自守函數理論講義 第二捲 [Lectures on the Theory of Theory of Automorphic Functions,Second Volume] pdf epub mobi txt 電子書 下載
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Felix Klein著名的Erlangen綱領使得群作用理論成為數學的核心部分。在此綱領的精神下,Felix Klein開始一個偉大的計劃,就是撰寫一係列著作將數學各領域包括數論、幾何、復分析、離散子群等統一起來。他的一本著作是《二十麵體和十五次方程的解》於1884年齣版,4年後翻譯成英文版,它將三個看似不同的領域——二十麵體的對稱性、十五次方程的解和超幾何函數的微分方程緊密地聯係起來。之後Felix Klein和Robert Fricke閤作撰寫瞭四捲著作,包括橢圓模函數兩捲本和自守函數兩捲本。弗裏剋、剋萊因著季理真主編迪普雷譯的《自守函數理論講義(第2捲)(英文版)(精)》是對一本著作的推廣,內容包含Poincare和Klein在自守形式的高度原創性的工作,它們奠定瞭Lie群的離散子群、代數群的算術子群及自守形式的現代理論的基礎,對數學的發展起著巨大的推動作用。
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目錄
Preface
Part I Narrower theory of the single-valued automorphic functions of one variable
Concept, existence and fundamental properties of the automorphic functions
1.1 Definition of the automorphic functions
1.2 Production of an elementary potential of the second kind belonging
to the fundamental domain
1.3 Production of automorphic functions of the group F
1.4 Mapping of the fundamental domain P onto a closed Riemann surface
1.5 The totality of all automorphic functions belonging to a group F and their principal properties
1.6 Classification and closer study of the elementary automorphic functions
1.7 Preparations for the classification of the higher automorphic functions
1.8 Classification and closer study of the higher automorphic functions ...
1.9 The integrals of the automorphic models
1.10 General single-valuedness theorem. Application to linear differential equations
1.11 as a linearly polymorphic function. The fundamental problem
1.12 Differential equations of the third order for the polymorphic functions.
1.13 Generalization of the concept of automorphic functions
Form-theoretic discussions for the automorphic models of genus zero
2.1 Shapes of the fundamental domains for the models of genus zero
2.2 Recapitulation of homogeneous variables, substitutions and groups...
2.3 General definition of the automorphic forms
2.4 The differentiation process and the principal forms of the models of genus zero
2.5 The family of prime forms and the ground forms for automorphic models with p = 0
2.6 Behavior of the automorphic forms q0d ((1,(2) with respect to the group generators
2.7 The ground forms for the groups of the circular-arc triangles
2.8 The single-valued automorphic forms and their multiplicator systems .
2.9 The number of all mtflfiplicator systems M for a given group F
2.10 Example for the determination of the number of the multiplicator systems M, the effect of secondary relations
2.11 Representation of all unbranched automorphic forms
2.12 Existence theorem for single-valued forms q0d((1,(2) for given multiplicator system M
2.13 Relations between multiplicator systems inverse to one another.
2.14 Integral forms and forms with prescribed poles
2.15 The (1, (2 as linearly-polymorphic forms of the zl, z2
2.16 Other forms of the polymorphic forms. History
2.17 Differential equations of second order for the polymorphic forms of zero dimension
2.18 Invariant form of the differential equation for the polymorphic forms (1, (2
2.19 Series representation of the polymorphic forms in the case n = 3
2.20 Representation of the polymorphic forms in the case n = 3 by definite integrals
Theory of Poincar6 series with special discussions for the models of genus zero
3.1 The approach to the Poincar6 series
3.2 First convergence study of the Poincar6 series
3.3 Behavior of the Poincar6 series at parabolic cusps
3.4 The Poincar6 series of (-2)nd dimension for groups F with boundary curves
3.5 The Poincar6 series of (-2)nd dimension for principal-circle groups With isolatedly situated boundary points
3.6 Convergence of the Poincar6 series of (-2)nd dimension for certain groups Without boundary curves and Without principal circle
3.7 Second convergence study in the principal-circle case. Continuous dependence of the Poincar6 series on the group moduli
3.8 Poles of the Poincar6 series and the possibility of its vanishing identically. Discussion for the case p = 0
3.9 Construction of one-pole Poincar6 series
3.10 One-poled series with poles at elliptic vertices
3.11 Introduction of the elementary forms ~ ((1, (2; ~ 1, ~2)
3.12 Behavior of the elementary form ~2((1,(2;(1,(2) at a parabolic cusp ( ..
3.13 Behavior of the elementary forms upon exercise of substitutions of the group F on (1, (2. Discussions for the models of genus p —— 0
3.14 Concerning the representability of arbitrary automorphic forms of genus zero by the elementary forms and the Poincar6 series
The automorphic forms and their analytic representations for models of arbitrary genus
4.1 Recapitulation concerning the groups of arbitrary genus p and their generation
4.2 Recapitulation and extension of the theory of the primeform for an arbitrary algebraic model
4.3 The polymorphic forms (1, (2 for a model of arbitrary genus p
4.4 Differential equations of the polymorphic functions and forms for models with p > 0
4.5 Representation of all unbranched automorphic forms of a group F of arbitrary genus by the prime-and groundforms
4.6 The single-valued automorphic forms and their multiplicator systems for a group of arbitrary genus
4.7 Existence of the single-valued forms for a given multiplicator system in the case of an arbitrary genus
4.8 More on single-valued automorphic forms for arbitrary p. The p forms z~-2((1,~'2)
4.9 Concept of conjugate forms. Extended Riemann-Roch theorem and applications of it
4.10 The Poincard series and the elementary forms for p. Unimultiplicative forms
4.11 Two-poled series of (——2)nd dimension and integrals of the 2nd kind for automorphic models of arbitrary genus p
4.12 The integrals of the first and third kinds. Product representation for the primeform ~
4.13 On the representability of the automorphic forms of arbitrary genus p by the elementary forms and the Poincard series
4.14 Closing remarks
Part II Fundamental theorems concerning the existence of polymorphic functions on Riemann surfaces
1 Continuity studies in the domain of the principal-circle groups
1.1 Recapitulation of the polygon theory of the principal-circle groups
1.2 The polygon continua of the character (0, 3)
1.3 The polygon continua of the character (0, 4)
1.4 The polygon continua of the character (0, n)
1.5 Another representation of the polygon continua of the character (0,4) .
1.6 The polygon continua of the character (1,1)
1.7 The polygon continua of the character (p, n)
1.8 Transition from the polygon continua to the group continua
1.9 The discontinuity of the modular group
1.10 The reduced polygons of the character (1,1)
1.11 The surface q)3 of third degree coming up for the character (1,1)
1.12 The discontinuity domain of the modular group and the character (1,1)
1.13 Connectivity and boundary of the individual group continuum of the character (1,1)
1.14 The reduced polygons of the character (0, 4)
1.15 The surfaces ~a of the third degree coming up for the character (0,4) ..
1.16 The discontinuity domain of the modular group and the group continua of the character (0, 4)
1.17 Boundary and connectivity of the individual group continuum of the character (0, 4)
1.18 The normal and the reduced polygons of the character (0, n)
1.19 The continua of the reduced polygons of the character (0, n) for given vertex invariants and fixed vertex arrangement
1.20 The discontinuity domain of the modular group and the group continua of the character (0, n)
1.21 The group continua of the character (p, n)
1.22 Report on the continua of the Riemann surfaces of the genus p
1.23 Report on the continua of the symmetric Riemann surfaces of the genus p
1.24 Continuity of the mapping between the continuum of groups and the continuum of Riemann surfaces
1.25 Single-valuedness of the mapping between the continuum of groups and the continuum of Riemann surfaces
1.26 Generalities on the continuity proof of the fundamental theorem in the domain of the principal-circle groups
1.27 Effectuation of the continuity proof for the signature (0, 3; ll, la)
1.28 Effectuation of the continuity proof for the signature (0, 3; ll)
1.29 Effectuation of the continuity proof for the signature (1,1; 11)
1.30 Effectuation of the continuity proof for the signature (0, 3)
1.31 Representation of the three-dimensional continua Bg and Bf for the signature (1,1)
1.32 Effectuation of the continuity proof for the signature (1,1)
Proof of the principal-circle and the boundary-circle theorem
2.1 Historical information concerning the direct methods of proof of the fundamental theorems
2.2 Theorems on logarithmic potentials and Green's functions
2.3 More on the solution of the boundary
自守函數理論講義 第二捲 [Lectures on the Theory of Theory of Automorphic Functions,Second Volume] 下載 mobi epub pdf txt 電子書
自守函數理論講義 第二捲 [Lectures on the Theory of Theory of Automorphic Functions,Second Volume] pdf epub mobi txt 電子書 下載