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MOSCOW CENTER FOR CONTINUOUS MATHEMATICAL EDUCATION
INDEPENDENT UNIVERSITY OF MOSCOW
HIGHER SCHOOL OF ECONOMICS

A MATHEMATICS PROGRAM IN ENGLISH
FOR UNDERGRADUATES AND GRADUATE STUDENTS

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Advanced courses
  • Equations of Mathematical Physics
  • Riemann Surfaces
  • Mathematical Catastrophe Theory
  • Introduction to Commutative and Homological Algebra



    Mathematical Catastrophe Theory

    1.Critical and noncritical points. Implicit function theorem. 2.Morse lemma. Examples of non-Morse functions.

    3.Typical singularities of mappings ${\bf R}^2 \to {\bf R}^2$ and ${\bf R}^2 \to {\bf R}^3.$ Equivalence of singularities. Stable singularities.

    4.Thom-Boardman classification.

    5.Index of a singular point of a mapping ${\bf R}^n \to {\bf R}^n$ and of a smooth function. Global index and Euler characteristic.

    6.Calculus of jets. Transversality theorems. Whitney (weak) embedding and immersion theorems.

    7.Multiplicity of a smooth map ${\bf C}^n \to {\bf C}^n$. Milnor number of a smooth function (geometrical definitions).

    8.Rings of polynomials and power series. Their ideals. Local algebra of a singularity. Sufficient jet theorem. The Milnor number as the dimension of the local algebra.

    9.Newton polyhedra and their applications.

    10. Classification of singular points of functions and their normal forms. Simple singularities.

    11.Milnor fiber and its topology. Monodromy operator.

    12.Braid groups. Deformations of singularities, monodromy groups. Galois group of a general polynomial equation of degree n. Applications to complexity theory. Applications to problems of integral geometry. Simple singularities and reflection groups.

    13.Resolution of singularities of algebraic varieties.

    Introduction to Commutative and Homological Algebra

    Commutative and homological algebra studies algebraic structures, say, modules over commutative rings, in terms of their generators and relations. It provides the most powerful algebraic tools for applications in algebraic and differential geometry, number theory, algebraic topology, etc. This course gives a quick introduction to these techniques. It is designed as the starting point for those who intend to study algebraic geometry and related topics.

    Prerequisites: basic linear and multilinear algebra (tensor products, multilinear maps), some experience in geometry and topology is desirable but not essential.

    1) M. F. Atiyah, I. G. McDonald, Introduction to commutative algebra, Addison-Wesley (1969)
    2) S. I. Gelfand, Yu. I. Manin, Methods of homological algebra, I.

    1. Polynomial ideals and algebraic varieties. Noetherian rings. Hilbert base theorem.
    2. Integer ring extensions. Gauss-Kronecker-Dedekind lemma. Finitely generated algebras over a field.
    3. Noether's normalization theorem. Hilbert's Nullstellensatz.
    4. Geometry of ring homorphisms: category of affine schemes.
    5. Category of modules. Generators and relations. Exact sequences. Grothendieck group.
    6. Categories and functors. Representable functors. Natural transformations. Adjoint functors.
    7. The Hom-functor and tensor products. Projective, flat and injective modules. Frobenius duality.
    8. Linear, additive and Abelian categories. Complexes and homology.
    9. Canonical resolvents, bar-construction, classical derived functors; Ext and Tor
    10. Composition of derived functors, spectral sequences.
    11. Koszul complex. Hilbert's syzygies theorem. duality.
    12. Category of sheaves. Cech cohomology. Leray spectral sequence.
    13. Sheaves of modules on algebraic varieties. Locally free resolvents. Ext-functors.
    14. Serre duality.
    15. Category of coherent sheaves on projective space. Serre theorem. Beilinson theorem.
    16. If time allows: Resultants and determinants of multidimensional format, the ideal of a canonical curve and the Green problem, moduli of coherent sheaves on projective spaces.";



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