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ALGBOOK TOPOLOGY 3.1 19. januar 2002 3. Topological spaces. n n n n (3.1) Definition. A topological space is a set !!X together with a collection !!{Uα }α∈I of subsets Uα of X such that (1) The set X and the empty set ∅ are in the collection {Uα }α∈I . (2) For every subset !!J of I the union ∪β∈J Uβ of the sets in {Uβ }β∈J is in the collection {Uα }α∈I . (3) For every finite subset J of I the intersection ∩β∈J Uβ of the sets in {Uβ }β∈J is in the collection {Uα }α∈I . The sets Uα are called the open sets of X and the complement !!X \ Uα of the open sets are called closed. We say that the collection of sets {Uα }α∈I is a topology on X. Often we simply say that X is a topological space. Let !!x be a point of X. A subset !!Y of X that contains x is a neighbourhood of x if there exists an open subset U of X such that x ∈ U ⊆ Y . A collection {Uβ }β∈J of open sets in X is called an open covering of X if the union of the sets is X, that is X = ∪β∈J Uβ . (3.2) Example. Let X be a set. The set X with the collection {∅, X} consisting of the empty set and X itself is a topological space. This topology is called the trivial topology on X. (3.3) Example. Let X be a set. The set X with the collection of all subsets of X is a topological space. This topology is called the discrete topology. n (3.4) Example. Let X be a set. The set X with the collection of sets consisting of ∅ and all the subsets U of X whose complement !!X \ U is a finite set is a topological space. We call this topology the finite complement topology. (3.5) Remark. Let X be a topological space with open sets {Uα }α∈I . For every subset Y of X we have that the collection of sets {Uα ∩ Y }α∈I are the open subsets of a topology on Y . We call this topology on Y the topology induced by the topology on X, and we say that Y is a subspace of X. n n (3.6) Definition. Let X be a topological space and let x be a point of X. A collection of sets !!B = {Uβ }β∈J consisting of open neighbourhoods Uβ of x is a basis for the neighbourhoods of x if there, for every open neighbourhood U of x, is an open set Uβ belonging to B such that x ∈ Uβ ⊆ U . A collection of subsets B = {Uγ }γ∈K of X consisting of open sets Uγ of X is a basis for the topology if the members !!Bx = {U ∈ B : x ∈ U } containing x is a basis for the neighbourhoods of x for every point x ∈ X. (3.7) Example. The collection of all open sets is a basis for the topology on X. n (3.8) Definition. For every subset !!Y of X we denote by !!Y the intersection of all the closed sets that contain Y . Equivalently Y is the set consisting of all points x in X such that every open neighbourhood of x contains at least one point of Y . We call Y the closure of the set Y . topology3 ALGBOOK TOPOLOGY 3.2 19. januar 2002 n n (3.9) Definition. Let X and Y be topological spaces. A map !!ψ : X → Y is called continuous if the inverse image ψ −1 (V ) of every open subset V of Y is open in X. The map is an isomorphism if there is a continuous homomorphism !!ω : Y → X which is inverse to ψ. That is ωψ = idX and ψω = idY . (3.10) Example. Let X be a topological space and Y a subset considered as a topological space with the induced topology. Then the inclusion map Y → X is continuous. (3.11) Example. The set theoretic inverse of a bijecive continuous map ψ : X → Y is not necessarily bijective. For example the identity map idX : X 0 → X 00 from the topological space X 0 with X as underlying set and the discrete topology to the topological space X 00 with X as underlying set and trivial topology is always continous. However, the inverse, which is also idX is not continous if X has more than one point. (3.12) Remark. For every topological space X the map idX is continuous. When ψ : X → Y and ω : Y → Z are continuous maps of topological spaces we have that ωψ : X → Z is continuous. In other words the topological spaces with continuous maps form a category, called the category of topological spaces. (3.13) Remark. Let X be a topological space and let Obj(K) be the collection of open sets of X. For each pair of open sets U, V in X we let Hom(U, V ) consist of the inclusion map of U in V if U is contained in V , and otherwise let Hom(U, V ) be empty. Then Obj(K) with these morphisms form a category. → (3.14) Exercises. 1. Let X be a set and let X = U0 ⊃ U1 ⊃ U2 ⊃ · · · be a sequence of subsets. (1) Show that the sets ∅ and {Un }n∈N are the open sets of a topology of X. (2) Show that if ∩n∈N Un 6= 0 the set ∩n∈N Un is not open in X. 2. Let X be a set and let x0 be an elements of X. (1) Show that X with the collection of all subsets of X that contain x0 is a topological space. (2) Show that X has a basis for the topology with open sets consisting of 1 or 2 elements. (3) Find the closed points of X. 3. Let Y = {y, X} be the disjoint union of a point y and the underlying set X of a topological space with open sets {Uα }α∈I . Show that Y with the family of sets {y, Uα }α∈I is a topological space. 4. Let X and Y be topological spaces and ψ : X → Y a map. (1) Show that when X has the discrete topology then ψ is continuous. (2) Show that when Y has the trivial topology then ψ is continuous. 5. Give another example than (?) of a continuous bijective homomorphism ψ : X → Y of topological spaces which is not an isomorphism. ALGBOOK TOPOLOGY 3.3 19. januar 2002 6. Let X and Y be topological spaces and B a basis for the topology on Y . Show that a map ψ : X → Y is continuous if and only if the inverse image of every open set belonging to B is open in X. 7. Let X be a set and let B = {Uα }α∈I be a family of subsets Uα with the property that for every pair of sets Uα , Uβ in the family B and every point x ∈ Uα ∩ Uβ there is a Uγ in B such that x ∈ Uγ ⊆ Uα ∩ Uβ . Let U be the family of all subsets U of X such that for every point x ∈ U there is a Uα in B such that x ∈ Uα ⊆ U . → (1) Show that X with the family of sets U is a topological spaces. (2) Show that the sets of B form a basis for the topological space of part (1). n 8. Let X and Y be topological spaces and let !!V be the collection of subsets of the cartesian product X × Y of the form U × V , where U is open in the X and V is open in Y . n (1) Show that X × Y with the sets !!U which consists of all the unions of the sets in V form a topological space. We call this topology the product topology on X ×Y. (2) Show that the projection !!π : X ×Y → X defined by π(x, y) = x is continuous when X × Y has the product topology. (3) Assume that X and Y have the finite complement topology. Show that in most cases the finite complement topology on X × Y is different from the product topology. n n → → → 9. Let X = Z. An arithmetic progression consists of numbers of the form !!Vp,q = {pn + q : n ∈ Z} where p and q are integers, and p 6= 0. (1) Show that for every integer m we have that Vp,q = Vp,mp+q . (2) Let p0 , p00 , q 0 , q 00 be natural numbers. Show that for every number n in Vp0 ,q0 ∩ Vp00 ,q00 there are natural numbers p, q such that n ∈ Vp,q ⊆ Vp0 ,q0 ∩ Vp00 ,q00 . (3) Show that the collection of all subsets of Z that are arithmetic progressions satisfy the conditions of Exercise (6), and consequently is the basis for a topology on X. (4) Show that all the arithmetic progressions Vp,q are closed in the topology of part (3). (5) Let Y be the union of all the sets Vp,0 where p is a prime number. Show that X \ Y = {−1, 1} and that {−1, 1} is not open in X. (6) Use part (4) and (5) to prove that there exists infinitely many prime numbers. 10. Let X be a set with a metric, that is, for each pair of points x, y of X there is a real number d(x, y) such that for all elements x, y, z of X we have: (1) (2) (3) (4) d(x, y) ≥ 0. d(x, y) = 0 if and only if x = y. d(x, y) = d(y, x). d(x, z) ≤ d(x, y) + d(y, z). Let U consist of all sets U with the property that for every point x of U there is a ALGBOOK TOPOLOGY 3.4 19. januar 2002 real number εx such that the set {y ∈ X : d(x, y) < εx } is contained in U . (1) Show that X with the family U is a topological space. (2) Show that for each point x of X the sets Ux,n = {y ∈ X : d(y, x) < 1/n} for all natural numbers n form a basis for the neighbourhoods of x.