prove directly by definition that [1, \infty) is not compact.

Prove directly from definition that the set {1/2^n | n=1, 2, 3, ...} is not compact...

Prove directly from definition that the set {1/2^n | n=1, 2, 3, ...} is not compact but {0, 1/2^n |n=1, 2, 3, ...} is compact.

Prove directly from the definition of the limit (b) lim (n−2)/(n+12)=1 c) lim n√8 = 1....

Prove directly from the definition of the limit (b) lim (n−2)/(n+12)=1 c) lim n√8 = 1. (Hint: recall the formula for x^n − 1).

Prove that lim x^2 = c^2 as x approaches c by appealing directly to the definition...

Prove that lim x^2 = c^2 as x approaches c by appealing directly to the definition of a limit.

Prove directly (using only the definition of the countably infinite set, without the use of any...

Prove directly (using only the definition of the countably infinite set, without the use of any theo-rems) that the union of a finite set and a countably infinite set is countably infinite.   

Show directly that a compact metric space is totally bounded

Show directly that a compact metric space is totally bounded

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.

Suppose A is bounded and not compact. Prove that there is a function that is continuous...

Suppose A is bounded and not compact. Prove that there is a function that is continuous on A, but not uniformly continuous. Give an example of a set that is not compact, but every function continuous on that set is uniformly continuous.

Prove the following: The intersection of two open sets is compact if and only if it...

Prove the following: The intersection of two open sets is compact if and only if it is empty. Can the intersection of an infinite collection of open sets be a non-empty compact set?

prove that a compact set is closed using the Heine - Borel theorem

prove that a compact set is closed using the Heine - Borel theorem

Let E⊆R (R: The set of all real numbers) Prove that E is sequentially compact if...

Let E⊆R (R: The set of all real numbers) Prove that E is sequentially compact if and only if E is compact