Let X and Y be metric spaces. Let f be a continuous function from X onto...

Let (X, dX) and (Y, dY ) be metric spaces and let f : X →...

Let (X, dX) and (Y, dY ) be metric spaces and let f : X → Y be a continuous bijection. Prove that if (X, dX) is compact, then f is a homeomorphism

Let X, Y be metric spaces, with Y complete. Let S ⊂ X and let f...

Let X, Y be metric spaces, with Y complete. Let S ⊂ X and let f : S → Y be uniformly continuous. (a) Suppose p ∈ S closure and (pn) is a sequence in S with pn → p. Show that (f(pn)) converges in y to some point yp.

Let (X1,d1) and (X2,d2) be metric spaces, and let y∈X2. Define f:X1→X2 by f(x) =y for...

Let (X1,d1) and (X2,d2) be metric spaces, and let y∈X2. Define f:X1→X2 by f(x) =y for all x∈X1. Show that f is continuous. (TOPOLOGY)

Let (X, d) be a compact metric space and F: X--> X be a function such...

Let (X, d) be a compact metric space and F: X--> X be a function such that d(F(x), F(y)) < d(x, y). Let G: X --> R be a function such that G(x) = d(F(x), x). Prove G is continuous (assume that it is proved that F is continuous).

Please prove the following theorem: Suppose (X,p) and (Y,b) are metric spaces, X is compact, and...

Please prove the following theorem: Suppose (X,p) and (Y,b) are metric spaces, X is compact, and f:X→Y is continuous. Then f is uniformly continuous.

Let (X, d) be a compact metric space and let A ⊆ X. Suppose that A...

Let (X, d) be a compact metric space and let A ⊆ X. Suppose that A is not compact. Prove that there exists a continuous function f : A → R, from (A, d) to (R, d|·|), which is not uniformly continuous.

If X, Y are topological spaces and f : X → Y we call the graph...

If X, Y are topological spaces and f : X → Y we call the graph of f the set Γf = {(x, f(x)); x ∈ X} which is a subset of X × Y. If X and Y are metric spaces and f is a continuous function prove that the graph of f is a closed set.

Suppose that f : X  → Y and g: X  → Y are continuous maps between topological spaces...

Suppose that f : X  → Y and g: X  → Y are continuous maps between topological spaces and that Y is Hausdorff. Show that the set A = {x ∈ X : f(x) = g(x)} is closed in X.

is about metric spaces: Let X be a metric discret space show that a sequence x_n...

is about metric spaces: Let X be a metric discret space show that a sequence x_n in X converge to l in X iff x_n is constant exept for a finite number of points.

The product of two metric spaces (Y, dY ) and (Z, dZ) is the metric space...

The product of two metric spaces (Y, dY ) and (Z, dZ) is the metric space (Y × Z, dY ×Z), where dY ×Z is defined by dY ×Z((y, z),(y 0 , z0 )) = dY (y, y0 ) + dZ(z, z0 ). Assume that (Y, dY ) and (Z, dZ) are compact. Prove that (Y × Z, dY × dZ) is compact.