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MATH41051 Three hours THE UNIVERSITY OF MANCHESTER INTRODUCTION TO TOPOLOGY 26 January 2016 09:45 – 12:45 Answer ALL FOUR questions in Section A (40 marks in total). Answer THREE of the FOUR questions in Section B (45 marks in total). Answer ALL THREE questions in Section C (50 marks in total). If more than THREE questions from Section B are attempted then credit will be given for the best THREE answers. Electronic calculators are permitted, provided they cannot store text. 1 of 5 P.T.O. MATH41051 SECTION A Answer ALL FOUR questions. A1. (a) Define what is meant by a topology on a set X. (b) Define what is meant by saying that a function f : X → Y between topological spaces is continuous. Define what is meant by saying that f is a homeomorphism. (c) Prove that the punctured disc { x ∈ R2 | 0 < |x| < 1 } with the usual topology is homeomorphic to the cylinder S 1 × (1, 2) ⊂ R2 × R = R3 with the usual topology. [Here S 1 denotes the unit circle {x ∈ R2 | |x| = 1 }.] [10 marks] A2. (a) Define what is meant by saying that a topological space X is path-connected. (b) Define what is meant by saying that path-connectedness is a topological property? (c) Prove that path-connectedness is a topological property. (d) Prove that the unit circle S 1 = { x ∈ R2 | |x| = 1 } with the usual topology is path-connected. [10 marks] A3. (a) Define what is meant by saying that a topological space is Hausdorff. (b) Determine whether the set S = {a, b, c} with topology τ = ∅, S, {a}, {b, c} is Hausdorff. (c) Suppose that X1 is a subset of a topological space X. Define the subspace topology on X1 induced by the topology on X. [It is not necessary to prove that this is a topology.] (d) Prove that, if X is a Hausdorff space, then a subset X1 of X with the subspace topology is also Hausdorff. [10 marks] A4. (a) Suppose that X is a topological space and x0 , x1 are points of X. What is meant by saying that two paths in X from x0 to x1 are homotopic? (b) Define the product σ ∗ τ of two paths σ and τ in X, giving the condition for the product to exist. (c) Prove that, if the product σ0 ∗ τ0 of two paths σ0 and τ0 in X exists and the paths σ1 and τ1 are homotopic to σ0 and τ0 respectively, then σ1 ∗ τ1 also exists and is homotopic to σ0 ∗ τ0 . [10 marks] 2 of 5 P.T.O. MATH41051 SECTION B Answer THREE of the FOUR questions. If more than THREE questions are attempted then credit will be given for the best THREE answers. B5. (a) Define what is meant by the path-components of a topological space. [You may assume the definition of a path and properties of paths.] (b) Prove that a continuous map of topological spaces f : X → Y induces a function f∗ : π0 (X) → π0 (Y ) between the sets of path-components, taking care to prove that your function is well-defined. Prove that if f is a homeomorphism then f∗ is a bijection. (c) A pair of distinct points {p, q} in a topological space X is called a cut-pair of type n when the subspace X \ {p, q} has n path-components. Prove that a homeomorphism f : X → Y induces a bijection between the subsets of cut-pairs of type n. (d) Hence show, using cut-pairs of type 3 or otherwise, that no two of the following subspaces of R2 with the usual topology are homeomorphic. (i) (ii) (iii) [These diagrams represent a circle with two diameters, a circle with a single diameter and a circle with a single radial line.] [15 marks] B6. (a) Suppose that q : X → Y is a surjection from a topological space X to a set Y . Define the quotient topology on Y determined by q. State the universal property of the quotient topology. (b) Suppose that f : X → Y is a continuous surjection from a compact topological space X to a Hausdorff topological space Y . Define an equivalence relation ∼ on X so that f induces a bijection F : X/ ∼ → Y from the identification space of this equivalence relation to Y . Prove that F is a homeomorphism. [State clearly any general results which you use.] (c) Let X = { x ∈ R2 | 1 6 |x| 6 2 } with the usual topology. Prove that the identification space X/S 1 is homeomorphic to the closed unit disc D2 = { x ∈ R2 | |x| 6 1 } with the usual topology. [Here S 1 denotes the unit circle {x ∈ R2 | |x| = 1 }.] [15 marks] 3 of 5 P.T.O. MATH41051 B7. Suppose that X is a topological space and x0 and x1 are points of X. (a) Define π1 (X, x0 ), the fundamental group of X based at x0 . You should define the group product and indicate why this is well-defined and gives a group structure. (b) Define what is meant by saying that X is simply connected. (c) Suppose that X is a path-connected space such that all paths from x0 to x1 are homotopic. Prove that X is simply connected. [15 marks] B8. (a) Let S 1 denote the unit circle in the complex plane with the usual topology. Explain how the continuous map p : R → S 1 given by p(x) = exp(2πix) may be used to define the degree of a loop in S 1 based at 1. (b) Explain how the degree may be used to define a group homomorphism φ : π1 (S 1 , 1) → Z to the additive group of the integers. Prove that φ is an epimorphism. [The homomorphism φ is in fact an isomorphism but you need not prove this.] (c) Let f : S 1 → S 1 be the map given by f (z) = z (the complex conjugate). Determine the homomorphism g : Z → Z corresponding to the induced homomorphism f∗ : π1 (S 1 , 1) → π1 (S 1 , 1) using the isomorphism φ. [Theorems about the lifting of paths in S 1 to paths in R may be used without proof.] [15 marks] 4 of 5 P.T.O. MATH41051 SECTION C Answer ALL THREE questions. C9. (a) Define what is meant by saying that a subset N ⊂ X of a topological space X is a neighbourhood of the point x0 ∈ N . Prove that a subset U ⊂ X is open in X if and only if it is a neighbourhood of each of its points. (b) Define what is meant by saying that a function f : X → Y to a topological space Y is continuous at the point x0 ∈ X. Prove that f is continuous if and only if it is continuous at x for each x ∈ X. (c) Define what is meant by the interior, A◦ , of a subset A ⊂ X in a topological space X. Prove that A is open if and only if A◦ = A. (d) The half-open interval topology on R, the set of real numbers, has a basis consisting of all halfopen intervals { [a, b) | a, b ∈ R }. In this topology find the interiors of the subsets (i) (0, 1), (ii) [0, 1), (iii) (0, 1], (iv) [0, 1]. [20 marks] C10. (a) Suppose that G is a group. Define what is meant by saying that a topological space X is a G-space. Prove that if X is a G-space then there is a homomorphism from G to the group of all homeomorphisms X → X under composition. (b) Define what is meant by a normal space. Prove that a compact Hausdorff space is normal. [15 marks] e → X of topological spaces is C11. (a) Define what is meant by saying that a continuous map p : X a covering. (b) Suppose that X is a G-space for a group G. Define what is meant by saying that the action of G on X is properly discontinuous. (c) Prove that the action of Z on R (with the usual topology) given by n · x = x + n for n ∈ Z and x ∈ R is properly discontinuous. (d) Prove that if X is a G-space with a properly discontinuous action then the quotient map q : X → X/G is a covering. [You may assume without proof that the quotient map q is an open map.] [15 marks] END OF EXAMINATION PAPER 5 of 5