Prove that if A is a subset of X, then a) A ∩ (X − A)...

[Q] Prove or disprove: a)every subset of an uncountable set is countable. b)every subset of a...

[Q] Prove or disprove: a)every subset of an uncountable set is countable. b)every subset of a countable set is countable. c)every superset of a countable set is countable.

Suppose that E is a closed connected infinite subset of a metric space X. Prove that...

Suppose that E is a closed connected infinite subset of a metric space X. Prove that E is a perfect set.

Let A and B be sets and let X be a subset of A. Let f:...

Let A and B be sets and let X be a subset of A. Let f: A→B be a bijection. Prove that f(A-X)=B-f(X).

Let A, B be sets and f: A -> B. For any subsets X,Y subset of...

Let A, B be sets and f: A -> B. For any subsets X,Y subset of A, X is a subset of Y iff f(x) is a subset of f(Y). Prove your answer. If the statement is false indicate an additional hypothesis the would make the statement true.

Prove that if A*B*C, then ray AB = ray AC and ray BC is a subset...

Prove that if A*B*C, then ray AB = ray AC and ray BC is a subset of ray AC

Let F be an ordered field.  Let S be the subset [a,b) i.e, {x|a<=x<b, x element of...

Let F be an ordered field.  Let S be the subset [a,b) i.e, {x|a<=x<b, x element of F}. Prove that infimum and supremum exist or do not exist.

Suppose S is a subset of the Reals and is non-empty and bounded above. Prove that...

Suppose S is a subset of the Reals and is non-empty and bounded above. Prove that alpha = supS if and only if , for every epsilon > 0 , there is and element x in S such that alpha - epsilon <x

41. Prove that a proper subset of a countable set is countable

41. Prove that a proper subset of a countable set is countable

Prove: A nonempty subset C⊆R is closed if and only if there is a continuous function...

Prove: A nonempty subset C⊆R is closed if and only if there is a continuous function g:R→R such that C=g-1(0).

Prove that The set P of all prime numbers is a closed subset of R but...

Prove that The set P of all prime numbers is a closed subset of R but not an open subset of R.