Here are two statements about positive real numbers. Prove or disprove each of the statements ∀x,...

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

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)

Prove or disprove the following statements. Remember to disprove a statement you have to show that...

Prove or disprove the following statements. Remember to disprove a statement you have to show that the statement is false. Equivalently, you can prove that the negation of the statement is true. Clearly state it, if a statement is True or False. In your proof, you can use ”obvious facts” and simple theorems that we have proved previously in lecture. (a) For all real numbers x and y, “if x and y are irrational, then x+y is irrational”. (b) For...

) Prove or disprove the statements: (a) If x is a real number such that |x...

) Prove or disprove the statements: (a) If x is a real number such that |x + 2| + |x| ≤ 1, then |x ^2 + 2x − 1| ≤ 2. (b) If x is a real number such that |x + 2| + |x| ≤ 2, then |x^ 2 + 2x − 1| ≤ 2. (c) If x is a real number such that |x + 2| + |x| ≤ 3, then |x ^2 + 2x − 1 |...

Let n be a positive integer and p and r two real numbers in the interval...

Let n be a positive integer and p and r two real numbers in the interval (0,1). Two random variables X and Y are defined on a the same sample space. All we know about them is that X∼Geom(p) and Y∼Bin(n,r). (In particular, we do not know whether X and Y are independent.) For each expectation below, decide whether it can be calculated with this information, and if it can, give its value (in terms of p, n, and r)....

Write the contrapositive statements to each of the following.  Then prove each of them by proving their respective contrapositives. ...

Write the contrapositive statements to each of the following.  Then prove each of them by proving their respective contrapositives.  In both statements assume x and y are integers. a. If  the product xy is even, then at least one of the two must be even. b. If the product xy  is odd, then both x and y must be odd. 3. Write the converse the following statement.  Then prove or disprove that converse depending on whether it is true or not.  Assume x...

(a) Prove or disprove the statement (where n is an integer): If 3n + 2 is...

(a) Prove or disprove the statement (where n is an integer): If 3n + 2 is even, then n is even. (b) Prove or disprove the statement: For irrational numbers x and y, the product xy is irrational.

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)

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

8. Prove or disprove the following statements about primes: (a) (3 Pts.) The sum of two...

8. Prove or disprove the following statements about primes: (a) (3 Pts.) The sum of two primes is a prime number. (b) (3 Pts.) If p and q are prime numbers both greater than 2, then pq + 17 is a composite number. (c) (3 Pts.) For every n, the number n2 ? n + 17 is always prime.