Painlevé Equations: Continuous, Discrete and Ultradiscrete

doi:10.1017/CBO9780511997136.004

2 - Painlevé Equations: Continuous, Discrete and Ultradiscrete

Published online by Cambridge University Press: 05 July 2011

Basil Grammaticos and

Alfred Ramani

Edited by

Decio Levi ,

Peter Olver ,

Zora Thomova and

Pavel Winternitz

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Basil Grammaticos: Affiliation:
Université Paris
Alfred Ramani: Affiliation:
Centre de Physique Théorique, École Polytechnique
Decio Levi: Affiliation:
Università degli Studi Roma Tre
Peter Olver: Affiliation:
University of Minnesota
Zora Thomova: Affiliation:
SUNY Institute of Technology
Pavel Winternitz: Affiliation:
Université de Montréal

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Summary

Abstract

We present a derivation of the continuous and discrete Painlevé equations and then proceed to establish a parallel between the special properties these equations possess, and which are related to their integrable character. The ultradiscrete forms of Painlevé equations are then derived and we show that their properties follow closely the ones of their continuous and discrete counterparts.

Introduction

Deriving integrable systems is a (very) delicate business. In the absence of a general, constructive theory the usual approach to discovering new integrable equations is to try to construct specific examples. Sometimes they are suggested by physical models, the KdV equation being the prototype of such a system. Once a sufficient number of examples are obtained one can formulate conjectures and proceed to propose integrability criteria. Painlevé equations are a minor exception to this approach. Their discovery is due to the inspired intuition of Painlevé [23]. He was faced with the problem of defining new functions from the solutions of differential equations, a challenge set by Picard [25], who thought that this would have been impossible for second-order equations. This pessimistic attitude was due to the fact that nonlinear differential equations possess multivaluedness-inducing singularities, the position of which depends on the initial conditions, thus making impossible any uniformisation treatment. The masterful solution of Painlevé was to look only for equations free of these “bad” singularities.

Type: Chapter
Information: Symmetries and Integrability of Difference Equations , pp. 50 - 82

DOI: https://doi.org/10.1017/CBO9780511997136.004 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

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References

[1] Ablowitz, M. J., Ramani, A., and Segur, H. 1978. Nonlinear evolution equations and ordinary differential equations of Painlevé type. Lett. Nuovo Cimento (2), 23(9), 333–338.CrossRef Google Scholar

[2] Bureau, F. J. 1964. Differential equations with fixed critical points. Ann. Mat. Pura Appl. (4), 64, 229–364.CrossRef Google Scholar

[3] Bureau, F. J. 1972. Équations différentielles du second ordre en Y et du second degré en ÿ dont l'intégrale générale est à points critiques fixes. Ann. Mat. Pura Appl. (4), 91, 163–281.CrossRef Google Scholar

[4] Fokas, A. S., and Ablowitz, M. J. 1982. On a unified approach to transformations and elementary solutions of Painlevé equations. J. Math. Phys., 23, 2033–2042.CrossRef Google Scholar

[5] Fokas, A. S., Grammaticos, B., and Ramani, A. 1993. From continuous to discrete Painlevé equations. J. Math. Anal. Appl., 180(2), 342–360.CrossRef Google Scholar

[6] Gambier, B. 1910. Sur les équations différentielles du second ordre et du premier degré dont l'intégrale générale est à points critiques fixes. Acta Math., 33(1), 1–55.CrossRef Google Scholar

[7] Grammaticos, B., and Ramani, A. 2000. The hunting for the discrete Painlevé equations. Sophia Kovalevskaya to the 150th anniversary. Regul. Chaotic Dyn., 5(1), 53–66.CrossRef Google Scholar

[8] Grammaticos, B., Ramani, A., and Papageorgiou, V. 1991. Do integrable mappings have the Painlevé property? Phys. Rev. Lett., 67(14), 1825–1828.CrossRef Google Scholar PubMed

[9] Grammaticos, B., Ohta, Y., Ramani, A., and Takahashi, D. 1998. The ultimate discretisation of the Painlevé equations. Phys. D, 114(3-4), 185–196.Google Scholar

[10] Gromak, V. A., and Lukashevich, N. A. 1990. Analytic Properties of Solutions of Painlevé Equations. Minsk: Universitetskoye. in Russian.Google Scholar

[11] Hietarinta, J., and Viallet, C. M. 1998. Singularity confinement and chaos in discrete systems. Phys. Rev. Lett., 81(2), 325–328.CrossRef Google Scholar

[12] Ince, E. L. 1944. Ordinary Differential Equations. New York: Dover.Google Scholar

[13] Jimbo, M., and Miwa, T. 1981. Monodromy preserving deformation of linear ordinary differential equations with rational coefficients. II. Phys. D, 2(11), 407–448.CrossRef Google Scholar

[14] Jimbo, M., and Sakai, H. 1996. A q-analog of the sixth Painlevé equation. Lett. Math. Phys., 38(2), 145–154.CrossRef Google Scholar

[15] Joshi, N., Nijhoff, F. W., and Ormerod, C. 2004. Lax pairs for ultra-discrete Painlevé cellular automata. J. Phys. A, 37(44), L559–L565.CrossRef Google Scholar

[16] Kruskal, M. D. 2000. Private communication.

[17] Malmquist, J. 1922. Sur les équations différentielles du second ordre dont l'intégrale générale a ses points critiques fixes. Ark. Mat. Astr. Fys., 17(8), 1–89.Google Scholar

[18] Nijhoff, F., Satsuma, J., Kajiwara, K., Grammaticos, B., and Ramani, A. 1996. A study of the alternate discrete Painlevé II equation. Inverse Problems, 12(5), 697–716.CrossRef Google Scholar

[19] Ohta, Y., Tamizhmani, K. M., Grammaticos, B., and Ramani, A. 1999. Singularity confinement and algebraic entropy: the case of the discrete Painlevé equations. Phys. Lett. A, 262(2-3), 152–157.CrossRef Google Scholar

[20] Ohta, Y., Ramani, A., and Grammaticos, B. 2002. Elliptic discrete Painlevé equations. J. Phys. A, 35(45), L653–L659.CrossRef Google Scholar

[21] Okamoto, K. 1979. Sur les feuilletages associés aux équations du second ordre à points critiques fixes de P. Painlevé. Japan. J. Math. (N. S.), 5(1), 1–79.CrossRef Google Scholar

[22] Okamoto, K. 1981. On the τ-function of the Painlevé equations. Phys. D, 2(3), 525–535.CrossRef Google Scholar

[23] Painlevé, P. 1888. Sur les équations différentielles du premier ordre. C. R. Acad. Sci. Paris, 107, 221–224, 320–323, 724–727.Google Scholar

[24] Papageorgiou, V., Nijhoff, F., Grammaticos, B., and Ramani, A. 1992. Isomonodromic deformation problems for discrete analogues of Painlevé equations. Phys. Lett. A, 164(1), 57–64.CrossRef Google Scholar

[25] Picard, E. 1889. Mémoire sur la théorie des fonctions algébriques de deux variables. J. Math. Pures Appl. (4), 5, 135–320.Google Scholar

[26] Quispel, G. R. W., Roberts, J. A. G., and Thompson, C. J. 1989. Integrable mappings and soliton equations. II. Phys. D, 34(1-2), 183–192.CrossRef Google Scholar

[27] Ramani, A., and Grammaticos, B. 1992. Miura transforms for discrete Painlevé equations. J. Phys. A, 25(14), L633–L637.CrossRef Google Scholar

[28] Ramani, A., and Grammaticos, B. 1996. Discrete Painlevé equations: coalescences, limits and degeneracies. Phys. A, 228, 160–171.CrossRef Google Scholar

[29] Ramani, A., Grammaticos, B., and Hietarinta, J. 1991. Discrete versions of the Painlevé equations. Phys. Rev. Lett., 67(14), 1829–1832.CrossRef Google Scholar PubMed

[30] Ramani, A., Ohta, Y., Satsuma, J., and Grammaticos, B. 1998. Self-duality and Schlesinger chains for the asymmetric d-PII and q-PIII equations. Comm. Math. Phys., 192(1), 67–76.CrossRef Google Scholar

[31] Ramani, A., Grammaticos, B., Tamizhmani, T., and Tamizhmani, K. M. 2000. On a transcendental equation related to Painlevé III, and its discrete forms. J. Phys. A, 33(3), 579–590.CrossRef Google Scholar

[32] Ramani, A., Grammaticos, B., and Willox, R. 2008. Contiguity relations for discrete and ultradiscrete Painlevé equations. J. Nonlinear Math. Phys., 15(4), 353–364.CrossRef Google Scholar

[33] Sakai, H. 2001. Rational surfaces associated with affine root systems and geometry of the Painlevé equations. Comm. Math. Phys., 220(1), 165–229.CrossRef Google Scholar

[34] Takahashi, D., Tokihiro, T., Grammaticos, B., Ohta, Y., and Ramani, A. 1997. Constructing solutions to the ultradiscrete Painlevé equations. J. Phys. A, 30(22), 7953–7966.CrossRef Google Scholar

[35] Takenawa, T. 2001. A geometric approach to singularity confinement and algebraic entropy. J. Phys. A, 34(10), L95–L102.CrossRef Google Scholar

[36] Tamizhmani, K. M., Grammaticos, B., and Ramani, A. 1993. Schlesinger transforms for the discrete Painlevé IV equation. Lett. Math. Phys., 29(1), 49–54.CrossRef Google Scholar

[37] Tamizhmani, K. M., Ramani, A., Grammaticos, B., and Ohta, Y. 1996. A study of the discrete PV equation: Miura transformations and particular solutions. Lett. Math. Phys., 38(3), 289–296.CrossRef Google Scholar

[38] Tamizhmani, T., Grammaticos, B., Ramani, A., and Tamizhmani, K. M. 2001. On a class of special solutions of the Painlevé equations. Phys. A, 295(3-4), 359–370.CrossRef Google Scholar

[39] Tokihiro, T., Takahashi, D., Matsukidaira, J., and Satsuma, J. 1996. From soliton equations to integrable cellular automata through a limiting procedure. Phys. Rev. Lett., 76(18), 3247–3250.CrossRef Google Scholar PubMed

[40] Tokihiro, T., Grammaticos, B., and Ramani, A. 2002. From the continuous PV to discrete Painlevé equations. J. Phys. A, 35(28), 5943–5950.CrossRef Google Scholar

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2 - Painlevé Equations: Continuous, Discrete and Ultradiscrete

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