Answer:
(a) 0.9412
(b) 0.9996 ≈ 1
Step-by-step explanation:
Denote the events a follows:
[tex]P[/tex] = a person passes the security system
[tex]H[/tex] = a person is a security hazard
Given:
[tex]P (H) = 0.04,\ P(P^{c}|H^{c})=0.02\ and\ P(P|H)=0.01[/tex]
Then,
[tex]P(H^{c})=1-P(H)=1-0.04=0.96\\P(P|H^{c})=1-P(P|H)=1-0.02=0.98\\[/tex]
(a)
Compute the probability that a person passes the security system using the total probability rule as follows:
The total probability rule states that: [tex]P(A)=P(A|B)P(B)+P(A|B^{c})P(B^{c})[/tex]
The value of P (P) is:
[tex]P(P)=P(P|H)P(H)+P(P|H^{c})P(H^{c})\\=(0.01\times0.04)+(0.98\times0.96)\\=0.9412[/tex]
Thus, the probability that a person passes the security system is 0.9412.
(b)
Compute the probability that a person who passes through the system is without any security problems as follows:
[tex]P(H^{c}|P)=\frac{P(P|H^{c})P(H^{c})}{P(P)} \\=\frac{0.98\times0.96}{0.9412} \\=0.9996\\\approx1[/tex]
Thus, the probability that a person who passes through the system is without any security problems is approximately 1.
