown in Fig. 2.2.4.

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|Variational Principles and Methods

这一章是专门回顾数学的初步证明是有用的后续和研究积分公式和更常用的变分方法，如里兹，伽辽金，搭配，子域，和最小二乘法。由于有限元方法可以看作是变分方法在单元上的应用，因此了解变分方法是如何工作的是有用的。我们首先讨论文献中使用的短语“变分方法”和“变分公式”的一般含义。
“直接变分方法”是指利用变分原理，如固体力学和结构力学中的虚功原理和最小总势能原理，来确定问题的近似解的方法(参见Oden和Reddy[1]和Reddy[2])。在经典意义上，变分原理与寻找极值(即，最小值或最大值)或关于问题变量的函数的平稳值有关。泛函包括问题的所有内在特征，如控制方程、边界和/或初始条件以及约束条件(如果有的话)。在固体和结构力学问题中，泛函表示系统的总能量，而在其他问题中，它只是控制方程的积分表示。
变分原理在力学中一直起着重要的作用。首先，许多力学问题都是根据求极值(即最小值或最大值)来提出的，因此，就其本质而言，可以用变分陈述来表述。第二，有些问题可以用其他方法来表述，比如守恒定律，但这些问题也可以用变分原理来表述。第三，变分公式为获得实际问题的近似解提供了强有力的基础，否则许多实际问题就难以解决。例如，最小总势能原理可以看作是弹性体平衡方程的替代，也是建立位移有限元模型的基础，可以用来确定弹性体内的近似位移场和应力场。变分公式还可以统一不同的领域，提出新的理论，并为研究问题解的存在性和唯一性提供有力的手段。同样，Hamilton原理可以用来代替控制动力系统的方程，Biot提出的变分形式可以代替线性连续统热力学中的某些方程。

数学代写|有限元方法代写Finite Element Method代考|Variational Formulations

“变分公式”一词的经典用法是指一个泛函的构造(其含义将很快被阐明)或一个与问题的控制方程等效的变分原理。这个短语的现代用法是指将控制方程转化为等价的加权积分陈述的公式，这些陈述不一定等同于变分原理。甚至那些在经典意义上不承认变分原理的问题(例如，控制粘性或非粘性流体流动的Navier-Stokes方程)现在也可以用加权积分表述出来。
物理定律的变分公式的重要性，在这个短语的现代或一般意义上，远远超出了它作为其他公式的简单替代(见Oden和Reddy[1])。事实上，连续介质物理定律的变分形式可能是考虑它们的唯一自然和严格正确的方式。虽然所有足够光滑的场都会导致有意义的变分形式，但反过来是不成立的:存在物理现象，只有在变分设置中才能充分地用数学建模;从当地的角度来看，它们是荒谬的。
讨论有限元法的出发点是控制所研究的物理现象的微分方程。因此，我们将首先讨论为什么需要微分方程的积分表述。

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金融工程代写

非参数统计代写

非参数统计指的是一种统计方法，其中不假设数据来自于由少数参数决定的规定模型；这种模型的例子包括正态分布模型和线性回归模型。

广义线性模型代考

广义线性模型（GLM）归属统计学领域，是一种应用灵活的线性回归模型。该模型允许因变量的偏差分布有除了正态分布之外的其它分布。

有限元方法代写

随机分析代写

时间序列分析代写

回归分析代写

MATLAB代写

R语言代写	问卷设计与分析代写
PYTHON代写	回归分析与线性模型代写
MATLAB代写	方差分析与试验设计代写
STATA代写	机器学习/统计学习代写
SPSS代写	计量经济学代写
EVIEWS代写	时间序列分析代写
EXCEL代写	深度学习代写
SQL代写	各种数据建模与可视化代写

数学代写|有限元方法代写Finite Element Method代考|General Introduction

Posted on 2023年5月11日2023年5月11日 by statistics-lab

数学代写|有限元方法代写Finite Element Method代考|Variational Principles and Methods

This chapter is devoted to a review of mathematical preliminaries that prove to be useful in the sequel and a study of integral formulations and more commonly used variational methods such as the Ritz, Galerkin, collocation, subdomain, and least-squares methods. Since the finite element method can be viewed as an element-wise application of a variational method, it is useful to learn how variational methods work. We begin with a discussion of the general meaning of the phrases “variational methods” and “variational formulations” used in the literature.
The phrase “direct variational methods” refers to methods that make use of variational principles, such as the principles of virtual work and the principle of minimum total potential energy in solid and structural mechanics, to determine approximate solutions of problems (see Oden and Reddy [1] and Reddy [2]). In the classical sense, a variational principle has to do with finding the extremum (i.e., minimum or maximum) or stationary values of a functional with respect to the variables of the problem. The functional includes all the intrinsic features of the problem, such as the governing equations, boundary and/or initial conditions, and constraint conditions, if any. In solid and structural mechanics problems, the functional represents the total energy of the system, and in other problems it is simply an integral representation of the governing equations.
Variational principles have always played an important role in mechanics. First, many problems of mechanics are posed in terms of finding the extremum (i.e., minima or maxima) and thus, by their nature, can be formulated in terms of variational statements. Second, there are problems that can be formulated by other means, such as the conservation laws, but these can also be formulated by means of variational principles. Third, variational formulations form a powerful basis for obtaining approximate solutions to practical problems, many of which are intractable otherwise. The principle of minimum total potential energy, for example, can be regarded as a substitute to the equations of equilibrium of an elastic body, as well as a basis for the development of displacement finite element models that can be used to determine approximate displacement and stress fields in the body. Variational formulations can also serve to unify diverse fields, suggest new theories, and provide a powerful means to study the existence and uniqueness of solutions to problems. Similarly, Hamilton’s principle can be used in lieu of the equations governing dynamical systems, and the variational forms presented by Biot replace certain equations in linear continuum thermodynamics.

数学代写|有限元方法代写Finite Element Method代考|Variational Formulations

The classical use of the phrase “variational formulations” refers to the construction of a functional (whose meaning will be made clear shortly) or a variational principle that is equivalent to the governing equations of the problem. The modern use of the phrase refers to the formulation in which the governing equations are translated into equivalent weighted-integral statements that are not necessarily equivalent to a variational principle. Even those problems that do not admit variational principles in the classical sense (e.g., the Navier-Stokes equations governing the flow of viscous or inviscid fluids) can now be formulated using weighted-integral statements.
The importance of variational formulations of physical laws, in the modern or general sense of the phrase, goes far beyond its use as simply an alternative to other formulations (see Oden and Reddy [1]). In fact, variational forms of the laws of continuum physics may be the only natural and rigorously correct way to think of them. While all sufficiently smooth fields lead to meaningful variational forms, the converse is not true: there exist physical phenomena which can be adequately modelled mathematically only in a variational setting; they are nonsensical when viewed locally.
The starting point for the discussion of the finite element method is differential equations governing the physical phenomena under study. As such, we shall first discuss why integral statements of the differential equations are needed.

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|Variational Principles and Methods

数学代写|有限元方法代写Finite Element Method代考|Variational Formulations

统计代写请认准statistics-lab™. statistics-lab™为您的留学生涯保驾护航。

金融工程代写

非参数统计代写

非参数统计指的是一种统计方法，其中不假设数据来自于由少数参数决定的规定模型；这种模型的例子包括正态分布模型和线性回归模型。

广义线性模型代考

广义线性模型（GLM）归属统计学领域，是一种应用灵活的线性回归模型。该模型允许因变量的偏差分布有除了正态分布之外的其它分布。

有限元方法代写

随机分析代写

时间序列分析代写

回归分析代写

MATLAB代写

R语言代写	问卷设计与分析代写
PYTHON代写	回归分析与线性模型代写
MATLAB代写	方差分析与试验设计代写
STATA代写	机器学习/统计学习代写
SPSS代写	计量经济学代写
EVIEWS代写	时间序列分析代写
EXCEL代写	深度学习代写
SQL代写	各种数据建模与可视化代写

数学代写|有限元方法代写Finite Element Method代考|CIVL6840

Posted on 2023年2月28日2023年2月28日 by statistics-lab

如果你也在怎样代写有限元方法Finite Element Method这个学科遇到相关的难题，请随时右上角联系我们的24/7代写客服。

有限元法是一种系统的方法，将无限维函数空间中的函数首先转换为有限维函数空间中的函数，最后转换为用数值方法可以处理的普通向量。

我们提供的有限元方法Finite Element Method及其相关学科的代写，服务范围广, 其中包括但不限于:

Statistical Inference 统计推断
Statistical Computing 统计计算
Advanced Probability Theory 高等概率论
Advanced Mathematical Statistics 高等数理统计学
(Generalized) Linear Models 广义线性模型
Statistical Machine Learning 统计机器学习
Longitudinal Data Analysis 纵向数据分析
Foundations of Data Science 数据科学基础

数学代写|有限元方法代写Finite Element Method代考|CIVL6840

数学代写|有限元方法代写Finite Element Method代考|Consistent nodal load vector

Equations $(6.37)(\mathrm{c}, \mathrm{d})$ are used to find statically equivalent forces and moments acting on the nodes due to distributed forces acting along the element. These nodal forces (and moments) are referred to as the consistent nodal forces (and moments). Consider the concentrated and the distributed forces acting on the element shown in Fig. 6.3. By using Eqs. (6.37) and (6.29) the following consistent nodal force vectors are found.
Concentrated force: $-F_y \delta\left(x^{\prime}-a\right)$ acting along the $-y$-axis and located at $x^{\prime}=a$
$$
\left{r_q^{\prime}\right}^{(e)}=-F_y^{\prime}\left{\frac{b^2\left(L^{(e)}+2 a\right)}{L^{(e) 3}} \frac{a b^2}{L^{(e) 2}} \frac{a^2\left(L^{(e)}+2 b\right)}{L^{(e) 3}}-\frac{a^2 b}{L^{(e) 2}}\right}^T
$$
where $b=L-a$.
Linearly distributed force: $q_{y^{\prime}}=q_{y^{\prime} 1}+\frac{q_{y^{\prime} 2}-q_{y^{\prime} 1}}{L} x^{\prime}$. Note that $q_{y^{\prime}}$ is positive along the $+y^{\prime}$-axis.
$$
\left{r_q^{\prime}\right}^{(e)}=\left{\frac{\left(7 q_{y_1}+3 q_{y_2}\right) L^{(c)}}{20} \frac{\left(3 q_{y_1}+2 q_{y_2}\right) L^{(e) 2}}{60} \frac{\left(3 q_{y 1}+7 q_{y_2}\right) L^{(e)}}{20}-\frac{\left(2 q_{y_1 1}+3 q_{y_2 2}\right) L^{(e) 2}}{60}\right}^T
$$
Distributed force with constant magnitude: $q_{y^{\prime}}\left(x^{\prime}\right)=q_{y^{\prime} 0}$ which points along the $+y^{\prime}$-axis.
$$
\left{r_q{ }^{\prime}\right}^{(e)}=\left{\frac{q_{y_0} L^{(e)}}{2} \frac{q_{y^{\prime} 0} L^{(e) 2}}{12} \frac{q_{y_0 0} L^{(e)}}{2}-\frac{q_{y_0 0} L^{(e) 2}}{12}\right}^T
$$
The signs of the forces in these vectors are determined by the sign convention defined in Fig. 6.1.

数学代写|有限元方法代写Finite Element Method代考|General beam element with membrane

In many load bearing situations stretching and bending occurs on the same member, simultaneously (Fig. 6.4). The element stiffness matrix that represents the equilibrium of such a member is obtained by using the superposition of membrane and bending responses. Note that here we consider small deflection cases where these two effects can be assumed to be uncoupled from one another. The equilibrium equation for such a generic beam element is represented in matrix form as follows:
$$
\left[k_{m b}^{\prime}\right]^{(e)}\left{d_{m b}\right}^{(e)}=\left{r_{m b}\right}^{(e)}
$$
This relationship can be obtained by using a superposition of the membrane and beam mechanics, represented by Eqs. (5.22) and (6.38),
$$
\left[k_m{ }^{\prime}\right]^{(e)}\left{d_m{ }^{\prime}\right}^{(e)}+\left[k_b^{\prime}\right]^{(e)}\left{d_b{ }^{\prime}\right}^{(e)}=\left{r_m{ }^{\prime}\right}^{(e)}+\left{r_b\right}^{(e)}
$$
As the membrane and the bending actions are uncoupled (at least in this presentation) the following variables can be easily identified,
$$
\left.\left[k_{m b}\right]^{\prime}\right]^{(e)}=\left[\begin{array}{cccccc}
k_m & 0 & 0 & -k_m & 0 & 0 \
0 & 12 k_b & 6 k_b L^{(e)} & 0 & -12 k_b & 6 k_b L^{(e)} \
0 & 6 k_b L^{(e)} & 4 k_b L^{(e) 2} & 0 & -6 k_b L^{(e)} & 2 k_b L^{(e) 2} \
-k_m & 0 & 0 & k_m & 0 & 0 \
0 & -12 k_b & -6 k_b L^{(e)} & 0 & 12 k_b & -6 k_b L^{(e)} \
0 & 6 k_b L^{(e)} & 2 k_b L^{(e) 2} & 0 & -6 k_b L^{(e)} & 4 k_b L^{(e) 2}
\end{array}\right]
$$
with $k_m=\frac{E A}{L^{(e)}}$ and $k_b=\frac{E I}{\left.L^{(e)}\right)}$
$$
\begin{aligned}
& \left{d_{m b}{ }^{\prime}\right}^{(e)}=\left{\begin{array}{llllll}
u_1^{\prime} & v_1^{\prime} & \theta_1^{\prime} & u_2^{\prime} & v_2^{\prime} & \theta_2^{\prime}
\end{array}\right}^T \
& \left{r_{m b}\right}^{\prime(e)}=\left[\begin{array}{llllll}
F_{x^{\prime} 1} & F_{y^{\prime} 1} & M_1 & F_{x^{\prime} 2} & F_{y^{\prime} 2} & M_2
\end{array}\right}^T
\end{aligned}
$$

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|Consistent nodal load vector

方程式 $(6.37)(\mathrm{c}, \mathrm{d})$ 用于查找由于沿单元作用的分布力而作用在节点上的静态等效力和力矩。这些节点力 (和力矩) 被称为一致节点力 (和力矩) 。考虑作用在图 $6.3$ 中所示的单元上的集中力和分布力。通过使用方程式。(6.37) 和 (6.29) 找到以下一致的节点力矢量。
集中力量: $-F_y \delta\left(x^{\prime}-a\right)$ 沿着 $-y$-轴并位于 $x^{\prime}=a$
left{ $_r_{-} q^{\wedge}{$ prime $\left.} \backslash r i g h t\right}^{\wedge}{(e)}=-F _y^{\wedge}{\backslash$ prime $} \backslash l e f t\left{\backslash f r a c\left{b^{\wedge} 2 \backslash l e f t\left(L^{\wedge}{(e)}+2\right.\right.\right.$ a right $\left.)\right}{L \wedge{(e) 3}} \backslash f r a c\left{a b^{\wedge} 2\right}\left{L^{\wedge}{(e) 2\right.$
在哪里 $b=L-a$.
线性分布力： $q_{y^{\prime}}=q_{y^{\prime} 1}+\frac{q_{y^{\prime} 2}-q_{y^{\prime}}}{L} x^{\prime}$. 注意 $q_{y^{\prime}}$ 沿为正 $+y^{\prime}$-轴。
Veft $\left{r_{-} q^{\wedge}{\backslash\right.$ prime $\left.} \backslash r i g h t\right} \wedge{(e)}=\backslash \operatorname{eft}\left{\backslash f r a c\left{\backslash \operatorname{lft}\left(7 q_{-}\left{y_{-} 1\right}+3 q_{_}\left{y_{-} 2\right} \backslash r i g h t\right) L^{\wedge}{(c)}\right}{20} \backslash f r a c\left{\backslash e f t\left(3 q_{-}\left{y_{-} 1\right}+2 q_{-}\left{y_{-}\right.\right.\right.\right.$
大小恒定的分布力： $q_{y^{\prime}}\left(x^{\prime}\right)=q_{y^{\prime} 0}$ 哪个点沿着 $+y^{\prime}$-轴。
Veft{r_q {}$^{\wedge}{\backslash$ prime $\left.} \backslash r i g h t\right}^{\wedge}{(e)}=\bigvee$ left $\left{\right.$ frac $\left{q_{-}\left{y_{-} 0\right} L^{\wedge}{(e)}\right}{2} \backslash$ frac $\left{q_{_}\left{y^{\wedge}{\backslash p r i m e} 0\right} L^{\wedge}{(e) 2}\right}{12} \backslash f r a c\left{q_{-}\left{y_{-} 00\right.\right.$
这些矢量中力的符号由图 $6.1$ 中定义的符号约定确定。

数学代写|有限元方法代写Finite Element Method代考|General beam element with membrane

在许多承重情况下，拉伸和弯曲同时发生在同一构件上 (图 6.4) 。表示此类构件平衡的单元刚度矩阵是通过使用膜响应和弯曲响应的冝加获得的。请注意，这里我们考虑小偏转情况，其中可以假设这两种效应彼此不耦合。这种通用梁单元的平衡方程以矩阵形式表示如下:
这种关系可以通过使用由方程式表示的膜和梁力学的敢加来获得。(5.22) 和 (6.38)，
由于膜和弯曲动作是不耦合的（至少在本演示文稿中是这样），可以轻松识别以下变量，
和 $k_m=\frac{E A}{L^{(e)}}$ 和 $k_b=\frac{E I}{\left.L^{(e)}\right)}$

统计代写请认准statistics-lab™. statistics-lab™为您的留学生涯保驾护航。

金融工程代写

非参数统计代写

非参数统计指的是一种统计方法，其中不假设数据来自于由少数参数决定的规定模型；这种模型的例子包括正态分布模型和线性回归模型。

广义线性模型代考

广义线性模型（GLM）归属统计学领域，是一种应用灵活的线性回归模型。该模型允许因变量的偏差分布有除了正态分布之外的其它分布。

有限元方法代写

随机分析代写

时间序列分析代写

回归分析代写

MATLAB代写

R语言代写	问卷设计与分析代写
PYTHON代写	回归分析与线性模型代写
MATLAB代写	方差分析与试验设计代写
STATA代写	机器学习/统计学习代写
SPSS代写	计量经济学代写
EVIEWS代写	时间序列分析代写
EXCEL代写	深度学习代写
SQL代写	各种数据建模与可视化代写

数学代写|有限元方法代写Finite Element Method代考|ENGR7961

Posted on 2023年2月28日2023年2月28日 by statistics-lab

如果你也在怎样代写有限元方法Finite Element Method这个学科遇到相关的难题，请随时右上角联系我们的24/7代写客服。

有限元法是一种系统的方法，将无限维函数空间中的函数首先转换为有限维函数空间中的函数，最后转换为用数值方法可以处理的普通向量。

我们提供的有限元方法Finite Element Method及其相关学科的代写，服务范围广, 其中包括但不限于:

Statistical Inference 统计推断
Statistical Computing 统计计算
Advanced Probability Theory 高等概率论
Advanced Mathematical Statistics 高等数理统计学
(Generalized) Linear Models 广义线性模型
Statistical Machine Learning 统计机器学习
Longitudinal Data Analysis 纵向数据分析
Foundations of Data Science 数据科学基础

数学代写|有限元方法代写Finite Element Method代考|ENGR7961

数学代写|有限元方法代写Finite Element Method代考|Total potential energy of a beam element

Similar to the development presented for the axial bar in Section 5.2.4, the total potential energy of the beam under the effect of external forces is expressed as follows:
$$
\begin{aligned}
& \pi_p^{(e)}=U^{(e)}-W^{(e)} \
& \pi_p^{(e)}=\int_A \int_0^{L^{(e)}} \sigma^{\prime} d \varepsilon^{\prime} d A d x^{\prime}-\left(\int_0^{L^{(-)}} v^{\prime}\left(F_b A+q\right) d x^{\prime}+v_1^{\prime} F_{y 1}{ }^{\prime}+v_2^{\prime} F_{y 2}{ }^{\prime}+\theta_1 M_1+\theta_2 M_2\right)
\end{aligned}
$$
where the first term represents the strain energy stored in the beam, and the second term represents the work done by the external forces. Note that for a beam we have $d A=b d y^{\prime}$ where $b$ is the breadth of the beam’s cross-section.
The bending strain, is a longitudinal strain $\varepsilon_{x^{\prime}}$, which depends on the normal distance as measured from the neutral axis of the beam (Fig. 6.2) as given in Eq. (2.138),
$$
\varepsilon_{x^{\prime}}=-y^{\prime} \frac{d^2 v^{\prime}}{d x^{\prime 2}}
$$

The strain energy component of the total potential energy then becomes,
$$
U_b^{(e)}=\frac{1}{2} \int_0^{L^{(e)}}\left[\int_A E\left(-y^{\prime} \frac{d^2 v^{\prime}}{d x^2}\right)^2 b d y^{\prime}\right] d x^{\prime}=\frac{1}{2} \int_0^{L^{(e)}} E\left(\frac{d^2 v^{\prime}}{d x^2}\right)^2\left(\int_{-c / 2}^{c / 2} y^2 b d y^{\prime}\right) d x^{\prime}
$$
Note that the inner integral over the area represents the definition of the second moment of area
$$
I=\int_{-c / 2}^{c / 2} y^{\prime 2} b d y^{\prime}
$$
The strain energy due to bending $U_b^{(e)}$ in a beam element is therefore expressed as follows:
$$
U_b^{(e)}=\frac{1}{2} \int_0^{L^{(e)}} E I\left(\frac{d^2 v^{\prime}}{d x^{\prime 2}}\right)^2 d x^{\prime}, \text { or } U_b^{(e)}=\frac{1}{2} \int_0^{L^{(e)}} E I\left(\frac{d \theta}{d x^{\prime}}\right)^2 d x^{\prime}
$$

数学代写|有限元方法代写Finite Element Method代考|Finite element form of the equilibrium equations

The principle of minimum total potential energy states that the equilibrium conditions are found when the variation of the total potential energy functional is zero. For an Euler-Bernoulli beam element, this is expressed as follows:
$$
\delta \pi_p^{(\varepsilon)}=\int_0^{L^{(c)}} E I \frac{d \theta}{d x^{\prime}} \frac{d \delta \theta}{d x^{\prime}} d x^{\prime}-\left(\int_0^{L^{(c)}} \delta v^{\prime}\left(F_{B y^{\prime}} A+q_y\right) d x^{\prime}+\delta v_1{ }^{\prime} F_{y_1}+\delta v_2{ }^{\prime} F_{y^{\prime}}+\delta \theta_1 M_1+\delta \theta_2 M_2\right)
$$

In order to find an expression for the curvature, $d \theta / d x^{\prime}$ recall that the beam deflection $v^{\prime}$ is approximated as follows:
$$
\begin{aligned}
v^{\prime}\left(x^{\prime}\right) & =N_1^{(b)} v_1^{\prime}+N_2^{(b)} \theta_1+N_3^{(b)} v_2{ }^{\prime}+N_4^{(b)} \theta_2 \text { (a) } \
& =\left[N^{(b)}\right]\left{d_b^{\prime}\right}^{(e)}
\end{aligned}
$$
where $\left[N^{(b)}\right]$ and $\left{d_b^{\prime}\right}^{(e)}$ are the shape function matrix and the degree of freedom vector, (Eq. (6.10)(a)) respectively,
$$
\left[\begin{array}{llll}
N^{(b)}
\end{array}\right]=\left[\begin{array}{llll}
N_1^{(b)} & N_2^{(b)} & N_3^{(b)} & N_4^{(b)}
\end{array}\right]
$$
$N_i^{(L)}$ are the $\mathrm{C}^1$-continuous shape functions given by Eq. (6.5). Using this approximation, the curvature vector is found as follows:
$$
\frac{d \theta}{d x^{\prime}}=\frac{d^2 v^{\prime}}{d x^{\prime 2}}=\frac{d^2}{d x^{\prime 2}}\left(\left[N^{(b)}\right]\left{d_b^{\prime}\right}^{(e)}\right)=\left[B^{(b)}\right]\left{d_b^{\prime}\right}^{(e)}
$$
where $\left[\begin{array}{llll}B^{(b)}\end{array}\right]=\left[\begin{array}{llll}B_1^{(b)} & B_2^{(b)} & B_3^{(b)} & B_4^{(b)}\end{array}\right]$ is the curvature-displacement matrix with,
$$
\begin{aligned}
& B_1^{(b)}=\frac{d^2 N_1^{(b)}}{d x^2}=\left(-\frac{6}{L^{(e) 2}}+\frac{12 x^{\prime}}{L^{(e) 3}}\right), \quad B_2^{(b)}=\frac{d^2 N_2^{(b)}}{d x^{\prime 2}}=\left(-\frac{4}{L^{(e)}}+\frac{6 x}{L^{(e) 2}}\right), \
& B_3^{(b)}=\frac{d^2 N_3^{(b)}}{d x^{\prime 2}}=\left(\frac{6}{L^{(e) 2}}-\frac{12 x^{\prime}}{L^{(e) 3}}\right), \quad B_4=\frac{d^2 N_4^{(b)}}{d x^{\prime 2}}=\left(-\frac{2}{L^{(e)}}+\frac{6 x^{\prime}}{L^{(e) 2}}\right)
\end{aligned}
$$

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|Total potential energy of a beam element

类似于第 5.2.4 节中轴杆的开发，梁在外力作用下的总势能表示如下:
$$
\pi_p^{(e)}=U^{(e)}-W^{(e)} \quad \pi_p^{(e)}=\int_A \int_0^{L^{(e)}} \sigma^{\prime} d \varepsilon^{\prime} d A d x^{\prime}-\left(\int_0^{L^{(-)}} v^{\prime}\left(F_b A+q\right) d x^{\prime}+v_1^{\prime} F_{y 1}^{\prime}+v_2^{\prime}\right.
$$
其中第一项表示存储在梁中的应变能，第二项表示外力所做的功。请注意，对于光束，我们有 $d A=b d y^{\prime}$ 在哪里 $b$ 是梁横截面的宽度。
弯曲应变是纵向应变 $\varepsilon_{x^{\prime}}$ ，这取决于从梁的中性轴（图 6.2）测量的法向距离，如等式 1 中给出。(2.138)，
$$
\varepsilon_{x^{\prime}}=-y^{\prime} \frac{d^2 v^{\prime}}{d x^{\prime 2}}
$$
总势能的应变能分量变为，
$$
U_b^{(e)}=\frac{1}{2} \int_0^{L^{(e)}}\left[\int_A E\left(-y^{\prime} \frac{d^2 v^{\prime}}{d x^2}\right)^2 b d y^{\prime}\right] d x^{\prime}=\frac{1}{2} \int_0^{L^{(e)}} E\left(\frac{d^2 v^{\prime}}{d x^2}\right)^2\left(\int_{-c / 2}^{c / 2} y^2 b d y^{\prime}\right) d x^{\prime}
$$
请注意，面积上的内部积分表示面积二阶矩的定义
$$
I=\int_{-c / 2}^{c / 2} y^{\prime 2} b d y^{\prime}
$$
弯曲引起的应变能 $U_b^{(e)}$ 因此，在梁单元中表示如下:
$$
U_b^{(e)}=\frac{1}{2} \int_0^{L^{(e)}} E I\left(\frac{d^2 v^{\prime}}{d x^{\prime 2}}\right)^2 d x^{\prime}, \text { or } U_b^{(e)}=\frac{1}{2} \int_0^{L^{(e)}} E I\left(\frac{d \theta}{d x^{\prime}}\right)^2 d x^{\prime}
$$

数学代写|有限元方法代写Finite Element Method代考|Finite element form of the equilibrium equations

最小总势能原理指出，当总势能泛函的变化为零时，就会找到平衡条件。对于 Euler-Bernoulli 梁单元，这表示如下:
$$
\delta \pi_p^{(\varepsilon)}=\int_0^{L^{(c)}} E I \frac{d \theta}{d x^{\prime}} \frac{d \delta \theta}{d x^{\prime}} d x^{\prime}-\left(\int_0^{L^{(c)}} \delta v^{\prime}\left(F_{B y^{\prime}} A+q_y\right) d x^{\prime}+\delta v_1^{\prime} F_{y_1}+\delta v_2^{\prime} F_{y^{\prime}}+\delta \theta_1 M_1\right.
$$
为了找到曲率的表达式， $d \theta / d x^{\prime}$ 回想一下光束偏转 $v^{\prime}$ 近似如下:
‘begin ${$ aligned $} v^{\wedge}{$ lprime $} \backslash l e f t\left(x^{\wedge}{\backslash\right.$ prime $} \backslash$ \right) $\&=N _1 \wedge{(b)} v_{-} 1^{\wedge}{$ lprime $}+N _2^{\wedge}{(b)} \backslash$ theta_ $1+N_{-} 3^{\wedge}{(b)} v_{-} 2{}^{\wedge}$
$$
\left[N^{(b)}\right]=\left[\begin{array}{llll}
N_1^{(b)} & N_2^{(b)} & N_3^{(b)} & N_4^{(b)}
\end{array}\right]
$$
$N_i^{(L)}$ 是 $\mathrm{C}^1$ – 由等式给出的连续形状函数。(6.5)。使用此近似值，曲率向量如下所示:
在哪里 $\left[B^{(b)}\right]=\left[\begin{array}{llll}B_1^{(b)} & B_2^{(b)} & B_3^{(b)} & B_4^{(b)}\end{array}\right]$ 是曲率位移矩阵，
$$
B_1^{(b)}=\frac{d^2 N_1^{(b)}}{d x^2}=\left(-\frac{6}{L^{(e) 2}}+\frac{12 x^{\prime}}{L^{(e) 3}}\right), \quad B_2^{(b)}=\frac{d^2 N_2^{(b)}}{d x^{\prime 2}}=\left(-\frac{4}{L^{(e)}}+\frac{6 x}{L^{(e) 2}}\right), \quad B_3^{(b)}
$$

统计代写请认准statistics-lab™. statistics-lab™为您的留学生涯保驾护航。

金融工程代写

非参数统计代写

非参数统计指的是一种统计方法，其中不假设数据来自于由少数参数决定的规定模型；这种模型的例子包括正态分布模型和线性回归模型。

广义线性模型代考

广义线性模型（GLM）归属统计学领域，是一种应用灵活的线性回归模型。该模型允许因变量的偏差分布有除了正态分布之外的其它分布。

有限元方法代写

随机分析代写

时间序列分析代写

回归分析代写

MATLAB代写

R语言代写	问卷设计与分析代写
PYTHON代写	回归分析与线性模型代写
MATLAB代写	方差分析与试验设计代写
STATA代写	机器学习/统计学习代写
SPSS代写	计量经济学代写
EVIEWS代写	时间序列分析代写
EXCEL代写	深度学习代写
SQL代写	各种数据建模与可视化代写

数学代写|有限元方法代写Finite Element Method代考|EG3001

Posted on 2023年2月21日2023年2月21日 by statistics-lab

如果你也在怎样代写有限元方法Finite Element Method这个学科遇到相关的难题，请随时右上角联系我们的24/7代写客服。

有限元法是一种系统的方法，将无限维函数空间中的函数首先转换为有限维函数空间中的函数，最后转换为用数值方法可以处理的普通向量。

我们提供的有限元方法Finite Element Method及其相关学科的代写，服务范围广, 其中包括但不限于:

Statistical Inference 统计推断
Statistical Computing 统计计算
Advanced Probability Theory 高等概率论
Advanced Mathematical Statistics 高等数理统计学
(Generalized) Linear Models 广义线性模型
Statistical Machine Learning 统计机器学习
Longitudinal Data Analysis 纵向数据分析
Foundations of Data Science 数据科学基础

数学代写|有限元方法代写Finite Element Method代考|EG3001

数学代写|有限元方法代写Finite Element Method代考|One-dimensional, Lagrange interpolation functions

Shape functions for the domain $x^{\prime} \in\left[0, L^{(e)}\right]$ : In finite element method each small segment is assigned its own local coordinate system. In this case the domain of the element is defined as $x^{\prime} \in\left[0, L^{(e)}\right]$. The shape functions for this domain can be easily obtained by letting,
$x_1=0$ and $x_2=L^{(e)}$ for the linear shape functions, and
$x_1=0, x_2=r L^{(e)}$ and $x_3=L^{(e)}$ for the quadratic shape functions
in Eqs. (4.23) and (4.30), respectively. Note that $r(0<r<1)$ is a coefficient that ensures that node- 2 is located between nodes-1 and-3. This gives,
Linear shape functions:
$$
N_1\left(x^{\prime}\right)=1-\frac{x^{\prime}}{L^{(e)}} \text { and } N_2\left(x^{\prime}\right)=\frac{x^{\prime}}{L^{(e)}}
$$
Quadratic shape functions:
for $0<r<1$ :
$$
\begin{aligned}
& N_1\left(x^{\prime}\right)=\left(1-\frac{x^{\prime}}{r L^{(e)}}\right)\left(1-\frac{x^{\prime}}{L^{(e)}}\right) \
& N_2\left(x^{\prime}\right)=\frac{1}{1-r}\left(\frac{x^{\prime}}{r L^{(e)}}\right)\left(1-\frac{x^{\prime}}{L^{(e)}}\right) \
& N_3\left(x^{\prime}\right)=\frac{1}{r-1}\left(\frac{x^{\prime}}{L^{(e)}}\right)\left(r-\frac{x^{\prime}}{L^{(e)}}\right)
\end{aligned}
$$ for $r=1 / 2$ :
$$
\begin{aligned}
& N_1\left(x^{\prime}\right)=\left(1-2 \frac{x^{\prime}}{L^{(e)}}\right)\left(1-\frac{x^{\prime}}{L^{(e)}}\right) \
& N_2\left(x^{\prime}\right)=4\left(\frac{x^{\prime}}{L^{(e)}}\right)\left(1-\frac{x^{\prime}}{L^{(e)}}\right) \
& N_3\left(x^{\prime}\right)=-\left(\frac{x^{\prime}}{L^{(e)}}\right)\left(1-2 \frac{x^{\prime}}{L^{(e)}}\right)
\end{aligned}
$$

数学代写|有限元方法代写Finite Element Method代考|Equilibrium equations in finite element form

The finite element formulation of this boundary value problem described by Eqs. (4.3)-(4.5) will be carried out by using the method of weighted residuals. The weighted residual integral of the boundary value problem is given as follows:
$$
\int_0^{L^{(e)}} w\left[\frac{d}{d x^{\prime}}\left(a \frac{d u}{d x^{\prime}}\right)+p u+q\right] d x^{\prime}=0 \text { in } 0<x^{\prime}<L^{(e)}
$$
where $w\left(x^{\prime}\right)$ is an arbitrary weight function with the properties described in Section 3.5. Integrating the first term by parts,
$$
\begin{aligned}
& w\left(L^{(e)}\right)\left(\left.a_{L^{(e)}} \frac{d u}{d x^{\prime}}\right|{L^{(e)}}\right)-w(0)\left(\left.a_0 \frac{d u}{d x^{\prime}}\right|_0\right) \ & -\int_0^{L(e)} a \frac{d u}{d x^{\prime}} \frac{d w}{d x^{\prime}} d x^{\prime}+\int_0^{L(e)} p w u d x^{\prime}+\int_0^{L(e)} w q d x^{\prime}=0 \end{aligned} $$ and using the natural boundary conditions given in Eqs. (4.4) and (4.5), the weak form of the boundary value problem is found ās föllows: $$ \begin{aligned} & w\left(L^{(e)}\right)\left(a{L^{(e)}}\left(\alpha_{L^{(e)}} u_{L^{(e)}}+\beta_{\left.L^{(e)}\right)}\right)\right)-w(0)\left(-a_0\left(\alpha_0 u_0+\beta_0\right)\right)- \
& \int_0^{L^{(e)}} a \frac{d u}{d x^{\prime}} \frac{d w}{d x^{\prime}} d x^{\prime}+\int_0^{L^{(c)}} p w u d x^{\prime}+\int_0^{L^{(e)}} w q d x^{\prime}=0
\end{aligned}
$$
Note that the weight function has the properties of the variation of $u$. Making the substitution $w \rightarrow \delta u$ and using the nodal notation for variables at the ends of the element, $u_1=u(0)=u_0$ and $u_2=u\left(L^{(e)}\right)=u_{L^{(e)}}$, the weak form is transformed as follows:
$$
\begin{aligned}
\delta u_2\left(a_2\left(\alpha_2 u_2+\beta_2\right)\right)-\delta u_1\left(-a_1\left(\alpha u_1+\beta_1\right)\right) \
-\int_0^{L^{(c)}} a \frac{d u}{d x^{\prime}} \frac{d \delta u}{d x^{\prime}} d x^{\prime}+\int_0^{L^{(e)}} p u \delta u d x^{\prime}+\int_0^{L^{(c)}} q \delta u d x^{\prime}=0
\end{aligned}
$$
First, let us consider a two node, $C^{(0)}$ element shown in the Fig. 4.2. Higher order interpolations for $\tilde{u}$ can also be considered.

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|One-dimensional, Lagrange interpolation functions

域的形函数 $x^{\prime} \in\left[0, L^{(e)}\right]$ : 在有限元法中，每个小段都分配有自己的局部坐标系。在这种情况下，元素的域定义为 $x^{\prime} \in\left[0, L^{(e)}\right]$. 这个域的形状函数可以很容易地通过让，
$x_1=0$ 和 $x_2=L^{(e)}$ 对于线性形函数，和
$x_1=0, x_2=r L^{(e)}$ 和 $x_3=L^{(e)}$ 对于方程式中的二次形函数
。分别为 (4.23) 和 (4.30)。注意 $r(0<r<1)$ 是确保节点 2 位于节点 1 和节点 3 之间的系数。这给出了线性形函数:
$$
N_1\left(x^{\prime}\right)=1-\frac{x^{\prime}}{L^{(e)}} \text { and } N_2\left(x^{\prime}\right)=\frac{x^{\prime}}{L^{(e)}}
$$
二次形函数:
对于 $0<r<1$ :
$$
N_1\left(x^{\prime}\right)=\left(1-\frac{x^{\prime}}{r L^{(e)}}\right)\left(1-\frac{x^{\prime}}{L^{(e)}}\right) \quad N_2\left(x^{\prime}\right)=\frac{1}{1-r}\left(\frac{x^{\prime}}{r L^{(e)}}\right)\left(1-\frac{x^{\prime}}{L^{(e)}}\right) N_3\left(x^{\prime}\right)=\frac{r}{r}
$$
为了 $r=1 / 2$ :
$$
N_1\left(x^{\prime}\right)=\left(1-2 \frac{x^{\prime}}{L^{(e)}}\right)\left(1-\frac{x^{\prime}}{L^{(e)}}\right) \quad N_2\left(x^{\prime}\right)=4\left(\frac{x^{\prime}}{L^{(e)}}\right)\left(1-\frac{x^{\prime}}{L^{(e)}}\right) N_3\left(x^{\prime}\right)=-\left(\frac{x}{L^{(}}\right.
$$

数学代写|有限元方法代写Finite Element Method代考|Equilibrium equations in finite element form

方程式描述了这个边界值问题的有限元公式。(4.3)-(4.5)将采用加权残差法进行。给出边值问题的加权残差积分如下:
$$
\int_0^{L^{(e)}} w\left[\frac{d}{d x^{\prime}}\left(a \frac{d u}{d x^{\prime}}\right)+p u+q\right] d x^{\prime}=0 \text { in } 0<x^{\prime}<L^{(e)}
$$
在哪里 $w\left(x^{\prime}\right)$ 是具有第 $3.5$ 节中描述的属性的任意权重函数。对第一项进行部分积分，
$$
w\left(L^{(e)}\right)\left(a_{L^{(e)}} \frac{d u}{d x^{\prime}} \mid L^{(e)}\right)-w(0)\left(\left.a_0 \frac{d u}{d x^{\prime}}\right|0\right) \quad-\int_0^{L(e)} a \frac{d u}{d x^{\prime}} \frac{d w}{d x^{\prime}} d x^{\prime}+\int_0^{L(e)} p w u d x^{\prime}+ $$ 并使用等式中给出的自然边界条件。(4.4) 和 (4.5) 边值问题的弱形式如下: $$ w\left(L^{(e)}\right)\left(a L^{(e)}\left(\alpha{L^{(e)}} u_{L^{(e)}}+\beta_{\left.L^{(e)}\right)}\right)\right)-w(0)\left(-a_0\left(\alpha_0 u_0+\beta_0\right)\right)-\int_0^{L^{(e)}} a \frac{d u}{d x^{\prime}} \frac{d w}{d x^{\prime}} d x^{\prime}
$$
请注意，权重函数具有以下变化的性质 $u$. 进行替换 $w \rightarrow \delta u$ 并在元素的末端使用节点符号表示变量， $u_1=u(0)=u_0$ 和 $u_2=u\left(L^{(e)}\right)=u_{L^{(e)}}$ ，弱形式变换如下:
$$
\delta u_2\left(a_2\left(\alpha_2 u_2+\beta_2\right)\right)-\delta u_1\left(-a_1\left(\alpha u_1+\beta_1\right)\right)-\int_0^{L^{(c)}} a \frac{d u}{d x^{\prime}} \frac{d \delta u}{d x^{\prime}} d x^{\prime}+\int_0^{L^{(e)}} p u \delta u d x^{\prime}+\int_0^{L^{(c)}}
$$
首先，让我们考虑一个双节点， $C^{(0)}$ 元素如图 $4.2$ 所示。高阶揷值 $\tilde{u}$ 也可以考虑。

统计代写请认准statistics-lab™. statistics-lab™为您的留学生涯保驾护航。

金融工程代写

非参数统计代写

非参数统计指的是一种统计方法，其中不假设数据来自于由少数参数决定的规定模型；这种模型的例子包括正态分布模型和线性回归模型。

广义线性模型代考

广义线性模型（GLM）归属统计学领域，是一种应用灵活的线性回归模型。该模型允许因变量的偏差分布有除了正态分布之外的其它分布。

有限元方法代写

随机分析代写

时间序列分析代写

回归分析代写

MATLAB代写

R语言代写	问卷设计与分析代写
PYTHON代写	回归分析与线性模型代写
MATLAB代写	方差分析与试验设计代写
STATA代写	机器学习/统计学习代写
SPSS代写	计量经济学代写
EVIEWS代写	时间序列分析代写
EXCEL代写	深度学习代写
SQL代写	各种数据建模与可视化代写

数学代写|有限元方法代写Finite Element Method代考|ENGR7961

Posted on 2023年2月21日2023年2月21日 by statistics-lab

如果你也在怎样代写有限元方法Finite Element Method这个学科遇到相关的难题，请随时右上角联系我们的24/7代写客服。

有限元法是一种系统的方法，将无限维函数空间中的函数首先转换为有限维函数空间中的函数，最后转换为用数值方法可以处理的普通向量。

我们提供的有限元方法Finite Element Method及其相关学科的代写，服务范围广, 其中包括但不限于:

Statistical Inference 统计推断
Statistical Computing 统计计算
Advanced Probability Theory 高等概率论
Advanced Mathematical Statistics 高等数理统计学
(Generalized) Linear Models 广义线性模型
Statistical Machine Learning 统计机器学习
Longitudinal Data Analysis 纵向数据分析
Foundations of Data Science 数据科学基础

数学代写|有限元方法代写Finite Element Method代考|One-dimensional interpolation for finite element method

We are interested in developing a polynomial approximation $\tilde{u}$ for $u(x)$ in a region $x_1^{\prime} \leq x^{\prime} \leq x_2{ }^{\prime}$ We are going to use an interpolation that passes through $M+1$ points in this region:
$$
u\left(x^{\prime}\right) \approx \tilde{u}\left(x^{\prime}\right)=a_0+\sum_{j=1}^M a_j x^j
$$
where $a_0$ and $a_j$ are constant coefficients. In this section we transform this polynomial approximation from one whose unknowns are $a_0$ and $a_j$, to one whose unknowns are $u_j$. The polynomial will be required pass through points $\left(x_j^{\prime}, u_j\right)$ wheree $1 \leq j \leq M+1$ with $x_1^{\prime}=0$ and $x_M^{\prime}=L^{(e)}$. The values of $u_j$ aree known at $M+1$ positions in this domain. The approach developed in the next section results in a polynomial approximation of $u(x)$ that is of order $M$, also known as the Lagrange interpolation,
$$
\tilde{u}\left(x^{\prime}\right)=\sum_{i=1}^{M+1} N_i\left(x^{\prime}\right) u_i
$$
where the shape functions $N_i\left(x^{\prime}\right)$ are defined as follows:
$$
N_i\left(x^{\prime}\right)=\frac{\left(x_1^{\prime}-x^{\prime}\right)\left(x_2^{\prime}-x^{\prime}\right) \cdots\left(x_{i-1}^{\prime}-x^{\prime}\right)\left(x_{i+1}^{\prime}-x^{\prime}\right) \cdots\left(x_M^{\prime}-x^{\prime}\right)\left(x_{M+1}^{\prime}-x^{\prime}\right)}{\left(x_1^{\prime}-x_i^{\prime}\right)\left(x_2^{\prime}-x_i^{\prime}\right) \cdots\left(x_{i-1}^{\prime}-x_i^{\prime}\right)\left(x_{i+1}^{\prime}-x_i^{\prime}\right) \cdots\left(x_M^{\prime}-x_i^{\prime}\right)\left(x_{M+1}^{\prime}-x_i^{\prime}\right)}
$$
General characteristics of Lagrange shape functions are as follows:
$N_i=1$ at $x^{\prime}=x_i^{\prime}$, but zero at the other positions (nodes)
(C1)
$N_i$ are polynomials of the same degree
(C2)
The sum of all shape functions is equal to one, i.e., $\sum_{i=1}^{M+1} N_i=1$.
(C3)
It is important to keep in mind that the Lagrange interpolation (4.13) gives a polynomial approximation that is exactly of the same polynomial order as Eq. (4.12), but the unknowns are expressed in terms of $u_i$ instead of $a_i$. This will be demonstrated in the following sections.
$\mathrm{C}^0$ Continuity
Note that Lagrange shape functions use only the nodal degrees of freedom $u_i$. Eq. (4.13) ensures the continuity of the degrees of freedom at the nodes. Interpolation functions that only provide the continuity of the primitive variable across element boundaries are said to be $\mathrm{C}^0$ continuous.

Later we will develop interpolation functions that provide higher order continuity, e.g., $u_j$ and $d u_j / d x^{\prime}$.

数学代写|有限元方法代写Finite Element Method代考|General form of C0 shape functions

Consider the polynomial approximation,
$$
\tilde{u}=a_0+a_1 x^{\prime}+a_2 x^{\prime 2}+a_3 x^{\prime 3}+\ldots a_n x^{\prime M}
$$
which can also be represented as follows:
$$
\tilde{u}=[X]{a}=\sum_{i=0}^M a_j x^j
$$
where,
$$
\begin{aligned}
& {[X]=\left[\begin{array}{llllll}
1 & x^{\prime} & x^{\prime 2} & x^{\prime 3} & \ldots & x^{\prime M}
\end{array}\right]} \
& {a}=\left{\begin{array}{llllll}
a_0 & a_1 & a_2 & a_3 & \ldots & a_M
\end{array}\right}^T
\end{aligned}
$$
After we evaluate $u$ at $(M+1)$ different $x_i^{\prime}$ locations, we get a system of $(M+1)$ algebraic equations for the unknown $a_i$,
$$
\begin{aligned}
& u_1=u\left(x_1^{\prime}\right)=a_0+a_1 x_1^{\prime}+a_2 x^{\prime 2}{ }1+a_3 x^{\prime 3}{ }_1+\ldots a_M x^{\prime M}{ }_1 \ & u_2=u\left(x_2^{\prime}\right)=a_0+a_1 x_2^{\prime}+a_2 x^{\prime 2}{ }_2+a_3 x^{\prime 3}{ }_2+\ldots a_M x^{\prime}{ }_2 \ & \vdots \ & u{M+1}=u\left(x^{\prime}{ }{M+1}\right)=a_0+a_1 x{M+1}^{\prime}+a_2 x^{\prime 2}{ }{M+1}+a_3 x^{\prime 3}{ }{M+1}+\ldots a_M x^M{ }_{M+1}
\end{aligned}
$$

有限元方法代考

数学代写|有限元方法代写Finite Element Method代考|One-dimensional interpolation for finite element method

我们有兴趣开发多项式近似 $\tilde{u}$ 为了 $u(x)$ 在一个地区 $x_1^{\prime} \leq x^{\prime} \leq x_2{ }^{\prime}$ 我们将使用通过的揷值 $M+1$ 该地区的要点:
$$
u\left(x^{\prime}\right) \approx \tilde{u}\left(x^{\prime}\right)=a_0+\sum_{j=1}^M a_j x^j
$$
在哪里 $a_0$ 和 $a_j$ 是常数系数。在本节中，我们将这个多项式近似值从末知数为 $a_0$ 和 $a_j$ ，对于一个末知数是 $u_j$. 多项式将需要通过点 $\left(x_j^{\prime}, u_j\right)$ 在哪里 $1 \leq j \leq M+1$ 和 $x_1^{\prime}=0$ 和 $x_M^{\prime}=L^{(e)}$. 的价值观 $u_j$ 众所周知 $M+1$ 该领域的职位。下一节中开发的方法导致多项式近似 $u(x)$ 那是有秩序的 $M$ ，也称为拉格朗日揷值，
$$
\tilde{u}\left(x^{\prime}\right)=\sum_{i=1}^{M+1} N_i\left(x^{\prime}\right) u_i
$$
形状起作用的地方 $N_i\left(x^{\prime}\right)$ 定义如下：
$$
N_i\left(x^{\prime}\right)=\frac{\left(x_1^{\prime}-x^{\prime}\right)\left(x_2^{\prime}-x^{\prime}\right) \cdots\left(x_{i-1}^{\prime}-x^{\prime}\right)\left(x_{i+1}^{\prime}-x^{\prime}\right) \cdots\left(x_M^{\prime}-x^{\prime}\right)\left(x_{M+1}^{\prime}-x^{\prime}\right)}{\left(x_1^{\prime}-x_i^{\prime}\right)\left(x_2^{\prime}-x_i^{\prime}\right) \cdots\left(x_{i-1}^{\prime}-x_i^{\prime}\right)\left(x_{i+1}^{\prime}-x_i^{\prime}\right) \cdots\left(x_M^{\prime}-x_i^{\prime}\right)\left(x_{M+1}^{\prime}-x_i^{\prime}\right)}
$$
拉格朗日形函数的一般特征如下：
$N_i=1$ 在 $x^{\prime}=x_i^{\prime}$ ，但在其他位置（节点）为零
(C1)
$N_i$ 是同次多项式
(C2)
所有形函数之和等于一，即 $\sum_{i=1}^{M+1} N_i=1$.
(C3)
重要的是要记住，拉格朗日揷值 (4.13) 给出的多项式近似与方程式的多项式阶数完全相同。（4.12)，但末知数表示为 $u_i$ 代替 $a_i$. 这将在以下部分中进行演示。
$\mathrm{C}^0$ 连续性
请注意，拉格朗日形状函数仅使用节点自由度 $u_i$. 当量。(4.13) 确保节点自由度的连续性。仅提供跨元素边界的原始变量连续性的揷值函数被称为 $\mathrm{C}^0$ 连续的。
稍后我们将开发提供高阶连续性的揷值函数，例如， $u_j$ 和 $d u_j / d x^{\prime}$.

数学代写|有限元方法代写Finite Element Method代考|General form of C0 shape functions

考虑多项式近似，
$$
\tilde{u}=a_0+a_1 x^{\prime}+a_2 x^{\prime 2}+a_3 x^{\prime 3}+\ldots a_n x^{\prime M}
$$
也可以表示为:
$$
\tilde{u}=[X] a=\sum_{i=0}^M a_j x^j
$$
在哪里，
Ibegin{aligned $}\left{\left[[X]=\backslash \mid e f t\left[\backslash b e g i n{a r r a y}{\mid I I I I} 1 \& x^{\wedge}{\backslash p r i m e} \& x^{\wedge}{\backslash p r i m e ~ 2} \& x^{\wedge}{\backslash p r i m e ~ 3} \& \mid\right.\right.\right.$ dots\& $x^{\wedge}{\backslash p r i m e ~ M} \backslash e n d{a r r$
我们评估后 $u$ 在 $(M+1)$ 不同的 $x_i^{\prime}$ 位置，我们得到一个系统 $(M+1)$ 末知数的代数方程 $a_i$ ，
$$
u_1=u\left(x_1^{\prime}\right)=a_0+a_1 x_1^{\prime}+a_2 x^{\prime 2} 1+a_3 x_1^{\prime 3}+\ldots a_M x_1^{\prime M} \quad u_2=u\left(x_2^{\prime}\right)=a_0+a_1 x_2^{\prime}+a_2
$$

统计代写请认准statistics-lab™. statistics-lab™为您的留学生涯保驾护航。

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