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A connection formula for the second Painlevé transcendent (1988)

Clarkson, Peter A. ; McLeod, J. Bryce

Springer

Archive for rational mechanics and analysis 103 (1988), S. 97-138

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ISSN: 1432-0673

Source: Springer Online Journal Archives 1860-2000

Topics: Mathematics , Physics

Notes: Abstract We consider the second Painlevé transcendent $$\frac{{d^2 y}}{{dx^2 }} = xy + 2y^3 .$$ It is known that if y(x) ∼ k Ai (x) as x → + ∞, where −1〈k〈1 and Ai (x) denotes Airy's function, then $$y(x) \sim d|x|^{ - \tfrac{1}{4}} sin\{ \tfrac{2}{3}|x|^{\tfrac{3}{2}} - \tfrac{3}{4}d^2 1n|x| - c\} ,$$ where the constants d, c depend on k. This paper shows that $$d^2 = \pi ^{ - 1} 1n(1 - k^2 )$$ , which confirms a conjecture by Ablowitz & Segur.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00251504

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Application of Uniform Asymptotics to the Second Painlevé Transcendent (1998)

Bassom, Andrew P. ; Clarkson, Peter A. ; Law, C. K. ; [et al.]

Springer

Archive for rational mechanics and analysis 143 (1998), S. 241-271

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ISSN: 1432-0673

Source: Springer Online Journal Archives 1860-2000

Topics: Mathematics , Physics

Notes: Abstract. In this work we propose a new method for investigating connection problems for the class of nonlinear second‐order differential equations known as the Painlevé equations. Such problems can be characterized by the question as to how the asymptotic behaviours of solutions are related as the independent variable is allowed to pass towards infinity along different directions in the complex plane. Connection problems have been previously tackled by a variety of methods. Frequently these are based on the ideas of isomonodromic deformation and the matching of WKB solutions. However, the implementation of these methods often tends to be heuristic in nature and so the task of rigorising the process is complicated. The method we propose here develops uniform approximations to solutions. This removes the need to match solutions, is rigorous, and can lead to the solution of connection problems with minimal computational effort. Our method relies on finding uniform approximations of differ ential equations of the generic form $$ \frac{{\text d}^2\phi}{{\text d}\eta^2} = - \xi^2F(\eta,\xi)\phi $$ as the complex‐valued parameter $\xi \to \infty$ . The details of the treatment rely heavily on the locations of the zeros of the function F in this limit. If they are isolated, then a uniform approximation to solutions can be derived in terms of Airy functions of suitable argument. On the other hand, if two of the zeros of F coalesce as $|\xi| \to \infty$ , then an approximation can be derived in terms of parabolic cylinder functions. In this paper we discuss both cases, but illustrate our technique in action by applying the parabolic cylinder case to the “classical” connection problem associated with the second Painlevé transcendent. Future papers will show how the technique can be applied with very little change to the other Painlevé equations, and to the wider problem of the asymptotic behavio ur of the general solution to any of these equations.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s002050050105

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