a. The events are mutually exclusive, so
[tex]P(A\cup B\cup C)=P(A)+P(B)+P(C)=\boxed{0.9}[/tex]
b. For the same reason,
[tex]P(A\cap B\cap C)=\boxed0[/tex]
Another way to see this is to use the result from part (a), and the inclusion/exclusion principle:
[tex]P(A\cap B\cap C)=P(A)+P(B)+P(C)-P(A\cup B\cup C)[/tex]
and the right side reduces to 0.
c. Same as (b),
[tex]P(A\cap B)=\boxed0[/tex]
d. Same as (b),
[tex]P((A\cup B)\cap C)=\boxed0[/tex]
We can also use the distributivity rule for unions and intersections to write
[tex]P((A\cup B)\cap C)=P((A\cap C)\cup(B\cap C))=P(A\cap C)+P(B\cap C)=0[/tex]
e. If the [tex]A'[/tex] is the complement of [tex]A[/tex], then by DeMorgan's law,
[tex]P(A'\cap B'\cap C')=P(A\cup B\cup C)'=1-P(A\cup B\cup C)=\boxed{0.1}[/tex]
