一阶拟线性双曲型方程组慢时间尺度下的零松弛极限

本文考虑慢时间尺度下带松弛时间源项的高维一阶拟线性双曲型方程组Cauchy问题的光滑解,这个方程组具有非守恒的形式;假设它是部分耗散的对称双曲组,当松弛时间趋于零时,它在形式上趋于一个两阶非线性抛物型方程组.在双曲型方程组满足一些结构性的假设下,本文得到了两个收敛性的结果.对于大初值,本文证明了双曲型方程组在一个对松弛时间一致的时间区间上的收敛性,当初值在常数平衡态附近变化时,证明了光滑解关于时间的一致整体存在性和双曲型方程组的整体收敛性.本文也给出一些有物理背景的例子来作为这些结果的应用.     

非线性绝对值方程组的类SOR迭代方法

提出了非线性绝对值方程组(AVE)问题解的存在性和唯一性的一个充分条件,构建了数值求解方程组的类超松弛迭代方法,并证明其收敛性.数值算例表明该迭代方法是非常有效的.     

非光滑方程组牛顿法的全局收敛性分析

通过定义一种新的*-微分,本文给出了局部Lipschitz非光滑方程组的牛顿法,并对其全局收敛性进行了研究.该牛顿法结合了非光滑方程组的局部收敛性和全局收敛性.最后,我们把这种牛顿法应用到非光滑函数的光滑复合方程组问题上,得到了较好的收敛性.     

等熵气体动力学方程组Lax-Friedrichs格式的收敛性(Ⅰ)

§1引言 如所周知,Lax-Friedrichs格式是P.D.Lax对拟线性双曲型守恒律方程组提出的一种有限差分格式。若得到了其相应的差分逼近解的收敛性,这格式不仅提供了证明:整体广义解存在性的一种理想途径,而且能方便有效地直接用来进行整体解的数值计算。在单个守恒律方程情形,O.Oleinik,C.Conway and J.Smoller等证明了这一格式的收敛性,并得到了整体广义解的存在性。然而,对双曲型方程组,特别是气体动力学方程组,Lax-Friedrichs格式的收敛性一直没有什么结果。     

非光滑非线性互补问题的牛顿法

研究了非光滑的非线性互补问题. 首先将非光滑的非线性互补问题转化为一个非光滑方程组,然后用牛顿法求解这个非光滑方程组. 在该牛顿法中,每次迭代只需一个原始函数B-微分中的一个元素. 最后证明了该牛顿法的超线性收敛性.     

一类一维的辐射流体力学方程组激波的存在性

该文主要讨论一维空间中一类辐射流体力学方程组的激波. 由Rankine-Hugoniot条件及熵条件得此问题可表述为关于辐射流体力学方程组带自由边界的初边值问题. 首先通过变量代换, 将其自由边界转换为固定边界, 然后研究关于此非线性方程组的一个初边值问题解的存在唯一性. 为此先构造了此问题的一个近似解, 然后分别通过Picard迭代与Newton迭代对此非线性问题构造近似解序列. 通过一系列估计与紧性理论得到此近似解序列的收敛性, 其极限即为原辐射热力学方程组的一个激波.     

解非线性方程组松弛法的大范围收敛性

热知,松弛法是解多变量方程组的有效方法之一,它广泛用于求解由偏微分方程离散化导出的方程组。1962年与1963年S.Schechter与作者曾各自独立地研究并发表了解非线性方程组的逐步松弛法(SOR方法)的收敛性,作者还研究了其它松弛程序的收敛性并且给出了敛速估计,1968年S.Schechter也进一步研究了其它松弛程序并估计了收敛速度。前述结果以及后来其它工作均假定方程组具有连续的Jacobi矩阵存在(参考[4])。本文在不假定Jacobi矩阵存在的条件下建立了松弛法大范围收敛性理沦,证明SOR—Newton法,SOR—弦截法及SOR—Steffensen法的收敛性,并给出了敛速估计,从而扩大了这类方法的适用范围,利用所得到的结果解决了描写受控核反应方程的差分及有限元模拟的松弛法的收敛性。     

一类线性约束变分不等式问题的幂罚函数法

本文研究了一类线性约束变分不等式(Ⅵ)的幂罚函数法求解问题.利用Ⅵ的KKT条件,将Ⅵ转化为等价的混合互补问题和一个新的Ⅵ问题,并在一定条件下分析了解的存在性和唯一性.利用度理论证明了幂罚方程组解的存在性与唯一性.由以上结果最终证明了幂罚函数法的收敛性,即幂罚方程组的解收敛于Ⅵ问题的解.     

含参变量的三阶方向牛顿法及其收敛性

通过递推关系归纳迭代公式的讨论,研究含多个未知数的非光滑方程组及其收敛性,并以此证明希尔伯特空间上的含参变量的实系数非线性方程组的三阶方向牛顿法的半局部收敛性,给出解的存在性以及先验误差界.     

求解非线性方程组的L-M方法

本文研究了求解奇异非线性方程组的Levenberg-Marquardt方法的收敛性.利用选取新的迭代参数求解非线性方程组的L-M方法,获得点列的超线性收敛性和二阶收敛性,并把试验结果与文献[19,20]的结果进行了比较.     

New explicit approximate solution of MHD viscoelastic boundary layer flow over stretching sheet

In this paper, the study the momentum and heat transfer characteristics in an incompressible electrically conducting non‐Newtonian boundary layer flow of a viscoelastic fluid over a stretching sheet. The partial differential equations governing the flow and heat transfer characteristics are converted into highly nonlinear coupled ordinary differential equations by similarity transformations. The resultant coupled highly nonlinear ordinary differential equations are solved by means of, homotopy analysis method (HAM) for constructing an approximate solution of heat transfer in magnetohydrodynamic (MHD) viscoelastic boundary layer flow over a stretching sheet with non‐uniform heat source. The proposed method is a strong and easy to use analytic tool for nonlinear problems and does not need small parameters in the equations. The HAM solutions contain an auxiry parameter, which provides a convenient way of controlling the convergence region of series solutions. The results obtained here reveal that the proposed method is very effective and simple for solving nonlinear evolution equations. The method is straightforward and concise, and it can also be applied to other nonlinear evolution equations in physics. Copyright © 2012 John Wiley & Sons, Ltd.     

Global attractor for the Navier–Stokes equations with the heat convection in a cylindrical pipe

Global existence of regular solutions to the Navier–Stokes equations coupled with the heat convection in a cylindrical pipe has already been shown. In this paper, we prove the existence of the global attractor to the equations and convergence of their solutions to a stationary one. Copyright © 2012 John Wiley & Sons, Ltd.     

Approximate analytical solutions of reaction–diffusion equations with exponential source term: Homotopy perturbation method (HPM)

In this letter, the solutions of some nonlinear differential equations have been obtained by means of the homotopy perturbation method (HPM). Applications of the homotopy method to some nonlinear reaction–diffusion equations with exponential source term show rapid convergence of the sequence constructed by this method to the exact solutions.     

Global entropy solutions to a class of quasi-linear wave equations with large time-oscillating sources

This research explores the Cauchy problem for a class of quasi-linear wave equations with time dependent sources. It can be transformed into the Cauchy problem of hyperbolic integro-differential systems of nonlinear balance laws. We introduce the generalized Glimm scheme in new version and study its stability which is proved by Glimm-type interaction estimates in a dissipativity assumption. The generalized solutions to the perturbed Riemann problems, the building blocks of generalized Glimm scheme, are constructed by Riemann problem method modeled on the source free equations. The global existence for the Lipschitz continuous solutions and weak solutions to the systems is established by the consistency of scheme and the weak convergence of source. Finally, the weak solutions are also the entropy solutions which satisfy the entropy inequality.     

Convergence Rate to Stationary Solutions for Boltzmann Equation with External Force

For the Boltzmann equation with an external force in the form of the gradient of a potential function in space variable, the stability of its stationary solutions as local Maxwellians was studied by S. Ukai et al. (2005) through the energy method. Based on this stability analysis and some techniques on analyzing the convergence rates to stationary solutions for the compressible Navier-Stokes equations, in this paper, we study the convergence rate to the above stationary solutions for the Boltzmann equation which is a fundamental equation in statistical physics for non-equilibrium rarefied gas. By combining the dissipation from the viscosity and heat conductivity on the fluid components and the dissipation on the non-fluid component through the celebrated H-theorem, a convergence rate of the same order as the one for the compressible Navier-Stokes is obtained by constructing some energy functionals.     

Numerical solution of the heat equation by infinite-order ordinary differential equations

A numerical algorithm is given for solving a class of infinite-order differential equations previously discussed by the authors. These equations yield solutions to certain time-dependent boundary-value problems for the heat equation. An extrapolation process is given for increasing the speed of convergence of the sequence generated by the method. © 1992 John Wiley & Sons, Inc.     

GLOBAL EXISTENCE AND CONVERGENCE RATES OF SMOOTH SOLUTIONS FOR THE 3-D COMPRESSIBLE MAGNETOHYDRODYNAMIC EQUATIONS WITHOUT HEAT CONDUCTIVITY

In this paper, we are concerned with the global existence and convergence rates of the smooth solutions for the compressible magnetohydrodynamic equations without heat conductivity, which is a hyperbolic-parabolic system. The global solutions are obtained by combining the local existence and a priori estimates if H3-norm of the initial perturbation around a constant states is small enough and its L1-norm is bounded. A priori decay-in-time estimates on the pressure, velocity and magnetic field are used to get the uniform bound of entropy. Moreover, the optimal convergence rates are also obtained.     

The equations of motion of a collisionless continuum

The equations of motion of a collisionless continuum are derived within an Eulerian approach. They differ from the classical equations of motion of an ideal gas, which take into account heat conduction phenomena. Several problems related to the weak convergence of the solutions of the equations of motion of a continuum when there is an unbounded increase in time are discussed. The problem of the correctness of the operation of truncating the exact infinite chain of equations of a collisionless gas is examined.     

Parameter identification in nonlocal nonlinear evolution equations

We develop an approximation framework for identifying parameters in a general class of nonautonomous, nonlocal and nonlinear evolution equations. After establishing existence and uniqueness of solutions, we present a convergence theory for Galerkin approximations to inverse problems involving these equations. Our approach relies on the theory of maximal monotone operators in Banach spaces. An application to a nonautonomous nonlinear integral equation arising in heat flow is also discussed.     

Analytic approximate solutions for heat transfer of a micropolar fluid through a porous medium with radiation

This paper aims to present complete analytic solution to heat transfer of a micropolar fluid through a porous medium with radiation. Homotopy analysis method (HAM) has been used to get accurate and complete analytic solution. The analytic solutions of the system of nonlinear ordinary differential equations are constructed in the series form. The convergence of the obtained series solutions is carefully analyzed. The velocity and temperature profiles are shown and the influence of coupling constant, permeability parameter and the radiation parameter on the heat transfer is discussed in detail. The validity of our solutions is verified by the numerical results (fourth-order Runge–Kutta method and shooting method).