Name: From Gauss to Painleve By Katsunori Iwasaki
SKU: 9783322901651
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From Gauss to Painleve Summary

From Gauss to Painleve: A Modern Theory of Special Functions by Katsunori Iwasaki

This book gives an introduction to the modern theory of special functions. It focuses on the nonlinear Painleve differential equation and its solutions, the so-called Painleve functions. It contains modern treatments of the Gauss hypergeometric differential equation, monodromy of second order Fuchsian equations and nonlinear differential equations near singular points.The book starts from an elementary level requiring only basic notions of differential equations, function theory and group theory. Graduate students should be able to work with the text.The authors do an excellent job of presenting both the historical and mathematical details of the subject in a form accessible to any mathematician or physicist. (MPR in The American Mathematical Monthly Marz 1992.

1. Elements of Differential Equations.- 1.1 Cauchy's existence theorem.- 1.2 Linear equations.- 1.3 Local behavior around regular singularities (Frobenius's method).- 1.4 Fuchsian equations.- 1.5 Pfaffian systems and integrability conditions.- 1.6 Hamiltonian systems.- 2. The Hypergeometric Differential Equation.- 2.1 Definition and basic facts.- 2.1.1 The Gauss hypergeometric equation.- 2.1.2 Hypergeometric series.- 2.1.3 Finite group action and Rummer's 24 solutions.- 2.2 Contiguity relations.- 2.2.1 Contiguity relations.- 2.2.2 Contiguity relations and particular solutions of the Toda equation.- 2.3 Integral representations.- 2.3.1 Integral representations as a tool for global problems.- 2.3.2 Euler integral representation derived from the power series.- 2.3.3 The Euler transform.- 2.3.4 The hypergeometric Euler transform.- 2.3.5 Barnes integral representation: interpolation method.- 2.3.6 Barnes integral representation: difference equation method.- 2.3.7 The Gauss-Kummer identity.- 2.4 Monodromy of the hypergeometrie equation.- 2.4.1 Fundamental group of ?1 \\ {0, 1, ?} and the monodromy of the Riemann equation.- 2.4.2 Classification of 2-dimensional representations of the free group with 2 generators.- 2.4.3 Finding the monodromy by local properties and the Fuchs relation.- 2.4.4 Finding the monodromy by Euler integrals over arcs.- 2.4.5 Finding the monodromy by Euler integrals over double loops.- 2.4.6 Finding the monodromy by Barnes integrals.- 2.4.7 Finding the monodromy by Gauss-Kummer's identity.- 3. Monodromy-Preserving Deformation, Painleve Equations and Garnier Systems.- 3.1 Painleve equations.- 3.1.1 Historical remarks.- 3.1.2 Relations between the PJ's.- 3.1.3 Symmetry of the Painleve equation PVI.- 3.1.4 Solutions of PVI at singular points.- 3.1.5 Hamiltonian structure for PVI.- 3.1.6 Particular solutions of the PJ's.- 3.2 The Riemann-Hilbert problem for second order linear differential equations.- 3.2.1 Spaces of Fuchsian differential equations and those of representations of ?1.- 3.2.2 The Riemann-Hilbert problem.- 3.3 Monodromy-preserving deformations.- 3.3.1 M-invariant fundamental solutions.- 3.3.2 Totality of M-invariant fundamental solutions.- 3.3.3 Monodromy-preserving deformation of second order differential equations.- 3.3.4 SL-equations.- 3.3.5 Deformation equations for second order SL-equations.- 3.4 The Garnier system 𝒢n.- 3.4.1 Main theorem.- 3.4.2 Reduction to SL-equations.- 3.4.3 Explicit forms of Ki and Li.- 3.4.4 Explicit expression of Ai(x, t).- 3.4.5 Proof of Theorem 4.2.2.- 3.5 Schlesinger systems.- 3.6 The Schlesinger system and the Garnier system 𝒢n.- 3.6.1 Transformation of systems of equations into second order equations.- 3.6.2 Transformation of the Schlesinger system into the Garnier system.- 3.6.3 Transformation of second order equations into systems of equations.- 3.6.4 Relation between the Garnier system and the Schlesinger system.- 3.7 The polynomial Hamiltonian system ?nassociated with 𝒢n.- 3.7.1 Transformation of 𝒢ninto the polynomial Hamiltonian system ?n.- 3.7.2 Proof of Theorem 7.1.2.- 3.7.3 r-function associated with ?n.- 3.8 Symmetries of the Garnier system 𝒢nand of the system ?n.- 3.8.1 Symmetries of 𝒢n.- 3.8.2 Symmetries of ?n.- 3.8.3 Prolongation of the system ?n.- 3.9 Particular solutions of the Hamiltonian system ?n.- 3.9.1 The Lauricella hypergeometric series FD.- 3.9.2 Particular solutions of ?n.- 4. Studies on Singularities of Non-linear Differential Equations.- 4.1 Singularities of regular type.- 4.1.1 Holomorphic solutions.- 4.1.2 One-dimensional case.- 4.1.2.1 Formal transformations.- 4.1.2.2 Convergence of formal transformations.- 4.1.3 The n-dimensional case.- 4.2 Fixed singular points of regular type of Painleve equations.- 4.2.1 Transformation into the normal form.- 4.2.2 Solutions of equations in normal form.- 4.2.3 Proof of Theorem 2.2.1.- 4.2.4 Solutions of Painleve equations.- Notes on the chapter titlepage illustrations.- Index of symbols.

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Sku

NLS9783322901651

ISBN 13

9783322901651

ISBN 10

3322901653

Title

From Gauss to Painleve: A Modern Theory of Special Functions by Katsunori Iwasaki

Author

Katsunori Iwasaki

Series

Aspects of Mathematics

Condition

New

Binding type

Paperback

Publisher

Springer-Verlag Berlin and Heidelberg GmbH & Co. KG

Year published

2012-06-12

Number of pages

347

Prizes

N/A

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Book picture is for illustrative purposes only, actual binding, cover or edition may vary.

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This is a new book - be the first to read this copy. With untouched pages and a perfect binding, your brand new copy is ready to be opened for the first time

From Gauss to Painleve Katsunori Iwasaki

From Gauss to Painleve by Katsunori Iwasaki

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From Gauss to Painleve Summary

From Gauss to Painleve: A Modern Theory of Special Functions by Katsunori Iwasaki

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