Answer:
p(j or k or l) = p(j) + p(k) + p(l) - p(j ∩ k) - p(k ∩ l) - p(l ∩ j) + p(j ∩ k ∩ l)
Step-by-step explanation:
First let j ∪ k = m.
Then, p(j or k or l) = p(j ∪ k ∪ l) = p(m ∪ l)
Here, m and l are not mutually exclusive.
However, we can write the m ∪ l as a union of two disjoint sets as below:
m ∪ l = m ∪ (m' ∩ l)
where m and m' ∩ l are mutually exclusive.
Now, p(m ∪ l) = p[m ∪ (m' ∩ l)]
= p(m) + p(m' ∩ l)
p(m' ∩ l) = p(l) - p(m ∩ l)
So, p(m ∪ l) = p(m) + p(l) - p(m ∩ l) --- (1)
Now, p(m) = p(j ∪ k)
= p(j) + p(k) - p(j ∩ k) from the result of (1)
Also, p(m ∩ l) = p[(j ∪ k) ∩ l]
= p(j ∩ l) ∪ p(k ∩ l)
= p(j ∩ l) + p(k ∩ l) - p[(j ∩ l) ∩ (k ∩ l)]
= p(j ∩ l) + p(k ∩ l) - p(j ∩ k ∩ l)
Hence, (1) becomes
p(j ∪ k ∪ l) = p(j) + p(k) + p(l) - p(j ∩ k) - p(k ∩ l) - p(l ∩ j) + p(j ∩ k ∩ l)
