4.1 Matlab and independent classes  (Page 3/4)

Probabilities of boolean combinations

As in the nonindependent case, we may utilize the minterm expansion and the minterm probabilities to calculate the probabilities of Boolean combinations of events. However,it is frequently more efficient to manipulate the expressions for the Boolean combination to be a disjoint union of intersections.

In larger problems, or in situations where probabilities of several Boolean combinations are to be determined, it may be desirable to calculate all minterm probabilities then use theminterm vector techniques introduced earlier to calculate probabilities for various Boolean combinations. As a larger example for which computational aid is highly desirable, consideragain the class and the probabilities utilized in [link] , above.

Independent boolean combinations

Suppose we have a Boolean combination of the events in the class $\{A_i:1\le i\le n\}$ and a second combination the events in the class $\{B_j:1\le j\le m\}$ . If the combined class $\{A_i,B_j:1\le i\le n,1\le j\le m\}$ is independent, we would expect the combinations of the subclasses to be independent. It is importantto see that this is in fact a consequence of the product rule, for it is further evidence that the product rule has captured the essence of the intuitive notion of independence.In the following discussion, we exhibit the essential structure which provides the basis for the following general proposition.

Proposition . Consider n distinct subclasses of an independent class of events. If for each i the event A _i is a Boolean (logical) combination of members of the i th subclass, then the class $\{A_1,A_2,\cdots ,A_n\}$ is an independent class.