Show that for any events A,B, and C, the equality A ∩ (B ∪ C) =...

14. Prove that equality holds in Parts (b) and (c) of Theorem 1.1.7 if the function...

14. Prove that equality holds in Parts (b) and (c) of Theorem 1.1.7 if the function f is one-to-one. (b) f(E ∩ F) ⊂ f(E) ∩ f(F) (c) f(E) \ f(F) ⊂ f(E \ F) if F ⊂ E

Consider events A, B, and C, with P(A) > P(B) > P(C) > 0. Events A...

Consider events A, B, and C, with P(A) > P(B) > P(C) > 0. Events A and B are mutually exclusive and collectively exhaustive. Events A and C are independent. (a) Can events C and B be mutually exclusive? Explain your reasoning. (Hint: You might find it helpful to draw a Venn diagram.) (b)  Are events B and C independent? Explain your reasoning.

Consider subsets A, B ⊆ X and C ⊆ Y . Prove the following equality. (Argue...

Consider subsets A, B ⊆ X and C ⊆ Y . Prove the following equality. (Argue straight from the definitions – don’t use any results.) (A ∪ B) × C = (A × C) ∪ (B × C)

Prove that A∩(B∩Cc)=(A∩B)∩(A∩C)c . Is the equality A∪B∩Cc=(A∪B)∩(A∪C)c always true?

Prove that A∩(B∩Cc)=(A∩B)∩(A∩C)c . Is the equality A∪B∩Cc=(A∪B)∩(A∪C)c always true?

Suppose events A,B,C,D are mutually independent. Show that events AB and CD are independent. Justify each...

Suppose events A,B,C,D are mutually independent. Show that events AB and CD are independent. Justify each step from the definition of mutual independence.

It is not true that the equality u x (v x w) = (u x v)...

It is not true that the equality u x (v x w) = (u x v) x w for all vectors. 1. Find explicit vector for u, v and w where this equality does not hold. 2. U, V and W are all nonzero vectors that satisfy the equality. Show that at least one of the conditions below holds: a) v is orthogonal to u and w. b) w is a scalar multiple of u. You can possibly use a...

For two events A and B show that P (A∩B) ≥ P (A)+P (B)−1. (Hint: Apply...

For two events A and B show that P (A∩B) ≥ P (A)+P (B)−1. (Hint: Apply de Morgan’s law and then the Bonferroni inequality). Derive below Results 1 to 4 from Axioms 1 to 3 given in Section 2.1.2 in the textbook. Result 1: P (Ac) = 1 − P(A) Result 2 : For any two events A and B, P (A∪B) = P (A)+P (B)−P (A∩B) Result 3: For any two events A and B, P(A) = P(A ∩...

Please type if possible. 1. For two events A and B show that P(A∩B) ≥ P(A)+P(B)−1....

Please type if possible. 1. For two events A and B show that P(A∩B) ≥ P(A)+P(B)−1. (Hint: Apply de Morgan’s law and then the Bonferroni inequality). 2. Derive below Results 1 to 4 from Axioms 1 to 3 given in Section 2.1.2 in the textbook. Result 1: P(Ac ) = 1 − P(A) Result 2 : For any two events A and B, P(A∪B) = P(A)+P(B)−P(A∩B) Result 3: For any two events A and B, P(A) = P(A ∩ B)...

Given the following information about events A, B, and C, determine which pairs of events, if...

Given the following information about events A, B, and C, determine which pairs of events, if any, are independent and which pairs are mutually exclusive. P(A)=0.73 P(B)=0.08 P(C)=0.17 P(B|A)=0.73 P(C|B)=0.17 P(A|C)=0.17 Select all that apply: A and C are mutually exclusive A and B are independent B and C are mutually exclusive A and C are independent A and B are mutually exclusive B and C are independent

Prove or disprove that for any events A and B, P(A) + P(B) − 1 ≤...

Prove or disprove that for any events A and B, P(A) + P(B) − 1 ≤ P(A ∩ B) ≤ min{P(A), P(B)}.