Geometry and Topology (the second draft)
Space curves and surfaces
Curves and Parametrization, Regular Surfaces; Inverse Images of Regular Values.Gauss Map and Fundamental Properties; Isometries; Conformal Maps; Rigidity of the Sphere.
Topological space
Space, maps, compactness and connectedness, quotients; Paths and Homotopy. The Fundamental Group of the Circle. Induced Homomorphisms. Free Products of Groups. The van Kampen Theorem. Covering Spaces and Lifting Properties; Simplex and complexes. Triangulations. Surfaces and its classification.
Differential Manifolds
Differentiable Manifolds and Submanifolds, Differentiable Functions and Mappings; The Tangent Space, Vector Field and Covector Fields. Tensors and Tensor Fields and differential forms. The Riemannian Metrics as examples, Orientation and Volume Element; Exterior Differentiation and Frobenius's Theorem; Integration on manifolds, Manifolds with Boundary and Stokes' Theorem.
Homology and cohomology
Simplicial and Singular Homology. Homotopy Invariance. Exact Sequences and Excision. Degree. Cellular Homology. Mayer-Vietoris Sequences. Homology with Coefficients. The Universal Coefficient Theorem. Cohomology of Spaces. The Cohomology Ring. A Kunneth Formula. Spaces with Polynomial Cohomology. Orientations and Homology. Cup Product and Duality.
Riemannian Manifolds
Differentiation and connection, Constant Vector Fields and Parallel Displacement
Riemann Curvatures and the Equations of Structure Manifolds of Constant Curvature,
Spaces of Positive Curvature, Spaces of Zero Curvature, Spaces of Constant Negative Curvature
References:
M. do Carmo , Differentia geometry of curves and surfaces.
Prentice- Hall, 1976 (25th printing)
Chen Qing and Chia Kuai Peng, Differential Geometry
M. Armstrong, Basic Topology Undergraduate texts in mathematics
W.M. Boothby, An Introduction to Differentiable Manifolds and Riemannian Geometry Academic Press, Inc., Orlando, FL, 1986
M. Spivak, A comprehensive introduction to differential geometry
N. Hicks, Notes on differential geometry, Van Nostrand.
T. Frenkel, Geometry of Physics
J. Milnor, Morse Theory
A Hatcher, Algebraic Topology (http://www.math.cornell.edu/~hatcher/AT/ATpage.html)
J. Milnor, Topology from the differentiable viewpoint
R. Bott and L. Tu, Differential forms in algebraic topology
V. Guillemin, A. Pollack, Differential topology
Algebra, Number Theory and Combinatorics (second draft)
Linear Algebra
Abstract vector spaces; subspaces; dimension; matrices and linear transformations; matrix algebras and groups; determinants and traces; eigenvectors and eigenvalues, characteristic and minimal polynomials; diagonalization and triangularization of operators; invariant subspaces and canonical forms; inner products and orthogonal bases; reduction of quadratic forms; hermitian and unitary operators, bilinear forms; dual spaces; adjoints. tensor products and tensor algebras;
Integers and polynomials
Integers, Euclidean algorithm, unique decomposition; congruence and the Chinese Remainder theorem; Quadratic reciprocity ; Indeterminate Equations. Polynomials, Euclidean algorithm, uniqueness decomposition, zeros; The fundamental theorem of algebra; Polynomials of integer coefficients, the Gauss lemma and the Eisenstein criterion; Polynomials of several variables, homogenous and symmetric polynomials, the fundamental theorem of symmetric polynomials.
Group
Groups and homomorphisms, Sylow theorem, finitely generated abelian groups. Examples: permutation groups, cyclic groups, dihedral groups, matrix groups, simple groups, Jordan-Holder theorem, linear groups (GL(n, F) and its subgroups), p-groups, solvable and nilpotent groups, group extensions, semi-direct products, free groups, amalgamated products and group presentations.
Ring
Basic properties of rings, units, ideals, homomorphisms, quotient rings, prime and maximal ideals, fields of fractions, Euclidean domains, principal ideal domains and unique factorization domains, polynomial and power series rings, Chinese Remainder Theorem, local rings and localization, Nakayama's lemma, chain conditions and Noetherian rings, Hilbert basis theorem, Artin rings, integral ring extensions, Nullstellensatz, Dedekind domains,algebraic sets, Spec(A).
Module
Modules and algebra Free and projective; tensor products; irreducible modules and Schur’s lemma; semisimple, simple and primitive rings; density and Wederburn theorems; the structure of finitely generated modules over principal ideal domains, with application to abelian groups and canonical forms; categories and functors; complexes, injective modues, cohomology; Tor and Ext.
Field
Field extensions, algebraic extensions, transcendence bases; cyclic and cyclotomic extensions; solvability of polynomial equations; finite fields; separable and inseparable extensions; Galois theory, norms and traces, cyclic extensions, Galois theory of number fields, transcendence degree, function fields.
Group representation
Irreducible representations, Schur's lemma, characters, Schur orthogonality, character tables, semisimple group rings, induced representations, Frobenius reciprocity, tensor products, symmetric and exterior powers, complex, real, and rational representations.
Lie Algebra
Basic concepts, semisimple Lie algebras, root systems, isomorphism and conjugacy theorems, representation theory.
Combinatorics (TBA)
References:
Strang, Linear algebra, Academic Press.
I.M. Gelfand, Linear Algebra
《整数与多项式》冯克勤 余红兵著 高等教育出版社
Jacobson, Nathan Basic algebra. I. Second edition. W. H. Freeman and Company, New York, 1985. xviii+499 pp.
本文来源:https://www.2haoxitong.net/k/doc/6abb141da300a6c30c229fd1.html
文档为doc格式