Solving Fourth-Order PDEs using the LMAPS

被引:2
|
作者
Deng, Cheng [1 ]
Zheng, Hui [1 ,2 ]
Shi, Yan [3 ]
Chen, C. S. [1 ,4 ]
机构
[1] Nanchang Univ, Sch Civil Engn & Architecture, Nanchang 330031, Jiangxi, Peoples R China
[2] Commun Design & Res Inst Co Ltd Jiangxi Prov, Nanchang 330052, Jiangxi, Peoples R China
[3] Nanchang Univ, Stomatol Hosp, Dept Conservat Dent & Endodont, Jiangxi Prov Key Lab Oral Biol, Nanchang 330006, Jiangxi, Peoples R China
[4] Univ Southern Mississippi, Sch Math & Nat Sci, Hattiesburg, MS 39406 USA
来源
ADVANCES IN APPLIED MATHEMATICS AND MECHANICS | 2020年 / 12卷 / 04期
基金
美国国家科学基金会;
关键词
Localized method of approximate particular solutions; Helmholtz-type operator; fourth-order partial differential equation; polynomial basis functions; polyharmonic splines of RBFs; APPROXIMATE PARTICULAR SOLUTIONS; PARTIAL-DIFFERENTIAL-EQUATIONS; FINITE-ELEMENT-METHOD; BIHARMONIC EQUATION; SCHEME;
D O I
10.4208/aamm.OA-2019-0216
中图分类号
O29 [应用数学];
学科分类号
070104 ;
摘要
To overcome the difficulty for solving fourth order partial differential equations (PDEs) using localized methods, we introduce and extend a recent method to decompose the particular solution of such equation into particular solutions of two second-order differential equations using radial basis functions (RBFs). In this way, the localized method of approximate particular solutions (LMAPS) can be used to directly solve a fourth-order PDE without splitting it into two second-order problems. The closed-form particular solutions for polyharmonic splines RBFs augmented with polynomial basis functions for Helmholtz-type equations are the cores of the solution process. Several novel techniques are proposed to further improve the accuracy and efficiency. Four numerical examples are presented to show the effectiveness of our approach.
引用
收藏
页码:920 / 939
页数:20
相关论文
共 50 条
  • [1] The LMAPS for solving fourth -order PDEs with polynomial basis functions
    Chen, C. S.
    Shen, Shu-Hui
    Dou, Fangfang
    Li, J.
    [J]. MATHEMATICS AND COMPUTERS IN SIMULATION, 2020, 177 : 500 - 515
  • [2] Image denoising by fourth-order PDEs
    Kim, Seongjai
    [J]. PROCEEDINGS OF THE EIGHTH IASTED INTERNATIONAL CONFERENCE ON SIGNAL AND IMAGE PROCESSING, 2006, : 249 - 254
  • [3] Fourth-Order Difference Scheme and a Matrix Transform Approach for Solving Fractional PDEs
    Salman, Zahrah I.
    Kajani, Majid Tavassoli
    Mechee, Mohammed Sahib
    Allame, Masoud
    [J]. MATHEMATICS, 2023, 11 (17)
  • [4] Two Efficient Methods For Solving Non-linear Fourth-Order PDEs
    Altaie, Huda Omran
    [J]. INTERNATIONAL JOURNAL OF NONLINEAR ANALYSIS AND APPLICATIONS, 2020, 11 : 543 - 546
  • [5] EXISTENCE OF SOLUTIONS FOR FOURTH-ORDER PDES WITH VARIABLE EXPONENTS
    El Amrouss, Abdelrachid
    Moradi, Fouzia
    Moussaoui, Mimoun
    [J]. ELECTRONIC JOURNAL OF DIFFERENTIAL EQUATIONS, 2009,
  • [6] Fourth-order time-stepping for stiff PDEs
    Kassam, AK
    Trefethen, LN
    [J]. SIAM JOURNAL ON SCIENTIFIC COMPUTING, 2005, 26 (04): : 1214 - 1233
  • [7] MADM For Solving Fourth-Order ODE
    Kamaruddin, Anis N.
    Mohamad, Mahathir
    Sufahani, Suliadi
    Khalid, Kamil
    Rusiman, Mohd Saifullah
    Kamardan, M. Ghazali
    [J]. INTERNATIONAL SEMINAR ON MATHEMATICS AND PHYSICS IN SCIENCES AND TECHNOLOGY 2017 (ISMAP 2017), 2018, 995
  • [8] The local meshless method based on Pascal polynomial basis functions for solving fourth-order PDEs
    Chang, Wanru
    Zhang, Jianfeng
    Wang, Yun
    Wang, Jiawen
    [J]. ENGINEERING ANALYSIS WITH BOUNDARY ELEMENTS, 2022, 140 : 159 - 166
  • [9] Image Restoration Combining the Second-Order and Fourth-Order PDEs
    Liu, Tianhua
    Xiang, Zhaoyin
    [J]. MATHEMATICAL PROBLEMS IN ENGINEERING, 2013, 2013
  • [10] Fourth-Order Pattern Forming PDEs: Partial and Approximate Symmetries
    Jamal, Sameerah
    Johnpillai, Andrew G.
    [J]. MATHEMATICAL MODELLING AND ANALYSIS, 2020, 25 (02) : 198 - 207
12345