非线性抛物型方程的变网格有限元法

Three linear finite element schemes with moving mesh are established for a class of nonlinear parabolic equations.Optimal L^2-norm and energy norm error estimates are derived under certain conditions.     

数值积分对完全非线性抛物型积分微分方程有限元方法的影响*

抛物型积分微分方程在带有记忆性的热传导 ,扩散 ,生物力学等实际问题中有广泛的应用 本文考虑如下模型 :ｃ(ｘ ,ｕ) ｔ = · {ａ(ｘ ,ｕ) ｕ + ∫ｔ0 ｂ(ｘ ,ｔ,τ ,ｕ(ｘ ,τ) ) ｕ(ｘ ,τ)ｄτ}+ ｆ(ｘ ,ｔ ,ｕ)　　　　　　　　　　　　　　　　 (ｘ ,ｔ) ∈Ω× [0 ,Ｔ]ｕ(ｘ ,ｔ) =0 ,　　 (ｘ ,ｔ)∈ Ω× [0 ,Ｔ]ｕ(ｘ ,0 ) =ｕ0 (ｘ) ,　　ｘ ∈Ω ,其中Ω Ｒｎ 为多角型区域 , Ω为边界 不用数值积分 ,对这类问题有限元方法研究已有很多工作[5 -8,11] ,导出了最优Ｌ2 及Ｈ1模估计 众所周知 ,解偏微分方程的有限元方法最终…     

非线性退化抛物型方程

In this paper we study a nonliner degenerate parabolic equation for the second boundary value problem.using the method of regularity we prove the existence and uniqueness of weak solution.     

一类非线性抛物型方程组的交替方向变网格有限元方法

本文对一类非线性抛物型方程组提出并分析了一类全离散交替方向变网格有限元格式，且在相当一般的情况下得到了最佳的L^2模误差估计。     

非线性抛物型方程的爆破

本文考虑非线性抛物型方程ｕｔ＝ｅ＾ｕ（△ｕ＋ｕ），ｘ∈Ω，证明在Ω上当－△ｕ＝λｕ的第一特征值λ１（Ω）〈１时，解ｕ有有限时刻爆破。     

完全非线性抛物型方程的整体解

本文所研究的是下列完全非线性抛物型方程的整体解:u_t=Δu+f(u,Du,D~2u),u(0)=u_0,其中,f∈C~(1+r),r>2/n,u_0属于介于 W_1~2(R~n)∩C~2(R~n)与 W_1~3(R~n)∩C~3(R~n) 间的中间空间,且充分小.从而推广了以往相应的工作.     

二阶完全非线性抛物型方程的周期解

证明了二阶完全非线性抛物型方程周期粘性解的存在唯一性，在标准假设下解决了非线性抛物型方程古典周期解的存在唯一性问题。     

非线性抛物型偏积分微分方程的H1-Galerkin 混合有限元方法

收稿给出一类非线性抛物型偏积分微分方程的H1-Galerkin混合有限元方法.给出了一维空间的半离散、全离散格式及最优阶误差估计,并将该方法推广到二维和三维空间.     

Error estimates for a finite volume element method for parabolic equations in convex polygonal domains

We analyze the spatially semidiscrete piecewise linear finite volume element method for parabolic equations in a convex polygonal domain in the plane. Our approach is based on the properties of the standard finite element Ritz projection and also of the elliptic projection defined by the bilinear form associated with the variational formulation of the finite volume element method. Because the domain is polygonal, special attention has to be paid to the limited regularity of the exact solution. We give sufficient conditions in terms of data that yield optimal order error estimates in L₂ and H 1 . The convergence rate in the L_∞ norm is suboptimal, the same as in the corresponding finite element method, and almost optimal away from the corners. We also briefly consider the lumped mass modification and the backward Euler fully discrete method. © 2004 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq, 2004     

A Symmetric Characteristic Finite Volume Element Scheme for Nonlinear Convection-Diffusion Problems

In this paper, we implement alternating direction strategy and construct a symmetric FVE scheme for nonlinear convection-diffusion problems. Comparing to general FVE methods, our method has two advantages. First, the coefficient matrices of the discrete schemes will be symmetric even for nonlinear problems. Second, since the solution of the algebraic equations at each time step can be inverted into the solution of several one-dimensional problems, the amount of computation work is smaller. We prove the optimal H1-norm error estimates of order O（△t2 ＋ h） and present some numerical examples at the end of the paper.     

Adaptive finite element methods for Boussinesq equations

An a posteriori error analysis for Boussinesq equations is derived in this article. Then we compare this new estimate with a previous one developed for a regularized version of Boussinesq equations in a previous work. © 2000 John Wiley & Sons, Inc. Numer Methods Partial Differential Eq 16: 214–236, 2000     

Weak Galerkin finite element methods for linear parabolic integro‐differential equations

The semidiscrete and fully discrete weak Galerkin finite element schemes for the linear parabolic integro‐differential equations are proposed. Optimal order error estimates are established for the corresponding numerical approximations in both and norms. Numerical experiments illustrating the error behaviors are provided.© 2016 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq 32: 1357–1377, 2016     

Mortar element methods for parabolic problems

In this article a standard mortar finite element method and a mortar element method with Lagrange multiplier are used for spatial discretization of a class of parabolic initial‐boundary value problems. Optimal error estimates in L^∞(L²) and L^∞(H¹)‐norms for semidiscrete methods for both the cases are established. The key feature that we have adopted here is to introduce a modified elliptic projection. In the standard mortar element method, a completely discrete scheme using backward Euler scheme is discussed and optimal error estimates are derived. The results of numerical experiments support the theoretical results obtained in this article. © 2008 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq 2008     

A posteriori error estimates of mixed DG finite element methods for linear parabolic equations

In this article, we analyse a posteriori error estimates of mixed finite element discretizations for linear parabolic equations. The space discretization is done using the order λ?≥?1 Raviart–Thomas mixed finite elements, whereas the time discretization is based on discontinuous Galerkin (DG) methods (r?≥?1). Using the duality argument, we derive a posteriori l ^∞(L ²) error estimates for the scalar function, assuming that only the underlying mesh is static.     

Weak Galerkin finite element methods combined with Crank-Nicolson scheme for parabolic interface problems

This article is devoted to the a priori error estimates of the fully discrete Crank-Nicolson approximation for the linear parabolic interface problem via weak Galerkin finite element methods (WG-FEM). All the finite element functions are discontinuous for which the usual gradient operator is implemented as distributions in properly defined spaces. Optimal order error estimates in both $L^{\infty}(H^1)$ and $L^{\infty}(L^2)$ norms are established for lowest order WG finite element space $({\cal P}_{k}(K),\;{\cal P}_{k-1}(\partial K),\;\big[{\cal P}_{k-1}(K)\big]^2)$. Finally, we give numerical examples to verify the theoretical results.     

Immersed finite element methods for parabolic equations with moving interface

This article presents three Crank‐Nicolson‐type immersed finite element (IFE) methods for solving parabolic equations whose diffusion coefficient is discontinuous across a time dependent interface. These methods can use a fixed mesh because IFEs can handle interface jump conditions without requiring the mesh to be aligned with the interface. These methods will be compared analytically in the sense of accuracy and computational cost. Numerical examples are provided to demonstrate features of these three IFE methods. © 2012 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq, 2013     

Error estimates for finite volume element methods for general second‐order elliptic problems

We treat the finite volume element method (FVE) for solving general second order elliptic problems as a perturbation of the linear finite element method (FEM), and obtain the optimal H¹ error estimate, H¹ superconvergence and L^p (1 < p ≤ ∞) error estimates between the solution of the FVE and that of the FEM. In particular, the superconvergence result does not require any extra assumptions on the mesh except quasi‐uniform. Thus the error estimates of the FVE can be derived by the standard error estimates of the FEM. Moreover we consider the effects of numerical integration and prove that the use of barycenter quadrature rule does not decrease the convergence orders of the FVE. The results of this article reveal that the FVE is in close relationship with the FEM. © 2003 Wiley Periodicals, Inc. Numer Methods Partial Differential Eq 19: 693–708, 2003.