(2) If K is a subset of (X,d), show that K is compact if and only...

show that each subset of R is not compact by describing an open cover for it...

show that each subset of R is not compact by describing an open cover for it that has no finite subcover . [1,3) , also explain a little bit of finite subcover, what does it mean like a finite.

Prove that the union of two compact sets is compact using the fact that every open...

Prove that the union of two compact sets is compact using the fact that every open cover has a finite subcover.

For each of the following subsets of the real line, mark which ones are compact, meaning...

For each of the following subsets of the real line, mark which ones are compact, meaning that every open cover has a finite subcover. [1, infinity) (1, 3) [1, 3] (1, 3] {1, 3} Just answer the question by choosing the correct answer choices.

Suppose K is a nonempty compact subset of a metric space X and x∈X. Show, there...

Suppose K is a nonempty compact subset of a metric space X and x∈X. Show, there is a nearest point p∈K to x; that is, there is a point p∈K such that, for all other q∈K, d(p,x)≤d(q,x). [Suggestion: As a start, let S={d(x,y):y∈K} and show there is a sequence (qn) from K such that the numerical sequence (d(x,qn)) converges to inf(S).] Let X=R^2 and T={(x,y):x^2+y^2=1}. Show, there is a point z∈X and distinct points a,b∈T that are nearest points to...

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...

(a) If G is an open set and K is a compact set with K ⊆...

(a) If G is an open set and K is a compact set with K ⊆ G, show that there exists a δ > 0 such that {x|dist(x, K) < δ} ⊆ G. (b) Find an example of an open subset G in a metric space X and a closed, non compact subset F of G such that there is no δ > 0 with {x|dist(x, F) < δ} ⊆ G

let A be a subset of Rn and let x be a point in Rn. Show...

let A be a subset of Rn and let x be a point in Rn. Show that x is a limit point of A if and only if every open ball about x contains a point of A that is not equal to x

In this problem, we will explore how the cardinality of a subset S ⊆ X relates...

In this problem, we will explore how the cardinality of a subset S ⊆ X relates to the cardinality of a finite set X. (i) Explain why |S| ≤ |X| for every subset S ⊆ X when |X| = 1. (ii) Assume we know that if S ⊆ hni, then |S| ≤ n. Explain why we can show that if T ⊆ hn+ 1i, then |T| ≤ n + 1. (iii) Explain why parts (i) and (ii) imply that for...

Show that if X is an infinite set, then it is connected in the finite complement...

Show that if X is an infinite set, then it is connected in the finite complement topology. Show that in the finite complement on R every subspace is compact.

Show that the closed unit ball in a Hilbert space H is compact if and only...

Show that the closed unit ball in a Hilbert space H is compact if and only if H is finite dimensional. HINT: The closed unit ball must contain any basis.