Generating functions

Generating functions MA 4030-probability generating fnctions

Generating functions • Definition: Let a0,a1,……an,….be a sequence of real numbers and let • If the series converges in some real interval (-x0, x0), |x|≤ x0 the function A(x) is called a generating function for {aj}. MA 4030-probability generating fnctions

The generating function may be regarded as a transformation which carries the sequence {aj} into A(x).In general x will be a real number. However, it is possible to work with the complex numbers as well. • If, the sequence {aj}. is bounded , then a comparison with the geometric series shows that A(x) converges at least for |x| ≤1. MA 4030-probability generating fnctions

Probability Generating function • If we have the additional property that: aj ≥0 and • then A(x) is called a probability generating function. MA 4030-probability generating fnctions

Proposition • A generating function uniquely determines its sequence. • This single function A(x) can be used to represent the whole collection of individual items {aj}. • Uses of probability generating functions To find the density/mass function To find the Moments in stochastic models To Calculate limit distributions In difference equations or recursions MA 4030-probability generating fnctions

Example: • Let us consider a random variable X, where the probability, P[X=j]=pj • Suppose X is an integral valued random variable with values 0,1,2,……. • Then we can define the tail probabilities as Pr[X > j] = qj • The distribution function is thus Pr[X≤j] = 1- qj MA 4030-probability generating fnctions

The probability generating function is • The generating function, • is not a p.g.f. since . MA 4030-probability generating fnctions

Some useful results: • 1) 1-P(x) = (1-x) (Q(x)) • 2.) P’(1) = Q(1) • 3.) P’’(1) = 2Q’(1) • 4.) V(x)=P’’(1)+P’(1)-[P’(1)]2 =2’Q’(1) +Q(1)-[Q(1)]2 • 5) the rth factorial moment or rth moment about the origin, • µ’(r) = E [X(X-1) (X-2)……(X-r+1) • = P(r) (1) = rQ (r-1) (1) MA 4030-probability generating fnctions

Convolutions • Consider two non negative independent integral valued random variables X and Y, having the probability distribution, • P[X=j] = aj and P[Y=k] = bk • The probability of the event (X=j,Y=k) is therefore • Pr[ (X=j,Y=k)]= aj bk MA 4030-probability generating fnctions

Suppose we form a new random variable S=X+Y • Then the event S=r comprises the mutually exclusive events, (X=0,Y=r),(X=1,Y=r-1),….(X=m,Y=r-m), ………..(X=r-1,Y=1),(X=r,Y=0) If the distribution of S is given by P[S=r]=cr Then it follows that : Cr=a0br+a1br-1+…………..+arb0 This method of compoundingtwo sequences of numbers is called a convolution {cj}={aj}{bj] MA 4030-probability generating fnctions

Generating functions and Convolutions: • Proposition : The generating function of a convolution ({cj} ) is the product of the generating functions ({aj},{bj}) . MA 4030-probability generating fnctions

Define the associated probability generating functions of the sequences defined earlier. MA 4030-probability generating fnctions

Proof:Suppose we form a new random variable S=X+Y. Let S=n and P[S=n]=cn • Then the corresponding generating function is • Ctd… MA 4030-probability generating fnctions

MA 4030-probability generating fnctions

Extensions to convolution: • More generally the generating function of {aj},{bj},{cj},…is the product of the generating functions of {aj},{bj},{cj},…. • F(x)= A(x).B(x).C(x)…. • Also let X1,X2,…..,Xn be i.i.d r.v.s • and Sn=X1+X2+…..+Xn • Then the g.f.of Sn is [P(x)]n MA 4030-probability generating fnctions

Some properties of convolution 1.The convolution of two probability mass functions on the non negative integers is a pr. Mass function. 2.Convolution is a commutative operation X+Y and Y+X , have the same distribution. 3.It is an associative operation. (order is immaterial) X+(Y+Z) = (X+Y)+ Z , have the same distribution MA 4030-probability generating fnctions

Examples • Find the p.g.f , the mean and the variance of : 1.Bernoulli distribution where, p=P[success]=P[X=1], and q=P[X=0]. Where X= number of successes in a trial. 2.Poisson distribution P[X=r]= e-µ µr/r! eg: X -. number of phone calls in a unit time interval. µ is the average number of phone calls/unit 3.Geometric distribution P[X=j]=pqj X? define 4.Binomial distribution (X_ number of successes in n number of trials.) P[X=r] = nCr pr q n-r , where p= P[success] and q= P[failure] MA 4030-probability generating fnctions

1. For the Bernoulli r.v. • P(s)=[q+ps] the mean =P’[1]=p the variance =P’’[1]+P’[1]-{P’{1]}2 =0+p-p2=p(1-p) =qp 4. For the Binomial r.v. ,which is the sum of n independent r.v.s, P(s)=[q+ps]n Mean=np Variance =npq MA 4030-probability generating fnctions

2. For the Poisson r.v. • P[x]= • The mean =P’[1]= • And the variance=P’’[1]+P’[1]-{P’{1]}2 • = MA 4030-probability generating fnctions

3. For the Geometric r.v. • P[x]= • The mean =P’[x] | x=1= MA 4030-probability generating fnctions

To find the variance, • The variance =P’’[1]+P’[1]-{P’{1]}2 MA 4030-probability generating fnctions

Some more examples: Negative Binomial random variable Y, • The : Where the P{success]=p and P[failure]=q • Number of independent trials for the kth success : Y+k, Or the number of failures before the kth success r.v. Y; • This distribution is called the negative binomial because he probabilities correspond to the successive terms of the binomial expansion of MA 4030-probability generating fnctions

Let Y+k=n and y=n-k • The m.g.f is M( ,t)={q+pe-)}-k • And the p.g.f is P(x,t)=={q+px-1)}-k MA 4030-probability generating fnctions

Note that when k=1, the probability mass function becomes qyp, which is the Geometric distribution. • It can be shown that: P(x)= • Which is the nth power of the p.g.f. of the geometric distribution. • Then it is clear that negative binomial r.v. is the convolution of n geometric random variables. • Its mean MA 4030-probability generating fnctions

Compound Distributions • Consider the sum of n independent random variables, where the number of r.v. contributing to the sum is also a r.v. • Suppose SN=X1+X2+…+XN • Pr[Xi=j]=fj, Pr[N=n]=gn, Pr[SN=k]=hk, • with the corresponding p.g.fs. MA 4030-probability generating fnctions

This property is mainly used in discrete branching processes MA 4030-probability generating fnctions

Moment generating function • Moment generating function (m.g.f) of a r.v. Y is defined as M()=E[e Y] • If Y is a discrete integer valued r.v. with probability P[Y=j]=pj • Then M()= MA 4030-probability generating fnctions

Taylor expansion of of M() generates the • moments given by • M() = • is the rth moment about the origin, • M’()|  = =. =E(X), M’’ ()|  =0 =(E(X(X-1)) MA 4030-probability generating fnctions

If X is a continuous r.v.with a frequency distribution f(u), then we have • And all the other properties as in the discrete case. MA 4030-probability generating fnctions

M.g.f of the Binomial distribution • M()=(q+peθ)n • That is replace x in p.g.f. P(x) by eθ.. • M’()=n(q+peθ)n-1p • E[X}=M’()| =0 =n(q+peθ)n-1p| =0 • = n(q+p)n-1p , since eθ=1 when θ=0 • =np • Similarly it can be shown that V(X)=npq MA 4030-probability generating fnctions

Generating functions

Generating functions

Presentation Transcript

Moment Generating Functions

Moment Generating Functions

Chapter 9 Generating functions

Section 6.2 Calculating Coefficients Of Generating Functions

4.6 Generating functions

Chapter 6.1 Generating Functions

Generating Functions

TGFs Table Generating Functions

Use of moment generating functions

Generating Functions and Counting Trees

generating functions, templates, and macros

Use of moment generating functions

Moment Generating Functions

4.6.2 Exponential generating functions

Probability Generating Functions

Section 6.2 Calculating Coefficients Of Generating Functions

Moment Generating Functions

Composite Generating Functions

generating functions, templates, and macros