一类偏积分微分方程二阶差分全离散格式

本文给出了数值求解一类偏积分微分方程的二阶差分全离散格式．时间方向采用了二阶向后差分格式,积分项的离散利用了Lubich的二阶卷积求积公式,给出了稳定性的证明、误差估计及收敛性的结果,并给出了数值例子．     

一类偏积分微分方程二阶差分全离散格式

本给出了数值求解一类偏积分微分方程的二阶全离散差分格式．采用了Crank-Nicolson格式；积分项的离散利用了Lubieh的二阶卷积积分公式；给出了稳定性的证明，误差估计及收敛性的结果．     

一类非线性偏积分微分方程二阶差分全离散格式

给出了数值求解一类非线性偏积分微分方程的二阶全离散差分格式.采用了二阶向后差分格式,积分项的离散利用了Lubich的二阶卷积求积公式,给出了稳定性的证明、误差估计及收敛性的结果.     

一类偏积分微分方程二阶差分空间半离散格式的全局行为

偏积分微分方程产生于许多科学与工程领域,数值求解此类问题具有重要应用.本文给出了数值求解一类长时间偏积分微分方程的二阶差分空间半离散格式.借助于Laplace变换及Parseval等式,给出了全局稳定性的证明、误差估计及全局收敛性的结果.     

一类带弱奇异核偏积分微分方程二阶差分空间半离散格式的全局稳定性

本文给出了数值求解一类带弱奇异核偏积分微分方程的二阶差分空间半离散格式;借助于Laplace变换及Parseval等式,得到了全局稳定性的证明.     

一类带有黎曼边界条件的时间分数阶积分微分方程的紧差分格式（英文）

本文研究带黎曼边界条件的时间分数阶积分微分方程的数值方法.将L1离散公式逼近Caputo分数阶导数,加权带位移的Grünwald公式逼近Riemann-Liouville分数阶积分及其紧差分逼近空间二阶导数结合起来,建立一种求解该方程的差分格式并对其进行分析.尽管黎曼边界条件使得边界上的截断误差会比内部网格点的截断误差低一阶,本文仍严格证明格式是无条件稳定且全局收敛精度为O(τ^2-α+h⁴).最后,本文进行数值实验来验证理论结果.     

一类非线性延迟抛物偏微分方程的紧致差分格式

对于一类带有Dirichlet边界条件的延迟非线性抛物型偏微分方程的初边值问题建立了一个紧差分格式,用能量分析法证明该差分格式在L_∞范数下是无条件收敛的,且收敛阶为O(τ~2+h~4).最后,通过数值算例验证了理论结果.     

一类带弱奇异核非线性偏积分微分方程的全离散有限元

1引言我们将研究下面一类带弱奇异核非线性偏积分微分方程的数值解:u_t-▽·(a(u)▽u)-integral from n=0 to tβ(t-s)△u(s)ds=f(u),x∈Ω,t∈(?),(1.1) u(·,t)=0,x∈(?)Ω,t∈J,(1.2) u(·,0)=v(x),x∈Ω,(1.3)其中Ω为平面上的凸角域,J=(0,T],α和f为R上的光滑函数,满足0相似文献   

一类四阶抛物积分微分方程混合元方法的超收敛分析

本文的主要目的是利用双线性元Q_(11)及Q_(01)×Q_(10)元研究一类非线性四阶抛物积分微分方程的混合有限元方法.一方面,利用上述两种元的高精度结果以及对时间t的导数转移技巧,在半离散格式下,导出原始变量u和中间变量w=-?u在H~1-模意义下及流量p(向量)=-?u在(L~2)~2-模意义下具有O(h~2)阶的超逼近性质.进一步地,借助插值后处理技术,得到上述变量的整体超收敛结果.另一方面,建立一个新的向后Euler全离散格式.通过采取新的分裂技术,得到u和w在H~1-模意义下及p在(L~2)~2-模意义下具有O(h~2+?t)阶的超逼近和超收敛结果.这里,h和?t分别表示空间剖分参数和时间步长.最后,给出一个数值算例,计算结果验证了理论分析的正确性.     

A finite difference scheme for the nonlinear time-fractional partial integro-differential equation

In this paper, a finite difference scheme is proposed for solving the nonlinear time-fractional integro-differential equation. This model involves two nonlocal terms in time, ie, a Caputo time-fractional derivative and an integral term with memory. The existence of numerical solutions is shown by the Leray-Schauder theorem. And we obtain the discrete L₂ stability and convergence with second order in time and space by the discrete energy method. Then the uniqueness of numerical solutions is derived. Moreover, an iterative algorithm is designed for solving the derived nonlinear system. Numerical examples are presented to validate the theoretical findings and the efficiency of the proposed algorithm.     

A compact finite difference scheme for the fourth-order time-fractional integro-differential equation with a weakly singular kernel

In this paper, a compact finite difference scheme is constructed and investigated for the fourth-order time-fractional integro-differential equation with a weakly singular kernel. In the temporal direction, the Caputo derivative term is treated by means of L₁ discrete formula and the Riemann–Liouville fractional integral term is discretized by the second-order convolution quadrature rule. A fully discrete compact difference scheme is constructed with the space discretization by the fourth-order compact approximation. The stability and convergence are obtained by the discrete energy method, the Cholesky decomposition and the reduced-order method. Numerical experiments are presented to verify the theoretical analysis.     

非定常Burgers方程基于POD方法的全二阶差分格式降阶外推算法

利用特征投影分解方法和奇值分解技术对非定常Burgers 方程的经典全二阶有限差分格式做降阶处理, 给出一种时间和空间变量都是二阶精度的降阶差分格式, 并给出这种降阶全二阶精度差分解的误差估计和外推算法的实现, 最后用数值例子说明数值结果与理论结果是相吻合的.     

A fast second‐order difference scheme for the space–time fractional equation

In this paper, a fast second‐order accurate difference scheme is proposed for solving the space–time fractional equation. The temporal Caputo derivative is approximated by ?L2 ‐1_σ formula which employs the sum‐of‐exponential approximation to the kernel function appeared in Caputo derivative. The second‐order linear spline approximation is applied to the spatial Riemann–Liouville derivative. At each time step, a fast algorithm, the preconditioned conjugate gradient normal residual method with a circulant preconditioner (PCGNR), is used to solve the resulting system that reduces the storage and computational cost significantly. The unique solvability and unconditional convergence of the difference scheme are shown by the discrete energy method. Numerical examples are given to verify numerical accuracy and efficiency of the difference schemes.     

A study on a second order finite difference scheme for fractional advection–diffusion equations

Second order finite difference schemes for fractional advection–diffusion equations are considered in this paper. We note that, when studying these schemes, advection terms with coefficients having the same sign as those of diffusion terms need additional estimates. In this paper, by comparing generating functions of the corresponding discretization matrices, we find that sufficiently strong diffusion can dominate the effects of advection. As a result, convergence and stability of schemes are obtained in this situation.