Non-linear blow-up problems for systems of ODEs and PDEs: Non-local transformations, numerical and exact solutions

In Cauchy problems with blow-up solutions there exists a singular point whose position is unknown a priori (for this reason, the application of standard fixed-step numerical methods for solving such problems can lead to significant errors). In this paper, we describe a method for numerical integrati...

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Bibliographic Details
Published in:International journal of non-linear mechanics 2019-05, Vol.111, p.28-41
Main Authors: Polyanin, Andrei D., Shingareva, Inna K.
Format: Article
Language:English
Subjects:
Blow-up problems
Blowing
Boundary value problems
Conduction heating
Exact solutions
Independent variables
Linear systems
Method of lines
Methods
Non-linear partial differential equations
Non-local transformations
Nonlinear differential equations
Nonlinear equations
Nonlinear systems
Numerical analysis
Numerical and exact solutions
Numerical integration
Numerical methods
Ordinary differential equations
Partial differential equations
Systems of ordinary differential equations
Transformations (mathematics)
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Summary:In Cauchy problems with blow-up solutions there exists a singular point whose position is unknown a priori (for this reason, the application of standard fixed-step numerical methods for solving such problems can lead to significant errors). In this paper, we describe a method for numerical integration of blow-up problems for non-linear systems of coupled ordinary differential equations of the first order (xm)t′=fm(t,x1,…,xn), m=1,…,n, based on the introduction a new non-local independent variable  ξ, which is related to the original variables t and x1,…,xn by the equation ξt′=g(t,x1,…,xn,ξ). With a suitable choice of the regularizing function  g, the proposed method leads to equivalent problems whose solutions are represented in parametric form and do not have blowing-up singular points; therefore, the transformed problems admit the use of standard numerical methods with a fixed stepsize in ξ. Several test problems are formulated for systems of ordinary differential equations that have monotonic and non-monotonic blow-up solutions, which are expressed in elementary functions. Comparison of exact and numerical solutions of test problems showed the high efficiency of numerical methods based on non-local transformations of a special kind. The qualitative features of numerical integration of blow-up problems for single ODEs of higher orders with the use of non-local transformations are described. The efficiency of various regularizing functions is compared. It is shown that non-local transformations in combination with the method of lines can be successfully used to integrate initial–boundary value problems, described by non-linear parabolic and hyperbolic PDEs, that have blow-up solutions. We consider test problems (admitting exact solutions) for nonlinear partial differential equations such as equations of the heat-conduction type and Klein–Gordon type equations, in which the blowing-up occurs both in an isolated point of space x=x∗, and on the entire range of variation of the space variable 0≤x≤1. The results of numerical integration of test problems, obtained when approximating PDEs by systems with a different number of coupled ODEs, are compared with exact solutions. •Blow-up problems for systems ODEs are considered.•Blow-up problems for non-linear PDEs are studied.•Non-local transformations are used.•Exact solutions for test problems are given.•Numerical solutions of blow-up problems are presented.
ISSN:0020-7462
1878-5638
DOI:10.1016/j.ijnonlinmec.2019.01.012