Prove or provide a counterexample Let (X,T) be a topological space, and let A⊆X. Then A...

Let X be a topological space. Let S and T be topologies on X, where S...

Let X be a topological space. Let S and T be topologies on X, where S and T are not equal topologies. Suppose (X,S) is compact and (X,T) is Hausdorff. Prove that T is not contained in S.

Let X be a topological space. Let S and T be topologies on X, where S...

Let X be a topological space. Let S and T be topologies on X, where S and T are distinct topologies. Suppose (X,S) is compact and (X,T) is Hausdorff. Prove that T is not contained in S. how to solve?

Let X be a topological space with topology T = P(X). Prove that X is finite...

Let X be a topological space with topology T = P(X). Prove that X is finite if and only if X is compact. (Note: You may assume you proved that if ∣X∣ = n, then ∣P(X)∣ = 2 n in homework 2, problem 2 and simply reference this. Hint: Ô⇒ follows from the fact that if X is finite, T is also finite (why?). Therefore every open cover is already finite. For the reverse direction, consider the contrapositive. Suppose X...

Prove that if T is a discrete topological space (i.e., every subset of T is open)...

Prove that if T is a discrete topological space (i.e., every subset of T is open) and ∼ is any equivalence relation on T , then the quotient space T / ∼ is also discrete topological space. [Hint: It is a very short and straightforward proof.]

Show by counterexample that a connected component of a topological space is not necessarily open.

Show by counterexample that a connected component of a topological space is not necessarily open.

Give an example of a topological space X that is Hausdorff, but not regular. Prove that...

Give an example of a topological space X that is Hausdorff, but not regular. Prove that the space X you chose is Hausdorff. Prove that the space X you chose is not regular.

1.- Prove the intermediate value theorem: let (X, τ) be a connected topological space, f: X...

1.- Prove the intermediate value theorem: let (X, τ) be a connected topological space, f: X - → Y a continuous transformation and x1, x2 ∈ X with a1 = f (x1), a2 = f (x2) ( a1 different a2). Then for all c∈ (a1, a2) there is x∈ such that f (x) = c. 2.- Let f: X - → Y be a continuous and suprajective transformation. Show that if X is connected, then Y too.

Prove that if a topological space X has the fixed point property, then X is connected

Prove that if a topological space X has the fixed point property, then X is connected

Let f be a continuous from a topological space X to the reals. Let a be...

Let f be a continuous from a topological space X to the reals. Let a be in the reals and let A = {x in X : f(x)=a} Show that A is closed inX.

Prove the conjecture or provide a counterexample: Let U ∈ in the usual topology, and let...

Prove the conjecture or provide a counterexample: Let U ∈ in the usual topology, and let F be a finite set. Then (U−F) ∈ in the usual topology.