0.1 Proofs
1.
a.
1. If n = 2k, k an integer, then n2 = (2k)2 = 4k2 is a multiple of 4.
2. The converse is true: If n2 is a multiple of 4 then n must be even because n2 is odd when n is odd (Example 1).
c.
1. Verify: 23 − 6 · 22 + 11 · 2 − 6 = 0 and 33 − 6 · 32 + 11 · 3 − 6 = 0.
2. The converse is false: x = 1 is a counterexample. because
2.
a. Either n = 2k or n = 2k + 1, for some integer k. In the first case n2 = 4k2; in the second n2 = 4(k2 + k) + 1.
c. If n = 3k, then n3 − n = 3(9k3 − k); if n = 3k + 1, then
if n = 3k + 2, then n3 − n = 3(9k3 + 18k2 + 11k + 2).
3.
a.
1. If n is not odd, then n = 2k, k an integer, k ≥ 1, so n is not a prime.
2. The converse is false: n = 9 is a counterexample; it is odd but is not a prime.
c.
1. If 
then 
, that is a > b, contrary to the assumption.
then , that is a > b, contrary to the assumption.
2. The converse is true: If 
then 
, that is a ≤ b.
then , that is a ≤ b.
4.
a. If x > 0 and y > 0 assume . Squaring ...
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