A simple spatial integration scheme for solving Cauchy problems of non-linear evolution equations

被引:0
作者
Chang, Chih-Wen [1 ]
Liu, Chein-Shan [2 ,3 ]
Chang, Jiang-Ren [4 ]
Chen, Han-Taw [5 ]
机构
[1] Feng Chia Univ, Dept Mech & Comp Aided Engn, Taichung, Taiwan
[2] Hohai Univ, Coll Mech & Mat, Ctr Numer Simulat Software Engn & Sci, Nanjing, Jiangsu, Peoples R China
[3] Natl Taiwan Ocean Univ, Dept Mech & Mechatron Engn, Keelung, Taiwan
[4] Natl Taiwan Ocean Univ, Dept Syst Engn & Naval Architecture, Keelung, Taiwan
[5] Natl Cheng Kung Univ, Dept Mech Engn, Tainan, Taiwan
来源
INVERSE PROBLEMS IN SCIENCE AND ENGINEERING | 2017年 / 25卷 / 11期
关键词
Non-linear evolution equation; severely ill-posed problem; Cauchy problem; group preserving scheme (GPS); without initial condition; BURGERS-HUXLEY EQUATION; FITZHUGH-NAGUMO EQUATION; GROUP SHOOTING METHOD; GROUP PRESERVING SCHEME; ORDINARY DIFFERENTIAL-EQUATIONS; HEAT-CONDUCTION PROBLEMS; FIELD TRANSITION SYSTEM; QUASI-BOUNDARY REGULARIZATION; TIME-DEPENDENT COEFFICIENTS; TRAVELING-WAVE SOLUTIONS;
D O I
10.1080/17415977.2017.1281271
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
In this study, we address a new and simple non-iterative method to solve Cauchy problems of non-linear evolution equations without initial data. To start with, these ill-posed problems are analysed by utilizing a semi-discretization numerical scheme. Then, the resulting ordinary differential equations at the discretized times are numerically integrated towards the spatial direction by the group-preserving scheme (GPS). After that, we apply a two-stage GPS to integrate the semi-discretized equations. We reveal that the accuracy and stability of the new approach is very good from several numerical experiments even under a large random noisy effect and a very large time span.
引用
收藏
页码:1653 / 1675
页数:23
相关论文
共 82 条
[1]  
Aasaraai A., 2011, MIDDLE E J SCI RES, V10, P270
[2]   Soliton solutions for the Fitzhugh-Nagumo equation with the homotopy analysis method [J].
Abbasbandy, S. .
APPLIED MATHEMATICAL MODELLING, 2008, 32 (12) :2706-2714
[3]   Analytic and approximate solutions for Nagumo telegraph reaction diffusion equation [J].
Abdusalam, HA .
APPLIED MATHEMATICS AND COMPUTATION, 2004, 157 (02) :515-522
[4]  
Aminikhah H, 2015, IRAN J NUMER ANAL OP, V5, P63
[5]   Numerical approximation for the phase-field transition system [J].
Arnautu, V ;
Morosanu, C .
INTERNATIONAL JOURNAL OF COMPUTER MATHEMATICS, 1996, 62 (3-4) :209-221
[6]   MULTIDIMENSIONAL NON-LINEAR DIFFUSION ARISING IN POPULATION-GENETICS [J].
ARONSON, DG ;
WEINBERGER, HF .
ADVANCES IN MATHEMATICS, 1978, 30 (01) :33-76
[7]   Analytic approximate solutions to Burgers, Fisher, Huxley equations and two combined forms of these equations [J].
Babolian, E. ;
Saeidian, J. .
COMMUNICATIONS IN NONLINEAR SCIENCE AND NUMERICAL SIMULATION, 2009, 14 (05) :1984-1992
[8]   Numerical simulation of the generalized Huxley equation by He's variational iteration method [J].
Batiha, B. ;
Noorani, M. S. M. ;
Hashim, I. .
APPLIED MATHEMATICS AND COMPUTATION, 2007, 186 (02) :1322-1325
[9]   Fractional Steps Scheme to Approximate the Phase-Field Transition System with Non-Homogeneous Cauchy-Neumann Boundary Conditions [J].
Benincasa, T. ;
Morosanu, C. .
NUMERICAL FUNCTIONAL ANALYSIS AND OPTIMIZATION, 2009, 30 (3-4) :199-213
[10]  
Benincasa T., 2010, ROMAI J., V6, P15
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