Generating function

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In mathematics, a generating function is a representation of an infinite sequence of numbers as the coefficients of a formal power series. Generating functions are often expressed in closed form (rather than as a series), by some expression involving operations on the formal series.

Contents

There are various types of generating functions, including ordinary generating functions, exponential generating functions, Lambert series, Bell series, and Dirichlet series. Every sequence in principle has a generating function of each type (except that Lambert and Dirichlet series require indices 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 sometimes called generating series, [1] in that a series of terms can be said to be the generator of its sequence of term coefficients.

History

Generating functions were first introduced by Abraham de Moivre in 1730, in order to solve the general linear recurrence problem. [2]

George Pólya writes in Mathematics and plausible reasoning :

The name "generating function" is due to Laplace. Yet, without giving it a name, Euler used the device of generating functions long before Laplace [..]. He applied this mathematical tool to several problems in Combinatory Analysis and the Theory of Numbers.

Definition

A generating function is a device somewhat similar to a bag. Instead of carrying many little objects detachedly, which could be embarrassing, we put them all in a bag, and then we have only one object to carry, the bag.

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

Convergence

Unlike an ordinary series, the formal power series is not required to converge: in fact, the generating function is not actually regarded as a function, and the "variable" remains an indeterminate. One can generalize to formal power series in more than one indeterminate, to encode information about infinite multi-dimensional arrays of numbers. Thus generating functions are not functions in the formal sense of a mapping from a domain to a codomain.

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 series as its series expansion; this explains the designation "generating functions". However such interpretation is not required to be possible, because formal series are not required to give a convergent series when a nonzero numeric value is substituted for x.

Limitations

Not all expressions that are meaningful as functions of x are meaningful as expressions designating formal series; for example, negative and fractional powers of x are examples of functions that do not have a corresponding formal power series.

Types

Ordinary generating function (OGF)

When the term generating function is used without qualification, it is usually taken to mean an ordinary generating function. The ordinary generating function of a sequence an is: If an is the probability mass function of a discrete random variable, then its ordinary generating function is called a probability-generating function.

Exponential generating function (EGF)

The exponential generating function of a sequence an is

Exponential generating functions are generally more convenient than ordinary generating functions for combinatorial enumeration problems that involve labelled objects. [3]

Another benefit of exponential generating functions is that they are useful in transferring linear recurrence relations to the realm of differential equations. For example, take the Fibonacci sequence {fn} that satisfies the linear recurrence relation fn+2 = fn+1 + fn. The corresponding exponential generating function has the form

and its derivatives can readily be shown to satisfy the differential equation EF″(x) = EF(x) + EF(x) as a direct analogue with the recurrence relation above. In this view, the factorial term n! is merely a counter-term to normalise the derivative operator acting on xn.

Poisson generating function

The Poisson generating function of a sequence an is

Lambert series

The Lambert series of a sequence an is Note that in a Lambert series the index n starts at 1, not at 0, as the first term would otherwise be undefined.

The Lambert series coefficients in the power series expansions for integers n ≥ 1 are related by the divisor sum The main article provides several more classical, or at least well-known examples related to special arithmetic functions in number theory. As an example of a Lambert series identity not given in the main article, we can show that for |x|, |xq| < 1 we have that [4]

where we have the special case identity for the generating function of the divisor function, d(n) ≡ σ0(n), given by

Bell series

The Bell series of a sequence an is an expression in terms of both an indeterminate x and a prime p and is given by: [5]

Dirichlet series generating functions (DGFs)

Formal Dirichlet series are often classified as generating functions, although they are not strictly formal power series. The Dirichlet series generating function of a sequence an is: [6]

The Dirichlet series generating function is especially useful when an is a multiplicative function, in which case it has an Euler product expression [7] in terms of the function's Bell series:

If an is a Dirichlet character then its Dirichlet series generating function is called a Dirichlet L-series. We also have a relation between the pair of coefficients in the Lambert series expansions above and their DGFs. Namely, we can prove that: if and only if where ζ(s) is the Riemann zeta function. [8]

The sequence ak generated by a Dirichlet series generating function (DGF) corresponding to:has the ordinary generating function:

Polynomial sequence generating functions

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

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

Other generating functions

Other sequences generated by more complex generating functions include:

Convolution polynomials

Knuth's article titled "Convolution Polynomials" [9] defines a generalized class of convolution polynomial sequences by their special generating functions of the form for some analytic function F with a power series expansion such that F(0) = 1.

We say that a family of polynomials, f0, f1, f2, ..., forms a convolution family if deg fnn and if the following convolution condition holds for all x, y and for all n ≥ 0:

We see that for non-identically zero convolution families, this definition is equivalent to requiring that the sequence have an ordinary generating function of the first form given above.

A sequence of convolution polynomials defined in the notation above has the following properties:

  • The sequence n! · fn(x) is of binomial type
  • Special values of the sequence include fn(1) = [zn] F(z) and fn(0) = δn,0, and
  • For arbitrary (fixed) , these polynomials satisfy convolution formulas of the form

For a fixed non-zero parameter , we have modified generating functions for these convolution polynomial sequences given by where 𝓕t(z) is implicitly defined by a functional equation of the form 𝓕t(z) = F(x𝓕t(z)t). Moreover, we can use matrix methods (as in the reference) to prove that given two convolution polynomial sequences, fn(x) ⟩ and gn(x) ⟩, with respective corresponding generating functions, F(z)x and G(z)x, then for arbitrary t we have the identity

Examples of convolution polynomial sequences include the binomial power series, 𝓑t(z) = 1 + z𝓑t(z)t, so-termed tree polynomials, the Bell numbers, B(n), the Laguerre polynomials, and the Stirling convolution polynomials.

Ordinary generating functions

Examples for simple sequences

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 fundamental generating function is that of the constant sequence 1, 1, 1, 1, 1, 1, 1, 1, 1, ..., whose ordinary generating function is the geometric series

The left-hand side is the Maclaurin series expansion of the right-hand side. Alternatively, the equality 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 except the one of x0 are equal to 0). 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 function of other sequences are easily derived from this one. For instance, the substitution xax gives the generating function for the geometric sequence 1, a, a2, a3, ... for any constant a:

(The equality also follows directly from the fact that the left-hand side is the Maclaurin series expansion of the right-hand side.) In particular,

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, ... (which skips over x, x3, x5, ...) one gets the generating function

By squaring the initial generating function, or by finding the derivative of both sides with respect to x and making a change of running variable nn + 1, one sees that the coefficients form the sequence 1, 2, 3, 4, 5, ..., so one has

and the third power has as coefficients the triangular numbers 1, 3, 6, 10, 15, 21, ... whose term n is the binomial coefficient (n + 2
2
)
, so that

More generally, for any non-negative integer k and non-zero real value a, it is true that

Since

one can find the ordinary generating function for the sequence 0, 1, 4, 9, 16, ... of square numbers by linear combination of binomial-coefficient generating sequences:

We may also expand alternately to generate this same sequence of squares as a sum of derivatives of the geometric series in the following form:

By induction, we can similarly show for positive integers m ≥ 1 that [10] [11]

where {n
k
}
denote the Stirling numbers of the second kind and where the generating function

so that we can form the analogous generating functions over the integral mth powers generalizing the result in the square case above. In particular, since we can write

we can apply a well-known finite sum identity involving the Stirling numbers to obtain that [12]

Rational functions

The ordinary generating function of a sequence can be expressed as a rational function (the ratio of two finite-degree polynomials) if and only if the sequence is a linear recursive sequence with constant coefficients; this generalizes the examples above. Conversely, every sequence generated by a fraction of polynomials satisfies a linear recurrence with constant coefficients; these coefficients are identical to the coefficients of the fraction denominator polynomial (so they can be directly read off). This observation shows it is easy to solve for generating functions of sequences defined by a linear finite difference equation with constant coefficients, and then hence, for explicit closed-form formulas for the coefficients of these generating functions. The prototypical example here is to derive Binet's formula for the Fibonacci numbers via generating function techniques.

We also notice that the class of rational generating functions precisely corresponds to the generating functions that enumerate quasi-polynomial sequences of the form [13]

where the reciprocal roots, , are fixed scalars and where pi(n) is a polynomial in n for all 1 ≤ i.

In general, Hadamard products of rational functions produce rational generating functions. Similarly, if

is a bivariate rational generating function, then its corresponding diagonal generating function,

is algebraic. For example, if we let [14]

then this generating function's diagonal coefficient generating function is given by the well-known OGF formula

This result is computed in many ways, including Cauchy's integral formula or contour integration, taking complex residues, or by direct manipulations of formal power series in two variables.

Operations on generating functions

Multiplication yields convolution

Multiplication of ordinary generating functions yields a discrete convolution (the Cauchy product) of the sequences. For example, the sequence of cumulative sums (compare to the slightly more general Euler–Maclaurin formula) of a sequence with ordinary generating function G(an; x) has the generating function because 1/1 − x is the ordinary generating function for the sequence (1, 1, ...). See also the section on convolutions in the applications section of this article below for further examples of problem solving with convolutions of generating functions and interpretations.

Shifting sequence indices

For integers m ≥ 1, we have the following two analogous identities for the modified generating functions enumerating the shifted sequence variants of gnm and gn + m, respectively:

Differentiation and integration of generating functions

We have the following respective power series expansions for the first derivative of a generating function and its integral:

The differentiation–multiplication operation of the second identity can be repeated k times to multiply the sequence by nk, but that requires alternating between differentiation and multiplication. If instead doing k differentiations in sequence, the effect is to multiply by the kth falling factorial:

Using the Stirling numbers of the second kind, that can be turned into another formula for multiplying by as follows (see the main article on generating function transformations):

A negative-order reversal of this sequence powers formula corresponding to the operation of repeated integration is defined by the zeta series transformation and its generalizations defined as a derivative-based transformation of generating functions, or alternately termwise by and performing an integral transformation on the sequence generating function. Related operations of performing fractional integration on a sequence generating function are discussed here.

Enumerating arithmetic progressions of sequences

In this section we give formulas for generating functions enumerating the sequence {fan + b} given an ordinary generating function F(z), where a ≥ 2, 0 ≤ b < a, and a and b are integers (see the main article on transformations). For a = 2, this is simply the familiar decomposition of a function into even and odd parts (i.e., even and odd powers):

More generally, suppose that a ≥ 3 and that ωa = exp 2πi/a denotes the ath primitive root of unity. Then, as an application of the discrete Fourier transform, we have the formula [15]

For integers m ≥ 1, another useful formula providing somewhat reversed floored arithmetic progressions — effectively repeating each coefficient m times — are generated by the identity [16]

P-recursive sequences and holonomic generating functions

Definitions

A formal power series (or function) F(z) is said to be holonomic if it satisfies a linear differential equation of the form [17]

where the coefficients ci(z) are in the field of rational functions, . Equivalently, is holonomic if the vector space over spanned by the set of all of its derivatives is finite dimensional.

Since we can clear denominators if need be in the previous equation, we may assume that the functions, ci(z) are polynomials in z. Thus we can see an equivalent condition that a generating function is holonomic if its coefficients satisfy a P-recurrence of the form

for all large enough nn0 and where the ĉi(n) are fixed finite-degree polynomials in n. In other words, the properties that a sequence be P-recursive and have a holonomic generating function are equivalent. Holonomic functions are closed under the Hadamard product operation on generating functions.

Examples

The functions ez, log z, cos z, arcsin z, , the dilogarithm function Li2(z), the generalized hypergeometric functions pFq(...; ...; z) and the functions defined by the power series

and the non-convergent

are all holonomic.

Examples of P-recursive sequences with holonomic generating functions include fn1/n + 1(2n
n
)
and fn2n/n2 + 1, where sequences such as and log n are notP-recursive due to the nature of singularities in their corresponding generating functions. Similarly, functions with infinitely many singularities such as tan z, sec z, and Γ(z) are not holonomic functions.

Software for working with P-recursive sequences and holonomic generating functions

Tools for processing and working with P-recursive sequences in Mathematica include the software packages provided for non-commercial use on the RISC Combinatorics Group algorithmic combinatorics software site. Despite being mostly closed-source, particularly powerful tools in this software suite are provided by the Guess package for guessing P-recurrences for arbitrary input sequences (useful for experimental mathematics and exploration) and the Sigma package which is able to find P-recurrences for many sums and solve for closed-form solutions to P-recurrences involving generalized harmonic numbers. [18] Other packages listed on this particular RISC site are targeted at working with holonomic generating functions specifically.

Relation to discrete-time Fourier transform

When the series converges absolutely, is the discrete-time Fourier transform of the sequence a0, a1, ....

Asymptotic growth of a sequence

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(an; x) that has a finite radius of convergence of r can be written as

where each of A(x) and B(x) is a function that is analytic to a radius of convergence greater than r (or is entire), and where B(r) ≠ 0 then using the gamma function, a binomial coefficient, or a multiset coefficient. Note that limit as n goes to infinity of the ratio of an to any of these expressions is guaranteed to be 1; not merely that an is proportional to them.

Often this approach can be iterated to generate several terms in an asymptotic series for an. In particular,

The asymptotic growth of the coefficients of this generating function can then be sought via the finding of A, B, α, β, and r to describe the generating function, as above.

Similar asymptotic analysis is possible for exponential generating functions; with an exponential generating function, it is an/n! that grows according to these asymptotic formulae. Generally, if the generating function of one sequence minus the generating function of a second sequence has a radius of convergence that is larger than the radius of convergence of the individual generating functions then the two sequences have the same asymptotic growth.

Asymptotic growth of the sequence of squares

As derived above, the ordinary generating function for the sequence of squares is:

With r = 1, α = −1, β = 3, A(x) = 0, and B(x) = x + 1, we can verify that the squares grow as expected, like the squares:

Asymptotic growth of the Catalan numbers

The ordinary generating function for the Catalan numbers is

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:

Bivariate and multivariate generating functions

The generating function in several variables can be generalized to arrays with multiple indices. These non-polynomial double sum examples are called multivariate generating functions, or super generating functions. For two variables, these are often called bivariate generating functions.

Bivariate case

The ordinary generating function of a two-dimensional array am,n (where n and m are natural numbers) is: For instance, since (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 (n
k
)
for all k and n. To do this, consider (1 + x)n itself as a sequence in n, and find the generating function in y that has these sequence values as coefficients. Since the generating function for an is: the generating function for the binomial coefficients is: Other examples of such include the following two-variable generating functions for the binomial coefficients, the Stirling numbers, and the Eulerian numbers, where ω and z denote the two variables: [19]

Multivariate case

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 t1, t2 ... tr and the column sums are s1, s2 ... sc. Then, according to I. J. Good, [20] the number of such tables is the coefficient of: in:

Representation by continued fractions (Jacobi-type J-fractions)

Definitions

Expansions of (formal) Jacobi-type and Stieltjes-type continued fractions (J-fractions and S-fractions, respectively) whose hth rational convergents represent 2h-order accurate power series are another way to express the typically divergent ordinary generating functions for many special one and two-variate sequences. The particular form of the Jacobi-type continued fractions (J-fractions) are expanded as in the following equation and have the next corresponding power series expansions with respect to z for some specific, application-dependent component sequences, {abi} and {ci}, where z ≠ 0 denotes the formal variable in the second power series expansion given below: [21]

The coefficients of , denoted in shorthand by jn ≔ [zn] J[∞](z), in the previous equations correspond to matrix solutions of the equations:

where j0k0,0 = 1, jn = k0,n for n ≥ 1, kr,s = 0 if r > s, and where for all integers p, q ≥ 0, we have an addition formula relation given by:

Properties of the hth convergent functions

For h ≥ 0 (though in practice when h ≥ 2), we can define the rational hth convergents to the infinite J-fraction, J[∞](z), expanded by:

component-wise through the sequences, Ph(z) and Qh(z), defined recursively by:

Moreover, the rationality of the convergent function Convh(z) for all h ≥ 2 implies additional finite difference equations and congruence properties satisfied by the sequence of jn, and for Mh ≔ ab2 ⋯ abh + 1 if hMh then we have the congruence

for non-symbolic, determinate choices of the parameter sequences {abi} and {ci} when h ≥ 2, that is, when these sequences do not implicitly depend on an auxiliary parameter such as q, x, or R as in the examples contained in the table below.

Examples

The next table provides examples of closed-form formulas for the component sequences found computationally (and subsequently proved correct in the cited references [22] ) in several special cases of the prescribed sequences, jn, generated by the general expansions of the J-fractions defined in the first subsection. Here we define 0 < |a|, |b|, |q| < 1 and the parameters and x to be indeterminates with respect to these expansions, where the prescribed sequences enumerated by the expansions of these J-fractions are defined in terms of the q-Pochhammer symbol, Pochhammer symbol, and the binomial coefficients.

The radii of convergence of these series corresponding to the definition of the Jacobi-type J-fractions given above are in general different from that of the corresponding power series expansions defining the ordinary generating functions of these sequences.

Examples

Square numbers

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

Generating function typeEquation
Ordinary generating function
Exponential generating function
Bell series
Dirichlet series

where ζ(s) is the Riemann zeta function.

Applications

Generating functions are used to:

Various techniques: Evaluating sums and tackling other problems with generating functions

Example 1: Formula for sums of harmonic numbers

Generating functions give us several methods to manipulate sums and to establish identities between sums.

The simplest case occurs when sn = Σn
k = 0
ak
. We then know that S(z) = A(z)/1 − z for the corresponding ordinary generating functions.

For example, we can manipulate where Hk = 1 + 1/2 + ⋯ + 1/k are the harmonic numbers. Let be the ordinary generating function of the harmonic numbers. Then and thus

Using convolution with the numerator yields which can also be written as

Example 2: Modified binomial coefficient sums and the binomial transform

As another example of using generating functions to relate sequences and manipulate sums, for an arbitrary sequence fn we define the two sequences of sums for all n ≥ 0, and seek to express the second sums in terms of the first. We suggest an approach by generating functions.

First, we use the binomial transform to write the generating function for the first sum as

Since the generating function for the sequence ⟨ (n + 1)(n + 2)(n + 3) fn is given by we may write the generating function for the second sum defined above in the form

In particular, we may write this modified sum generating function in the form of for a(z) = 6(1 − 3z)3, b(z) = 18(1 − 3z)3, c(z) = 9(1 − 3z)3, and d(z) = (1 − 3z)3, where (1 − 3z)3 = 1 − 9z + 27z2 − 27z3.

Finally, it follows that we may express the second sums through the first sums in the following form:

Example 3: Generating functions for mutually recursive sequences

In this example, we reformulate a generating function example given in Section 7.3 of Concrete Mathematics (see also Section 7.1 of the same reference for pretty pictures of generating function series). In particular, suppose that we seek the total number of ways (denoted Un) to tile a 3-by-n rectangle with unmarked 2-by-1 domino pieces. Let the auxiliary sequence, Vn, be defined as the number of ways to cover a 3-by-n rectangle-minus-corner section of the full rectangle. We seek to use these definitions to give a closed form formula for Un without breaking down this definition further to handle the cases of vertical versus horizontal dominoes. Notice that the ordinary generating functions for our two sequences correspond to the series:

If we consider the possible configurations that can be given starting from the left edge of the 3-by-n rectangle, we are able to express the following mutually dependent, or mutually recursive, recurrence relations for our two sequences when n ≥ 2 defined as above where U0 = 1, U1 = 0, V0 = 0, and V1 = 1:

Since we have that for all integers m ≥ 0, the index-shifted generating functions satisfy [note 1] we can use the initial conditions specified above and the previous two recurrence relations to see that we have the next two equations relating the generating functions for these sequences given by which then implies by solving the system of equations (and this is the particular trick to our method here) that

Thus by performing algebraic simplifications to the sequence resulting from the second partial fractions expansions of the generating function in the previous equation, we find that U2n + 1 ≡ 0 and that for all integers n ≥ 0. We also note that the same shifted generating function technique applied to the second-order recurrence for the Fibonacci numbers is the prototypical example of using generating functions to solve recurrence relations in one variable already covered, or at least hinted at, in the subsection on rational functions given above.

Convolution (Cauchy products)

A discrete convolution of the terms in two formal power series turns a product of generating functions into a generating function enumerating a convolved sum of the original sequence terms (see Cauchy product).

  1. Consider A(z) and B(z) are ordinary generating functions.
  2. Consider A(z) and B(z) are exponential generating functions.
  3. Consider the triply convolved sequence resulting from the product of three ordinary generating functions
  4. Consider the m-fold convolution of a sequence with itself for some positive integer m ≥ 1 (see the example below for an application)

Multiplication of generating functions, or convolution of their underlying sequences, can correspond to a notion of independent events in certain counting and probability scenarios. For example, if we adopt the notational convention that the probability generating function, or pgf, of a random variable Z is denoted by GZ(z), then we can show that for any two random variables [23] if X and Y are independent. Similarly, the number of ways to pay n ≥ 0 cents in coin denominations of values in the set {1, 5, 10, 25, 50} (i.e., in pennies, nickels, dimes, quarters, and half dollars, respectively) is generated by the product and moreover, if we allow the n cents to be paid in coins of any positive integer denomination, we arrive at the generating for the number of such combinations of change being generated by the partition function generating function expanded by the infinite q-Pochhammer symbol product of

Example: Generating function for the Catalan numbers

An example where convolutions of generating functions are useful allows us to solve for a specific closed-form function representing the ordinary generating function for the Catalan numbers, Cn. In particular, this sequence has the combinatorial interpretation as being the number of ways to insert parentheses into the product x0 · x1 ·⋯· xn so that the order of multiplication is completely specified. For example, C2 = 2 which corresponds to the two expressions x0 · (x1 · x2) and (x0 · x1) · x2. It follows that the sequence satisfies a recurrence relation given by and so has a corresponding convolved generating function, C(z), satisfying

Since C(0) = 1 ≠ ∞, we then arrive at a formula for this generating function given by

Note that the first equation implicitly defining C(z) above implies that which then leads to another "simple" (of form) continued fraction expansion of this generating function.

Example: Spanning trees of fans and convolutions of convolutions

A fan of order n is defined to be a graph on the vertices {0, 1, ..., n} with 2n − 1 edges connected according to the following rules: Vertex 0 is connected by a single edge to each of the other n vertices, and vertex is connected by a single edge to the next vertex k + 1 for all 1 ≤ k < n. [24] There is one fan of order one, three fans of order two, eight fans of order three, and so on. A spanning tree is a subgraph of a graph which contains all of the original vertices and which contains enough edges to make this subgraph connected, but not so many edges that there is a cycle in the subgraph. We ask how many spanning trees fn of a fan of order n are possible for each n ≥ 1.

As an observation, we may approach the question by counting the number of ways to join adjacent sets of vertices. For example, when n = 4, we have that f4 = 4 + 3 · 1 + 2 · 2 + 1 · 3 + 2 · 1 · 1 + 1 · 2 · 1 + 1 · 1 · 2 + 1 · 1 · 1 · 1 = 21, which is a sum over the m-fold convolutions of the sequence gn = n = [zn] z/(1 − z)2 for m ≔ 1, 2, 3, 4. More generally, we may write a formula for this sequence as from which we see that the ordinary generating function for this sequence is given by the next sum of convolutions as from which we are able to extract an exact formula for the sequence by taking the partial fraction expansion of the last generating function.

Implicit generating functions and the Lagrange inversion formula

One often encounters generating functions specified by a functional equation, instead of an explicit specification. For example, the generating function T(z) for the number of binary trees on n nodes (leaves included) satisfies

The Lagrange inversion theorem is a tool used to explicitly evaluate solutions to such equations.

Lagrange inversion formula  Let be a formal power series with a non-zero constant term. Then the functional equation admits a unique solution in , which satisfies

where the notation returns the coefficient of in .

Applying the above theorem to our functional equation yields (with ):

Via the binomial theorem expansion, for even , the formula returns . This is expected as one can prove that the number of leaves of a binary tree are one more than the number of its internal nodes, so the total sum should always be an odd number. For odd , however, we get

The expression becomes much neater if we let be the number of internal nodes: Now the expression just becomes the th Catalan number.

Introducing a free parameter (snake oil method)

Sometimes the sum sn is complicated, and it is not always easy to evaluate. The "Free Parameter" method is another method (called "snake oil" by H. Wilf) to evaluate these sums.

Both methods discussed so far have n as limit in the summation. When n does not appear explicitly in the summation, we may consider n as a "free" parameter and treat sn as a coefficient of F(z) = Σ snzn, change the order of the summations on n and k, and try to compute the inner sum.

For example, if we want to compute we can treat n as a "free" parameter, and set

Interchanging summation ("snake oil") gives

Now the inner sum is zm + 2k/(1 − z)m + 2k + 1. Thus

Then we obtain

It is instructive to use the same method again for the sum, but this time take m as the free parameter instead of n. We thus set

Interchanging summation ("snake oil") gives

Now the inner sum is (1 + z)n + k. Thus

Thus we obtain for m ≥ 1 as before.

Generating functions prove congruences

We say that two generating functions (power series) are congruent modulo m, written A(z) ≡ B(z) (mod m) if their coefficients are congruent modulo m for all n ≥ 0, i.e., anbn (mod m) for all relevant cases of the integers n (note that we need not assume that m is an integer here—it may very well be polynomial-valued in some indeterminate x, for example). If the "simpler" right-hand-side generating function, B(z), is a rational function of z, then the form of this sequence suggests that the sequence is eventually periodic modulo fixed particular cases of integer-valued m ≥ 2. For example, we can prove that the Euler numbers, satisfy the following congruence modulo 3: [25]

One useful method of obtaining congruences for sequences enumerated by special generating functions modulo any integers (i.e., not only prime powers pk) is given in the section on continued fraction representations of (even non-convergent) ordinary generating functions by J-fractions above. We cite one particular result related to generating series expanded through a representation by continued fraction from Lando's Lectures on Generating Functions as follows:

Theorem: congruences for series generated by expansions of continued fractions  Suppose that the generating function A(z) is represented by an infinite continued fraction of the form and that Ap(z) denotes the pth convergent to this continued fraction expansion defined such that an = [zn] Ap(z) for all 0 ≤ n < 2p. Then:

  1. the function Ap(z) is rational for all p ≥ 2 where we assume that one of divisibility criteria of p | p1, p1p2, p1p2p3 is met, that is, p | p1p2pk for some k ≥ 1; and
  2. if the integer p divides the product p1p2pk, then we have A(z) ≡ Ak(z) (mod p).

Generating functions also have other uses in proving congruences for their coefficients. We cite the next two specific examples deriving special case congruences for the Stirling numbers of the first kind and for the partition function p(n) which show the versatility of generating functions in tackling problems involving integer sequences.

The Stirling numbers modulo small integers

The main article on the Stirling numbers generated by the finite products

provides an overview of the congruences for these numbers derived strictly from properties of their generating function as in Section 4.6 of Wilf's stock reference Generatingfunctionology. We repeat the basic argument and notice that when reduces modulo 2, these finite product generating functions each satisfy

which implies that the parity of these Stirling numbers matches that of the binomial coefficient

and consequently shows that [n
k
]
is even whenever k < ⌊ n/2.

Similarly, we can reduce the right-hand-side products defining the Stirling number generating functions modulo 3 to obtain slightly more complicated expressions providing that

Congruences for the partition function

In this example, we pull in some of the machinery of infinite products whose power series expansions generate the expansions of many special functions and enumerate partition functions. In particular, we recall that the partition function p(n) is generated by the reciprocal infinite q-Pochhammer symbol product (or z-Pochhammer product as the case may be) given by

This partition function satisfies many known congruence properties, which notably include the following results though there are still many open questions about the forms of related integer congruences for the function: [26]

We show how to use generating functions and manipulations of congruences for formal power series to give a highly elementary proof of the first of these congruences listed above.

First, we observe that in the binomial coefficient generating function all of the coefficients are divisible by 5 except for those which correspond to the powers 1, z5, z10, ... and moreover in those cases the remainder of the coefficient is 1 modulo 5. Thus, or equivalently It follows that

Using the infinite product expansions of it can be shown that the coefficient of z5m + 5 in z · ((1 − z)(1 − z2)⋯)4 is divisible by 5 for all m. [27] Finally, since we may equate the coefficients of z5m + 5 in the previous equations to prove our desired congruence result, namely that p(5m + 4) ≡ 0 (mod 5) for all m ≥ 0.

Transformations of generating functions

There are a number of transformations of generating functions that provide other applications (see the main article). A transformation of a sequence's ordinary generating function (OGF) provides a method of converting the generating function for one sequence into a generating function enumerating another. These transformations typically involve integral formulas involving a sequence OGF (see integral transformations) or weighted sums over the higher-order derivatives of these functions (see derivative transformations).

Generating function transformations can come into play when we seek to express a generating function for the sums

in the form of S(z) = g(z) A(f(z)) involving the original sequence generating function. For example, if the sums are then the generating function for the modified sum expressions is given by [28] (see also the binomial transform and the Stirling transform).

There are also integral formulas for converting between a sequence's OGF, F(z), and its exponential generating function, or EGF, (z), and vice versa given by

provided that these integrals converge for appropriate values of z.

Tables of special generating functions

An initial listing of special mathematical series is found here. A number of useful and special sequence generating functions are found in Section 5.4 and 7.4 of Concrete Mathematics and in Section 2.5 of Wilf's Generatingfunctionology. Other special generating functions of note include the entries in the next table, which is by no means complete. [29]

Formal power seriesGenerating-function formulaNotes
is a first-order harmonic number
is a Bernoulli number
is a Fibonacci number and
denotes the rising factorial, or Pochhammer symbol and some integer
is the polylogarithm function and is a generalized harmonic number for
is a Stirling number of the second kind and where the individual terms in the expansion satisfy
The two-variable case is given by

See also

Notes

  1. Incidentally, we also have a corresponding formula when m < 0 given by

Related Research Articles

<span class="mw-page-title-main">Binomial coefficient</span> Number of subsets of a given size

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In mathematics, the Bernoulli numbersBn are a sequence of rational numbers which occur frequently in analysis. The Bernoulli numbers appear in the Taylor series expansions of the tangent and hyperbolic tangent functions, in Faulhaber's formula for the sum of m-th powers of the first n positive integers, in the Euler–Maclaurin formula, and in expressions for certain values of the Riemann zeta function.

In mathematics, a power series is an infinite series of the form where an represents the coefficient of the nth term and c is a constant called the center of the series. Power series are useful in mathematical analysis, where they arise as Taylor series of infinitely differentiable functions. In fact, Borel's theorem implies that every power series is the Taylor series of some smooth function.

In mathematics, a formal series is an infinite sum that is considered independently from any notion of convergence, and can be manipulated with the usual algebraic operations on series.

In mathematics, the Hermite polynomials are a classical orthogonal polynomial sequence.

In mathematics, Abel's theorem for power series relates a limit of a power series to the sum of its coefficients. It is named after Norwegian mathematician Niels Henrik Abel, who proved it in 1826.

In combinatorial mathematics, the Bell polynomials, named in honor of Eric Temple Bell, are used in the study of set partitions. They are related to Stirling and Bell numbers. They also occur in many applications, such as in Faà di Bruno's formula.

In mathematics, the binomial series is a generalization of the polynomial that comes from a binomial formula expression like for a nonnegative integer . Specifically, the binomial series is the MacLaurin series for the function , where and . Explicitly,

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In combinatorics, the symbolic method is a technique for counting combinatorial objects. It uses the internal structure of the objects to derive formulas for their generating functions. The method is mostly associated with Philippe Flajolet and is detailed in Part A of his book with Robert Sedgewick, Analytic Combinatorics, while the rest of the book explains how to use complex analysis in order to get asymptotic and probabilistic results on the corresponding generating functions.

<span class="mw-page-title-main">Lambert series</span> Mathematical term

In mathematics, a Lambert series, named for Johann Heinrich Lambert, is a series taking the form

<span class="mw-page-title-main">Central binomial coefficient</span> Sequence of numbers ((2n) choose (n))

In mathematics the nth central binomial coefficient is the particular binomial coefficient

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In mathematics, the Stirling polynomials are a family of polynomials that generalize important sequences of numbers appearing in combinatorics and analysis, which are closely related to the Stirling numbers, the Bernoulli numbers, and the generalized Bernoulli polynomials. There are multiple variants of the Stirling polynomial sequence considered below most notably including the Sheffer sequence form of the sequence, , defined characteristically through the special form of its exponential generating function, and the Stirling (convolution) polynomials, , which also satisfy a characteristic ordinary generating function and that are of use in generalizing the Stirling numbers to arbitrary complex-valued inputs. We consider the "convolution polynomial" variant of this sequence and its properties second in the last subsection of the article. Still other variants of the Stirling polynomials are studied in the supplementary links to the articles given in the references.

In the mathematical field of combinatorics, the q-Pochhammer symbol, also called the q-shifted factorial, is the product with It is a q-analog of the Pochhammer symbol , in the sense that The q-Pochhammer symbol is a major building block in the construction of q-analogs; for instance, in the theory of basic hypergeometric series, it plays the role that the ordinary Pochhammer symbol plays in the theory of generalized hypergeometric series.

In mathematics, a Carleman matrix is a matrix used to convert function composition into matrix multiplication. It is often used in iteration theory to find the continuous iteration of functions which cannot be iterated by pattern recognition alone. Other uses of Carleman matrices occur in the theory of probability generating functions, and Markov chains.

In mathematics, the Mittag-Leffler polynomials are the polynomials gn(x) or Mn(x) studied by Mittag-Leffler (1891).

In mathematics, a transformation of a sequence's generating function provides a method of converting the generating function for one sequence into a generating function enumerating another. These transformations typically involve integral formulas applied to a sequence generating function or weighted sums over the higher-order derivatives of these functions.

In analytic number theory, a Dirichlet series, or Dirichlet generating function (DGF), of a sequence is a common way of understanding and summing arithmetic functions in a meaningful way. A little known, or at least often forgotten about, way of expressing formulas for arithmetic functions and their summatory functions is to perform an integral transform that inverts the operation of forming the DGF of a sequence. This inversion is analogous to performing an inverse Z-transform to the generating function of a sequence to express formulas for the series coefficients of a given ordinary generating function.

References

  1. This alternative term can already be found in E.N. Gilbert (1956), "Enumeration of Labeled graphs", Canadian Journal of Mathematics 3, p. 405–411, but its use is rare before the year 2000; since then it appears to be increasing.
  2. Knuth, Donald E. (1997). "§1.2.9 Generating Functions". Fundamental Algorithms. The Art of Computer Programming. Vol. 1 (3rd ed.). Addison-Wesley. ISBN   0-201-89683-4.
  3. Flajolet & Sedgewick 2009 , p. 95
  4. "Lambert series identity". Math Overflow. 2017.
  5. Apostol, Tom M. (1976), Introduction to analytic number theory, Undergraduate Texts in Mathematics, New York-Heidelberg: Springer-Verlag, ISBN   978-0-387-90163-3, MR   0434929, Zbl   0335.10001 pp.42–43
  6. Wilf 1994 , p. 56
  7. Wilf 1994 , p. 59
  8. Hardy, G.H.; Wright, E.M.; Heath-Brown, D.R; Silverman, J.H. (2008). An Introduction to the Theory of Numbers (6th ed.). Oxford University Press. p.  339. ISBN   9780199219858.
  9. Knuth, D. E. (1992). "Convolution Polynomials". Mathematica J. 2: 67–78. arXiv: math/9207221 . Bibcode:1992math......7221K.
  10. Spivey, Michael Z. (2007). "Combinatorial Sums and Finite Differences". Discrete Math. 307 (24): 3130–3146. doi: 10.1016/j.disc.2007.03.052 . MR   2370116.
  11. Mathar, R. J. (2012). "Yet another table of integrals". arXiv: 1207.5845 [math.CA]. v4 eq. (0.4)
  12. Graham, Knuth & Patashnik 1994 , Table 265 in §6.1 for finite sum identities involving the Stirling number triangles.
  13. Lando 2003 , §2.4
  14. Example from Stanley, Richard P.; Fomin, Sergey (1997). "§6.3". Enumerative Combinatorics: Volume 2. Cambridge Studies in Advanced Mathematics. Vol. 62. Cambridge University Press. ISBN   978-0-521-78987-5.
  15. Knuth 1997 , §1.2.9
  16. Solution to Graham, Knuth & Patashnik 1994 , p. 569, exercise 7.36
  17. Flajolet & Sedgewick 2009 , §B.4
  18. Schneider, C. (2007). "Symbolic Summation Assists Combinatorics". Sém. Lothar. Combin. 56: 1–36.
  19. See the usage of these terms in Graham, Knuth & Patashnik 1994 , §7.4 on special sequence generating functions.
  20. Good, I. J. (1986). "On applications of symmetric Dirichlet distributions and their mixtures to contingency tables". Annals of Statistics . 4 (6): 1159–1189. doi: 10.1214/aos/1176343649 .
  21. For more complete information on the properties of J-fractions see:
  22. See the following articles:
  23. Graham, Knuth & Patashnik 1994 , §8.3
  24. Graham, Knuth & Patashnik 1994 , Example 6 in §7.3 for another method and the complete setup of this problem using generating functions. This more "convoluted" approach is given in Section 7.5 of the same reference.
  25. Lando 2003 , §5
  26. Hardy et al. 2008 , §19.12
  27. Hardy, G.H.; Wright, E.M. An Introduction to the Theory of Numbers. p.288, Th.361
  28. Graham, Knuth & Patashnik 1994 , p. 535, exercise 5.71
  29. See also the 1031 Generating Functions found in Plouffe, Simon (1992). Approximations de séries génératrices et quelques conjectures[Approximations of generating functions and a few conjectures] (Masters) (in French). Université du Québec à Montréal. arXiv: 0911.4975 .

Citations