CHAP.  21                        RANDOM  VARIABLES
















                            Fig. 2-2  One random variable associated with coin tossing.


          These events have probabilities that are denoted by
                                        P(X = x) = P{C: X(6) = X}
                                        P(X 5 x) = P(6: X(6) 5 x}
                                        P(X > x) = P{C: X(6) > x)
                                   P(x, < X  I x,)  = P{(: x, < X(C) I  x,)
        EXAMPLE 2.2  In the experiment of  tossing a fair  coin three  times (Prob.  1.1), the sample space S,  consists of
        eight equally likely sample points S, = (HHH, . . . , TTT). If X  is the r.v. giving the number of heads obtained, find
        (a) P(X = 2); (b) P(X < 2).
        (a)  Let A c S, be the event defined by X  = 2. Then, from Prob. 1.1, we have
                                A = (X = 2) = {C: X(C) = 2) = {HHT, HTH, THH)
           Since the sample points are equally likely, we have
                                            P(X = 2) = P(A) = 3
        (b)  Let B c S, be the event defined by X < 2. Then
                              B = (X < 2) = {c: X(() < 2) = (HTT, THT, TTH, TTT)
           and                           P(X < 2) = P(B) = 3 = 4


        2.3  DISTRIBUTION FUNCTIONS
        A.  Definition :
             The distribution function  [or cumulative distributionfunction (cdf)] of X  is the function defined by


          Most of  the information  about a  random  experiment described by  the r.v. X is determined  by  the
          behavior of FAX).


        B.  Properties of FAX) :
             Several properties of FX(x) follow directly from its definition (2.4).


          2.  Fx(xl) I Fx(x,)   if  x, < x2
          3.  lim F,(x)  = Fx(oo) = 1
             x-'m
          4.   lim  FAX) = Fx(-  oo) = 0
             x-r-m
          5.  lim FAX) = Fda+) = Fx(a)   a+ =  lim  a + E
             x+a+                           O<&+O