0.4
0.75
0.3
Find the value of P(A∪(Bc∪Cc)c) for each of the following cases:
The events A, B, C are disjoint events and P(A)=2/5.
P(A∪(Bc∪Cc)c)= incorrect
The events A and C are disjoint, and P(A)=1/2 and P(B∩C)=1/4.
P(A∪(Bc∪Cc)c)= incorrect
P(Ac∩(Bc∪Cc))=0.7.
P(A∪(Bc∪Cc)c)= incorrect
0.75
0.3
P(A∪(Bc∪Cc)c)= 0.4
P(A∪(Bc∪Cc)c) = 0.75
P(A∪(Bc∪Cc)c) =0.3
Why don't scientists trust atoms?
Because they make up everything!
1. Disjoint events: Disjoint events are events that cannot happen at the same time. It means they have no outcomes in common. For example, if A and B are disjoint events, then P(A∩B) = 0.
2. Union (A∪B): The union of two events A and B, denoted by A∪B, is the event that at least one of A or B occurs. In terms of set theory, the union is the combination of all outcomes in A and B.
3. Complement (Ac): The complement of an event A, denoted by Ac, is the event that A does not occur. In terms of set theory, the complement is the set of all outcomes that are not in A.
4. Intersection (A∩B): The intersection of two events A and B, denoted by A∩B, is the event that both A and B occur. In terms of set theory, the intersection is the common outcomes in A and B.
Now, let's solve each case step by step:
Case 1: The events A, B, C are disjoint events and P(A) = 2/5.
Given A, B, and C are disjoint, it means they cannot happen at the same time. Therefore, B∩C = Ø (empty set).
Step 1: Find Bc (the complement of B).
Bc is the event that B does not occur. Since A, B, and C are disjoint, Bc = A∪C.
Step 2: Find Cc (the complement of C).
Cc is the event that C does not occur. Since A, B, and C are disjoint, Cc = A∪B.
Step 3: Find (Bc∪Cc)c (the complement of Bc∪Cc).
(Bc∪Cc) is the event that either B or C does not occur, which means at least one of them occurs. Therefore, (Bc∪Cc)c is the event where both B and C occur.
Step 4: Find A∪ (Bc∪Cc)c.
A∪ (Bc∪Cc)c is the event that either A occurs or both B and C occur.
Since A and (Bc∪Cc)c are disjoint events, we can calculate their probabilities separately and add them.
P(A∪ (Bc∪Cc)c) = P(A) + P((Bc∪Cc)c)
P(A∪ (Bc∪Cc)c) = P(A) + P(A∩(Bc∪Cc)) (using P(A∩B) = P(A) + P(B) - P(A∪B))
P(A∪ (Bc∪Cc)c) = P(A) + P((Ac∩Bc)∪(Ac∩Cc))
Since A, B, and C are disjoint, we know that Ac∩Bc = Ø and Ac∩Cc = Ø.
P(A∪ (Bc∪Cc)c) = P(A) + P(Ø∪Ø)
P(A∪ (Bc∪Cc)c) = P(A)
Therefore, in this case, P(A∪ (Bc∪Cc)c) = 2/5.
Case 2: The events A and C are disjoint, P(A) = 1/2, and P(B∩C) = 1/4.
Step 1: Find Bc (the complement of B).
Bc is the event that B does not occur.
Step 2: Find Cc (the complement of C).
Cc is the event that C does not occur.
Step 3: Find (Bc∪Cc).
(Bc∪Cc) is the event that either B or C does not occur, which means at least one of them occurs.
Step 4: Find (Bc∪Cc)c (the complement of Bc∪Cc).
(Bc∪Cc)c is the event where both B and C occur.
Step 5: Find P(A∪ (Bc∪Cc)c).
Calculate the probability of A∪ (Bc∪Cc)c using the steps mentioned in Case 1.
Case 3: Given P(Ac∩(Bc∪Cc)) = 0.7.
Step 1: Find Bc (the complement of B).
Bc is the event that B does not occur.
Step 2: Find Cc (the complement of C).
Cc is the event that C does not occur.
Step 3: Find (Bc∪Cc).
(Bc∪Cc) is the event that either B or C does not occur, which means at least one of them occurs.
Step 4: Find Ac∩(Bc∪Cc).
Ac∩(Bc∪Cc) is the event where A does not occur, and at least one of B or C occurs.
Step 5: Calculate the probability of Ac∩(Bc∪Cc). In this case, it is given as 0.7.
These steps should help you find the value of P(A∪(Bc∪Cc)c) for each case.