Generating function

In mathematics, a generating function is a formal power series in one indeterminate, whose coefficients encode information about a sequence of numbers a_n that is indexed by the natural numbers. Generating functions were first introduced by Abraham de Moivre in 1730, in order to solve the general linear recurrence problem.^[1] One can generalize to formal power series in more than one indeterminate, to encode information about arrays of numbers indexed by several natural numbers.

There are various types of generating functions, including ordinary generating functions, exponential generating functions, Lambert series, Bell series, and Dirichlet series; definitions and examples are given below. Every sequence in principle has a generating function of each type (except that Lambert and Dirichlet series require indexes to start at 1 rather than 0), but the ease with which they can be handled may differ considerably. The particular generating function, if any, that is most useful in a given context will depend upon the nature of the sequence and the details of the problem being addressed.

Generating functions are often expressed in closed form (rather than as a series), by some expression involving operations defined for formal power series. These expressions in terms of the indeterminate x may involve arithmetic operations, differentiation with respect to x and composition with (i.e., substitution into) other generating functions; since these operations are also defined for functions, the result looks like a function of x. Indeed, the closed form expression can often be interpreted as a function that can be evaluated at (sufficiently small) concrete values of x, and which has the formal power series as its Taylor series; this explains the designation "generating functions". However such interpretation is not required to be possible, because formal power series are not required to give a convergent series when a nonzero numeric value is substituted for x. Also, not all expressions that are meaningful as functions of x are meaningful as expressions designating formal power series; negative and fractional powers of x are examples of this.

Generating functions are not functions in the formal sense of a mapping from a domain to a codomain; the name is merely traditional, and they are sometimes more correctly called generating series.^[2]

A generating function is a clothesline on which we hang up a sequence of numbers for display.

— Herbert Wilf, Generatingfunctionology (1994)

The ordinary generating function of a sequence a_n is

${\displaystyle G(a_{n};x)=\sum _{n=0}^{\infty }a_{n}x^{n}.}$

When the term generating function is used without qualification, it is usually taken to mean an ordinary generating function.

If a_n is the probability mass function of a discrete random variable, then its ordinary generating function is called a probability-generating function.

The ordinary generating function can be generalized to arrays with multiple indices. For example, the ordinary generating function of a two-dimensional array a_{m, n} (where n and m are natural numbers) is

${\displaystyle G(a_{m,n};x,y)=\sum _{m,n=0}^{\infty }a_{m,n}x^{m}y^{n}.}$

The exponential generating function of a sequence a_n is

${\displaystyle \operatorname {EG} (a_{n};x)=\sum _{n=0}^{\infty }a_{n}{\frac {x^{n}}{n!}}.}$

The Poisson generating function of a sequence a_n is

${\displaystyle \operatorname {PG} (a_{n};x)=\sum _{n=0}^{\infty }a_{n}e^{-x}{\frac {x^{n}}{n!}}=e^{-x}\,\operatorname {EG} (a_{n};x)\,.}$

The Lambert series of a sequence a_n is

${\displaystyle \operatorname {LG} (a_{n};x)=\sum _{n=1}^{\infty }a_{n}{\frac {x^{n}}{1-x^{n}}}.}$

Note that in a Lambert series the index n starts at 1, not at 0.

The Bell series of an arithmetic function f(n) and a prime p is

${\displaystyle f_{p}(x)=\sum _{n=0}^{\infty }f(p^{n})x^{n}.}$

Dirichlet series are often classified as generating functions, although they are not strictly formal power series. The Dirichlet series generating function of a sequence a_n is

${\displaystyle \operatorname {DG} (a_{n};s)=\sum _{n=1}^{\infty }{\frac {a_{n}}{n^{s}}}.}$

The Dirichlet series generating function is especially useful when a_n is a multiplicative function, when it has an Euler product expression in terms of the function's Bell series

${\displaystyle \operatorname {DG} (a_{n};s)=\prod _{p}f_{p}(p^{-s})\,.}$

If a_n is a Dirichlet character then its Dirichlet series generating function is called a Dirichlet L-series.

The idea of generating functions can be extended to sequences of other objects. Thus, for example, polynomial sequences of binomial type are generated by

${\displaystyle e^{xf(t)}=\sum _{n=0}^{\infty }{p_{n}(x) \over n!}t^{n}}$

where p_n(x) is a sequence of polynomials and f(t) is a function of a certain form. Sheffer sequences are generated in a similar way. See the main article generalized Appell polynomials for more information.

Polynomials are a special case of ordinary generating functions, corresponding to finite sequences, or equivalently sequences that vanish after a certain point. These are important in that many finite sequences can usefully be interpreted as generating functions, such as the Poincaré polynomial, and others.

A key generating function is the constant sequence 1, 1, 1, 1, 1, 1, 1, 1, 1, ..., whose ordinary generating function is

${\displaystyle \sum _{n=0}^{\infty }x^{n}={1 \over 1-x}.}$

The left hand side is the Maclaurin series expansion of the right hand side. Alternatively, the right hand side expression can be justified by multiplying the power series on the left by 1 − x, and checking that the result is the constant power series 1, in other words that all coefficients vanish, except the one of x⁰. Moreover there can be no other power series with this property. The left hand side therefore designates the multiplicative inverse of 1 − x in the ring of power series.

Expressions for the ordinary generating of other sequences are easily derived for this one. For instance for the geometric sequence 1,a,a²,a³,... for any constant a one has

${\displaystyle \sum _{n=0}^{\infty }a^{n}x^{n}={1 \over 1-ax},}$

and in particular

${\displaystyle \sum _{n=0}^{\infty }(-1)^{n}x^{n}={1 \over 1+x}.}$

One can also introduce regular "gaps" in the sequence by replacing x by some power of x, so for instance for the sequence 1, 0, 1, 0, 1, 0, 1, 0, .... one gets the generating function

${\displaystyle \sum _{n=0}^{\infty }x^{2n}={1 \over 1-x^{2}}.}$

Computing the square of the initial generating function, one easily sees that the coefficients form the sequence 1, 2, 3, 4, 5, ..., so one has

${\displaystyle \sum _{n=0}^{\infty }(n+1)x^{n}={1 \over (1-x)^{2}},}$

and the third power has as coefficients the triangular numbers 1, 3, 6, 10, 15, 21, ... whose term n is the binomial coefficient ${\displaystyle {\tbinom {n+2}{2}}}$, so that

${\displaystyle \sum _{n=0}^{\infty }{\tbinom {n+2}{2}}x^{n}={1 \over (1-x)^{3}}.}$

Since

${\displaystyle {\binom {n+2}{2}}={\frac {1}{2}}{(n+1)(n+2)}={\frac {1}{2}}(n^{2}+3n+2),}$

one can find the ordinary generating function for the sequence 0, 1, 4, 9, 16, ... of square numbers by linear combination of the preceding sequences;

${\displaystyle G(n^{2};x)=\sum _{n=0}^{\infty }n^{2}x^{n}={2 \over (1-x)^{3}}-{3 \over (1-x)^{2}}+{1 \over 1-x}={\frac {x(x+1)}{(1-x)^{3}}}.}$

The ordinary generating function of a sequence can be expressed as a rational function (the ratio of two polynomials) if and only if the sequence is a linear recursive sequence; this generalizes the examples above.

Multiplication of ordinary generating functions yields a discrete convolution (the Cauchy product) of the sequences. For example, the sequence of cumulative sums ${\displaystyle (a_{0},a_{0}+a_{1},a_{0}+a_{1}+a_{2},\ldots )}$ of a sequence with ordinary generating function G(a_n; x) has the generating function ${\displaystyle G(a_{n};x){\frac {1}{1-x}}}$ because 1/(1-x) is the ordinary generating function for the sequence (1, 1, ...).

When the series converges absolutely, ${\displaystyle G\left(a_{n};e^{-i\omega }\right)=\sum _{n=0}^{\infty }a_{n}e^{-i\omega n}}$ is the discrete-time Fourier transform of the sequence a₀, a₁, ....

In calculus, often the growth rate of the coefficients of a power series can be used to deduce a radius of convergence for the power series. The reverse can also hold; often the radius of convergence for a generating function can be used to deduce the asymptotic growth of the underlying sequence.

For instance, if an ordinary generating function G(a_n; x) that has a finite radius of convergence of r can be written as

${\displaystyle G(a_{n};x)={\frac {A(x)+B(x)(1-x/r)^{-\beta }}{x^{\alpha }}}\,}$

where A(x) and B(x) are functions that are analytic to a radius of convergence greater than r (or are entire), and where B(r) ≠ 0 then

${\displaystyle a_{n}\sim {\frac {B(r)}{r^{\alpha }\Gamma (\beta )}}\,n^{\beta -1}(1/r)^{n}\,,}$

using the Gamma function.

As derived above, the ordinary generating function for the sequence of squares is ${\displaystyle {\frac {x(x+1)}{(1-x)^{3}}}\,.}$ With r = 1, α = 0, β = 3, A(x) = 0, and B(x) = x(x+1), we can verify that the squares grow as expected, like the squares:

${\displaystyle a_{n}\sim {\frac {B(r)}{r^{\alpha }\Gamma (\beta )}}\,n^{\beta -1}(1/r)^{n}={\frac {1(1+1)}{1^{0}\,\Gamma (3)}}\,n^{3-1}(1/1)^{n}=n^{2}\,.}$

The ordinary generating function for the Catalan numbers is ${\displaystyle {\frac {1-{\sqrt {1-4x}}}{2x}}\,.}$ With r = 1/4, α = 1, β = −1/2, A(x) = 1/2, and B(x) = −1/2, we can conclude that, for the Catalan numbers,

${\displaystyle a_{n}\sim {\frac {B(r)}{r^{\alpha }\Gamma (\beta )}}\,n^{\beta -1}(1/r)^{n}={\frac {-1/2}{(1/4)^{1}\Gamma (-1/2)}}\,n^{-1/2-1}\left({\frac {1}{1/4}}\right)^{n}={\frac {n^{-3/2}\,4^{n}}{\sqrt {\pi }}}\,.}$

One can define generating functions in several variables, for arrays with several indices. These are often called super generating functions, and for 2 variables are often called bivariate generating functions.

For instance, since ${\displaystyle (1+x)^{n}}$ is the ordinary generating function for binomial coefficients for a fixed n, one may ask for a bivariate generating function that generates the binomial coefficients ${\displaystyle {\binom {n}{k}}}$ for all k and n. To do this, consider ${\displaystyle (1+x)^{n}}$ as itself a series (in n), and find the generating function in y that has these as coefficients. Since the generating function for ${\displaystyle a^{n}}$ is just ${\displaystyle 1/(1-ay)}$, the generating function for the binomial coefficients is:

${\displaystyle {\frac {1}{1-(1+x)y}}=1+(1+x)y+(1+x)^{2}y^{2}+\dots ,}$

and the coefficient on ${\displaystyle x^{k}y^{n}}$ is the ${\displaystyle {\binom {n}{k}}}$ binomial coefficient.

Generating functions for the sequence of square numbers a_n = n² are:

${\displaystyle G(n^{2};x)=\sum _{n=0}^{\infty }n^{2}x^{n}={\frac {x(x+1)}{(1-x)^{3}}}}$

${\displaystyle \operatorname {EG} (n^{2};x)=\sum _{n=0}^{\infty }{\frac {n^{2}x^{n}}{n!}}=x(x+1)e^{x}}$

${\displaystyle f_{p}(x)=\sum _{n=0}^{\infty }p^{2n}x^{n}={\frac {1}{1-p^{2}x}}}$

${\displaystyle \operatorname {DG} (n^{2};s)=\sum _{n=1}^{\infty }{\frac {n^{2}}{n^{s}}}=\zeta (s-2)\,,}$

using the Riemann zeta function.

Multivariate generating functions arise in practice when calculating the number of contingency tables of non-negative integers with specified row and column totals. Suppose the table has r rows and c columns; the row sums are ${\displaystyle t_{1},\ldots t_{r}}$ and the column sums are ${\displaystyle s_{1},\ldots s_{c}}$. Then, according to I. J. Good ^[3], the number of such tables is the coefficient of ${\displaystyle x_{1}^{t_{1}}\ldots x_{r}^{t_{r}}y_{1}^{s_{1}}\ldots y_{c}^{s_{c}}}$ in

${\displaystyle \prod _{i=1}^{r}\prod _{j=1}^{c}{\frac {1}{1-x_{i}y_{j}}}.}$

Generating functions are used to

• Find a closed formula for a sequence given in a recurrence relation. For example consider Fibonacci numbers.
• Find recurrence relations for sequences – the form of a generating function may suggest a recurrence formula.
• Find relationships between sequences – if the generating functions of two sequences have a similar form, then the sequences themselves are probably related.
• Explore the asymptotic behaviour of sequences.
• Prove identities involving sequences.
• Solve enumeration problems in combinatorics and encoding their solutions. Rook polynomials are an example of an application in combinatorics.
• Evaluate infinite sums.

Examples of polynomial sequences generated by more complex generating functions include:

• Appell polynomials
• Chebyshev polynomials
• Difference polynomials
• Generalized Appell polynomials
• Q-difference polynomials

Polynomial interpolation is finding a polynomial whose values (not coefficients) agree with a given sequence; the Hilbert polynomial is an abstract case of this in commutative algebra.

• Moment-generating function
• Probability-generating function
• Stanley's reciprocity theorem
• Applications to partitions.
• Combinatorial principles

• Herbert S. Wilf (1994). Generatingfunctionology (second ed.). Academic Press. ISBN 0-12-751956-4.

• Ronald L. Graham, Donald E. Knuth, and Oren Patashnik. Concrete Mathematics. A foundation for computer science (second ed.). Addison-Wesley. pp. 320–380. ISBN 0-201-55802-5. {{cite book}}: Unknown parameter |part= ignored (help)CS1 maint: multiple names: authors list (link)

• Doubilet, Peter; Rota, Gian-Carlo; Stanley, Richard (1972). "On the foundations of combinatorial theory. VI. The idea of generating function". Proceedings of the Sixth Berkeley Symposium on Mathematical Statistics and Probability. 2: 267–318.{{cite journal}}: CS1 maint: postscript (link)

• Generating Functions, Power Indices and Coin Change at cut-the-knot
• Generatingfunctionology PDF download page
• 1031 Generating Functions
• Ignacio Larrosa Cañestro, León-Sotelo, Marko Riedel, Georges Zeller, Suma de números equilibrados, newsgroup es.ciencia.matematicas
• Frederick Lecue; Riedel, Marko, et al., Permutation, Les-Mathematiques.net, in French, title somewhat misleading.
• "Generating Functions" by Ed Pegg, Jr., Wolfram Demonstrations Project, 2007.