Math 389.60 Introduction to Topology and Differential Geometry

Math 389.60 – Introduction to Topology and Differential Geometry

Review for Midterm Test

The test will consist in 5 problems: 2 theoretical questions and 3 homework problems. One page of notes, front and back, is allowed, but without solutions to the homework problems.

Ch 1 Informal Topology

- Topological space, mapping, homeomorphism, embedding, isotopy.

Ch.2 Graphs

- Nodes, arcs, adjacency matrix, degree sequence of a graph, subgraphs; classes of graphs: simple graphs, complete graphs, bipartite and k-partite graphs;

- Traversability: walk, trail, circuit, paths, cycle; Eulerian graph & criterion (all nodes have even degrees), Hamiltonian graph; connected graphs and components of a graph;

- Colorings (of nodes); criterion for 2-colorable: no odd cycles.

- Planarity: definition, criterion (no K5 or K3,3), linking distance

- Graph homeomorphisms & graph morphisms (combinatorial/categorical definition), topological reduced form, reduced degree sequence, correspondence: homeomorphism <-> isomorphic (combinatorial).

Ch.3 Surfaces

- Polygonal presentations: presentations, skeleton, types of surfaces: closed/w. boundary, orientable or not, embeddable in R3 or not; examples.

- Closed surfaces: presentations and cut-and-paste equivalence, correspondence with homeomorphism classes of surfaces, invariants: Euler characteristic, orientability, classification of closed surfaces, normal presentations and correspondence with the pair of invariants.

- Operations on surfaces: Excision and gluing, connected sum (tubular joining), handle addition, properties: Sn=S0+n handles, X(S’+handle)=X(S’)+2, fattening a graph, cross-cap addition.

- Bordered surfaces: presentations, closure of a bordered surface, invariants (X,O,b) & classification, excision on bordered surfaces: separating or not.

- Riemann surfaces: presentations by a cycle of permutations acting transitively; relations with polynomial equations; the EP-characteristic formula of a RS-presentation.

Ch. 4 Graphs ands Surfaces

- Embeddings and their regions: definition, regions and their visualization, genus of a graph; all graphs are embeddable on an orientable surface;

- Polygonal embeddings: definition, EP-formula, rotation systems, embeddings and associated rotation systems (onto).

- Embedding a fixed graph: minimal embedding (it is polygonal), steps of the algorithm for determining the genus of a graph, estimating the genus of a graph, amalgamation of graphs.

- Voltage graphs and their coverings: voltage graph, cover graph, covering, isotopy group, branched cover, covering map.

Math 389.60 – Review for Final Exam

The final exam tests the second part of the course. It will consist in 5 problems: 2 theoretical questions and 3 homework problems. One page of notes, front and back, is allowed, without solutions to homework problems.

Ch. 5 Knots and Links

- Def. knot, link, 3D-isotopy, 2D-diagram, 2D-isotopy

- Rademeister moves and Theorem: 3D-isotopy  2D-isotopy + R-moves

- Def. Invariants of knots and links, complete invariants

- P-labelings of a link, the isotopy invariant: existence of a p-labeling

- Left/right crossing, linking number, it is an invariant, properties: it is an integer;

- Computing lk(K1,K2)

- Placements of graphs: def.

- A,B-connections, states, bracket polynomial

- Kauffman polynomial: specialization B=1/A, d=(A2+B2)

- Writhe: def. and properties (invariant to RM3, defining properties: 1) [O]=1, 2) [D]=A [DA]+B[DB], 3) [D O]=[D] d), computing it;

- Jones polynomial in terms of bracket polynomial; skein relation (relating L0, L+, L-);

- Alternating diagrams: def., regions, reduced alternating diagrams

- Number of crossings: def., invariant under RM3 => invariant of links for reduced alternating diagrams

- Spanning surfaces, 2-coloring

- Seifert surfaces: def., existence by construction (the idea)

Ch. 6 Differential Geometry of Surfaces

- Parameterized surfaces, tangent plane, normal: def., computing the normal for a given parameterization

- Orthogonal parameterizations

- Gaussian curvature: def., Gauss Theorem: formula in terms of E,F,G,L,M,N

- First fundamental form: def., computing it in a given parameterization

- Geodesics: def., inclination angle, equation of geodesics for orthogonal parameterizations.

Types of Problems

- Computing: the linking number of two disjoint knots, the crossing number for an alternating diagram, the bracket polynomial and the writhe, using the skein relation to find the Jones polynomial.

- Sketching the spanning surface using a 2-coloring, describing how to construct the Seifert surface in an example together with a rough sketch.

- Computing in a given parameterization: the principal normal to a surface, Gaussian curvature, first fundamental form.