Answer:
The reliability of the first system to work is 0.72 whereas the reliability of the second system to work is 0.98.As the reliability of the second system is more than the first one so the second system is more reliable.
Step-by-step explanation:
For first system as given in the attached diagram gives,
[tex]P(W_1W_2)=P(W_1) \times P(W_2)[/tex]
As the systems are independent.
The given data indicates that
- [tex]P(W_1)[/tex] is given as 0.9
- [tex]P(W_2)[/tex] is given as 0.8
Now the probability of the system is given as
[tex]P(W_1W_2)=P(W_1) \times P(W_2)\\P(W_1W_2)=0.9 \times 0.8\\P(W_1W_2)=0.72[/tex]
So the reliability of the first system to work is 0.72.
For the second system is given as
[tex]P(W_1W_2)=1-P(W_1'W_2')[/tex]
Where
- [tex]P(W_1'W_2')[/tex] is the probability where both of the systems does not work. this is calculated as
[tex]P(W_1'W_2')=P(W_1') \times P(W_2')\\P(W_1'W_2')=(1-P(W_1)) \times (1-P(W_2))\\P(W_1'W_2')=(1-0.9) \times (1-0.8)\\P(W_1'W_2')=(0.1) \times (0.2)\\P(W_1'W_2')=0.02[/tex]
So now the probability of the second system is given as
[tex]P(W_1W_2)=1-P(W_1'W_2')\\P(W_1W_2)=1-0.02\\P(W_1W_2)=0.98[/tex]
So the reliability of the second system to work is 0.98.
As the reliability of the second system is more than the first one so the second system is more reliable.
