Let x, y ∈Z. Prove that (x+1)y^2 is even if and only if x is odd...

1)Let ? be an integer. Prove that ?^2 is even if and only if ? is...

1)Let ? be an integer. Prove that ?^2 is even if and only if ? is even. (hint: to prove that ?⇔? is true, you may instead prove ?: ?⇒? and ?: ? ⇒ ? are true.) 2) Determine the truth value for each of the following statements where x and y are integers. State why it is true or false. ∃x ∀y x+y is odd.

Let a,b ∈ Z. Prove that a−b is even if and only if x and y...

Let a,b ∈ Z. Prove that a−b is even if and only if x and y are of the same parity.

Prove the following: Let n∈Z. Then n2 is odd if and only if n is odd.

Prove the following: Let n∈Z. Then n2 is odd if and only if n is odd.

Prove the following statements by contradiction a) If x∈Z is divisible by both even and odd...

Prove the following statements by contradiction a) If x∈Z is divisible by both even and odd integer, then x is even. b) If A and B are disjoint sets, then A∪B = AΔB. c) Let R be a relation on a set A. If R = R−1, then R is symmetric.

Prove that if x, y are both odd, then x^2 + y^2 is not a perfect...

Prove that if x, y are both odd, then x^2 + y^2 is not a perfect square. (Hint: first prove that if a number is a square and even, it is congruent to zero modulo four.)

3.a) Let n be an integer. Prove that if n is odd, then (n^2) is also...

3.a) Let n be an integer. Prove that if n is odd, then (n^2) is also odd. 3.b) Let x and y be integers. Prove that if x is even and y is divisible by 3, then the product xy is divisible by 6. 3.c) Let a and b be real numbers. Prove that if 0 < b < a, then (a^2) − ab > 0.

3. Prove by contrapositive: Let n ∈ N. If n^3−5n−10>0,then n ≥ 3. 4. Prove: Letx∈Z....

3. Prove by contrapositive: Let n ∈ N. If n^3−5n−10>0,then n ≥ 3. 4. Prove: Letx∈Z. Then5x−11 is even if and only if x is odd. 4. Prove: Letx∈Z. Then 5x−11 is even if and only if x is odd.

Let n be any integer, prove the following statement: n3+ 1 is even if and only...

Let n be any integer, prove the following statement: n3+ 1 is even if and only if n is odd.

Let p be an odd prime, and let x = [(p−1)/2]!. Prove that x^2 ≡ (−1)^(p+1)/2...

Let p be an odd prime, and let x = [(p−1)/2]!. Prove that x^2 ≡ (−1)^(p+1)/2 (mod p). (You will need Wilson’s theorem, (p−1)! ≡−1 (mod p).) This gives another proof that if p ≡ 1 (mod 4), then x^2 ≡ −1 (mod p) has a solution.

Let X, Y ⊂ Z and x, y ∈ Z Let A = (X\{x}) ∪ {x}....

Let X, Y ⊂ Z and x, y ∈ Z Let A = (X\{x}) ∪ {x}. a) Prove or disprove: A ⊆ X b) Prove or disprove: X ⊆ A 4 c) Prove or disprove: P(X ∪ Y ) ⊆ P(X) ∪ P(Y ) ∪ P(X ∩ Y ) d) Prove or disprove: P(X) ∪ P(Y ) ∪ P(X ∩ Y ) ⊆ P(X ∪ Y )