Prove that |cos x - cosy| < |x-y| for any x, y in the real numbers.

Prove the following: For any positive real numbers x and y, x+y ≥ √(xy)

Prove the following: For any positive real numbers x and y, x+y ≥ √(xy)

1) Prove that for all real numbers x and y, if x < y, then x...

1) Prove that for all real numbers x and y, if x < y, then x < (x+y)/2 < y 2) Let a, b ∈ R. Prove that: a) (Triangle inequality) |a + b| ≤ |a| + |b| (HINT: Use Exercise 2.1.12b and Proposition 2.1.12, or a proof by cases.)

Prove the following: If x and y are real numbers and x+y>20, then x>10 or y>10

Prove the following: If x and y are real numbers and x+y>20, then x>10 or y>10

Prove: If x is a sequence of real numbers that converges to L, then any subsequence...

Prove: If x is a sequence of real numbers that converges to L, then any subsequence of x converges to L.

Prove the following using the specified technique: (a) Prove by contrapositive that for any two real...

Prove the following using the specified technique: (a) Prove by contrapositive that for any two real numbers,x and y,if x is rational and y is irrational then x+y is also irrational. (b) Prove by contradiction that for any positive two real numbers,x and y,if x·y≥100 then either x≥10 or y≥10. Please write nicely or type.

Let x and y be real numbers. Then prove that sqrt(x^2) = abs(x) and abs(xy) =...

Let x and y be real numbers. Then prove that sqrt(x^2) = abs(x) and abs(xy) = abs(x) * abs(y)

Discreet Math: Prove or disprove each statement a) For any real number x, the floor of...

Discreet Math: Prove or disprove each statement a) For any real number x, the floor of 2x = 2 the floor of x b) For any real number x, the floor of the ceiling of x = the ceiling of x c) For any real numbers x and y, the ceiling of x and the ceiling of y = the ceiling of xy

Use axioms to prove the theorem: if x and y are non-zero real numbers, then xy...

Use axioms to prove the theorem: if x and y are non-zero real numbers, then xy does not equal 0

Let x = {x} and y ={y} represent bounded sequences of real numbers, z = x...

Let x = {x} and y ={y} represent bounded sequences of real numbers, z = x + y, prove the following: supX + supY = supZ where sup represents the supremum of each sequence.

Prove the continuity of sin x or cos x on R, or simply on any interval...

Prove the continuity of sin x or cos x on R, or simply on any interval of length 2\pi.