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A finite difference is a mathematical expression of the form . If a finite difference is divided by , one gets a
difference quotient In single-variable calculus, the difference quotient is usually the name for the expression : \frac which when taken to the limit as ''h'' approaches 0 gives the derivative of the function ''f''. The name of the expression stems from the fact t ...
. The approximation of
derivative In mathematics, the derivative of a function of a real variable measures the sensitivity to change of the function value (output value) with respect to a change in its argument (input value). Derivatives are a fundamental tool of calculus. F ...
s by finite differences plays a central role in
finite difference method In numerical analysis, finite-difference methods (FDM) are a class of numerical techniques for solving differential equations by approximating derivatives with finite differences. Both the spatial domain and time interval (if applicable) are di ...
s for the numerical solution of
differential equation In mathematics, a differential equation is an equation that relates one or more unknown functions and their derivatives. In applications, the functions generally represent physical quantities, the derivatives represent their rates of change, an ...
s, especially
boundary value problem In mathematics, in the field of differential equations, a boundary value problem is a differential equation together with a set of additional constraints, called the boundary conditions. A solution to a boundary value problem is a solution to t ...
s. The
difference operator In mathematics, a recurrence relation is an equation according to which the nth term of a sequence of numbers is equal to some combination of the previous terms. Often, only k previous terms of the sequence appear in the equation, for a parameter ...
, commonly denoted \Delta is the operator that maps a function to the function \Delta /math> defined by :\Delta x)= f(x+1)-f(x). A
difference equation In mathematics, a recurrence relation is an equation according to which the nth term of a sequence of numbers is equal to some combination of the previous terms. Often, only k previous terms of the sequence appear in the equation, for a parameter ...
is a
functional equation In mathematics, a functional equation is, in the broadest meaning, an equation in which one or several functions appear as unknowns. So, differential equations and integral equations are functional equations. However, a more restricted meaning ...
that involves the finite difference operator in the same way as a
differential equation In mathematics, a differential equation is an equation that relates one or more unknown functions and their derivatives. In applications, the functions generally represent physical quantities, the derivatives represent their rates of change, an ...
involves
derivative In mathematics, the derivative of a function of a real variable measures the sensitivity to change of the function value (output value) with respect to a change in its argument (input value). Derivatives are a fundamental tool of calculus. F ...
s. There are many similarities between difference equations and differential equations, specially in the solving methods. Certain recurrence relations can be written as difference equations by replacing iteration notation with finite differences. In
numerical analysis Numerical analysis is the study of algorithms that use numerical approximation (as opposed to symbolic computation, symbolic manipulations) for the problems of mathematical analysis (as distinguished from discrete mathematics). It is the study of ...
, finite differences are widely used for approximating derivatives, and the term "finite difference" is often used as an abbreviation of "finite difference approximation of derivatives". Finite difference approximations are finite difference quotients in the terminology employed above. Finite differences were introduced by Brook Taylor in 1715 and have also been studied as abstract self-standing mathematical objects in works by
George Boole George Boole (; 2 November 1815 – 8 December 1864) was a largely self-taught English mathematician, philosopher, and logician, most of whose short career was spent as the first professor of mathematics at Queen's College, Cork in Ire ...
(1860), L. M. Milne-Thomson (1933), and (1939). Finite differences trace their origins back to one of
Jost Bürgi Jost Bürgi (also ''Joost, Jobst''; Latinisation of names, Latinized surname ''Burgius'' or ''Byrgius''; 28 February 1552 – 31 January 1632), active primarily at the courts in Kassel and Prague, was a Swiss clockmaker, a maker of astronomica ...
's algorithms () and work by others including
Isaac Newton Sir Isaac Newton (25 December 1642 – 20 March 1726/27) was an English mathematician, physicist, astronomer, alchemist, theologian, and author (described in his time as a "natural philosopher"), widely recognised as one of the grea ...
. The formal calculus of finite differences can be viewed as an alternative to the
calculus Calculus, originally called infinitesimal calculus or "the calculus of infinitesimals", is the mathematical study of continuous change, in the same way that geometry is the study of shape, and algebra is the study of generalizations of arithm ...
of
infinitesimal In mathematics, an infinitesimal number is a quantity that is closer to zero than any standard real number, but that is not zero. The word ''infinitesimal'' comes from a 17th-century Modern Latin coinage ''infinitesimus'', which originally referr ...
s.


Basic types

Three basic types are commonly considered: ''forward'', ''backward'', and ''central'' finite differences. A forward difference, denoted \Delta_h of a
function Function or functionality may refer to: Computing * Function key, a type of key on computer keyboards * Function model, a structured representation of processes in a system * Function object or functor or functionoid, a concept of object-oriente ...
is a function defined as : \Delta_h x) = f(x + h) - f(x). Depending on the application, the spacing may be variable or constant. When omitted, is taken to be 1; that is, : \Delta x) = \Delta_1 x) =f(x+1)-f(x) . A backward difference uses the function values at and , instead of the values at and : : \nabla_h x) = f(x) - f(x-h)=\Delta_h x-h). Finally, the central difference is given by : \delta_h x) = f(x+\tfrac2)-f(x-\tfrac2)=\Delta_ x)+\nabla_ x).


Relation with derivatives

Finite difference is often used as an approximation of the derivative, typically in
numerical differentiation In numerical analysis, numerical differentiation algorithms estimate the derivative of a mathematical function or function subroutine using values of the function and perhaps other knowledge about the function. Finite differences The simplest ...
. The
derivative In mathematics, the derivative of a function of a real variable measures the sensitivity to change of the function value (output value) with respect to a change in its argument (input value). Derivatives are a fundamental tool of calculus. F ...
of a function at a point is defined by the
limit Limit or Limits may refer to: Arts and media * ''Limit'' (manga), a manga by Keiko Suenobu * ''Limit'' (film), a South Korean film * Limit (music), a way to characterize harmony * "Limit" (song), a 2016 single by Luna Sea * "Limits", a 2019 ...
. : f'(x) = \lim_ \frac. If has a fixed (non-zero) value instead of approaching zero, then the right-hand side of the above equation would be written : \frac = \frac. Hence, the forward difference divided by approximates the derivative when is small. The error in this approximation can be derived from
Taylor's theorem In calculus, Taylor's theorem gives an approximation of a ''k''-times differentiable function around a given point by a polynomial of degree ''k'', called the ''k''th-order Taylor polynomial. For a smooth function, the Taylor polynomial is the t ...
. Assuming that is twice differentiable, we have : \frac - f'(x) = O(h)\to 0 \quad \texth \to 0. The same formula holds for the backward difference: : \frac - f'(x) = O(h)\to 0 \quad \texth \to 0. However, the central (also called centered) difference yields a more accurate approximation. If is three times differentiable, : \frac - f'(x) = O\left(h^2\right) . The main problem with the central difference method, however, is that oscillating functions can yield zero derivative. If for odd, and for even, then if it is calculated with the
central difference scheme In applied mathematics, the central differencing scheme is a finite difference method that optimizes the approximation for the differential operator in the central node of the considered patch and provides numerical solutions to differential equat ...
. This is particularly troublesome if the domain of is discrete. See also
Symmetric derivative In mathematics, the symmetric derivative is an operation generalizing the ordinary derivative. It is defined asThomson, p. 1. : \lim_ \frac. The expression under the limit is sometimes called the symmetric difference quotient. A function is said ...
Authors for whom finite differences mean finite difference approximations define the forward/backward/central differences as the quotients given in this section (instead of employing the definitions given in the previous section).


Higher-order differences

In an analogous way, one can obtain finite difference approximations to higher order derivatives and differential operators. For example, by using the above central difference formula for and and applying a central difference formula for the derivative of at , we obtain the central difference approximation of the second derivative of : ;Second-order central : f''(x) \approx \frac = \frac = \frac . Similarly we can apply other differencing formulas in a recursive manner. ;Second order forward : f''(x) \approx \frac = \frac = \frac . ;Second order backward : f''(x) \approx \frac = \frac = \frac . More generally, the th order forward, backward, and central differences are given by, respectively, ;Forward :\Delta^n_h x) = \sum_^ (-1)^ \binom f\bigl(x + i h\bigr), or for , :\Delta^n x)= \sum_^n\binom ni(-1)^f(x + i) ;Backward :\nabla^n_h x) = \sum_^ (-1)^i \binom f(x - ih), ;Central :\delta^n_h x) = \sum_^ (-1)^i \binom f\left(x + \left(\frac - i\right) h\right). These equations use
binomial coefficient In mathematics, the binomial coefficients are the positive integers that occur as coefficients in the binomial theorem. Commonly, a binomial coefficient is indexed by a pair of integers and is written \tbinom. It is the coefficient of the t ...
s after the summation sign shown as . Each row of
Pascal's triangle In mathematics, Pascal's triangle is a triangular array of the binomial coefficients that arises in probability theory, combinatorics, and algebra. In much of the Western world, it is named after the French mathematician Blaise Pascal, although ot ...
provides the coefficient for each value of . Note that the central difference will, for odd , have multiplied by non-integers. This is often a problem because it amounts to changing the interval of discretization. The problem may be remedied taking the average of and . Forward differences applied to a
sequence In mathematics, a sequence is an enumerated collection of objects in which repetitions are allowed and order matters. Like a set, it contains members (also called ''elements'', or ''terms''). The number of elements (possibly infinite) is calle ...
are sometimes called the
binomial transform In combinatorics, the binomial transform is a sequence transformation (i.e., a transform of a sequence) that computes its forward differences. It is closely related to the Euler transform, which is the result of applying the binomial transform to th ...
of the sequence, and have a number of interesting combinatorial properties. Forward differences may be evaluated using the Nörlund–Rice integral. The integral representation for these types of series is interesting, because the integral can often be evaluated using
asymptotic expansion In mathematics, an asymptotic expansion, asymptotic series or Poincaré expansion (after Henri Poincaré) is a formal series of functions which has the property that truncating the series after a finite number of terms provides an approximation to ...
or
saddle-point In mathematics, a saddle point or minimax point is a point on the surface of the graph of a function where the slopes (derivatives) in orthogonal directions are all zero (a critical point), but which is not a local extremum of the functi ...
techniques; by contrast, the forward difference series can be extremely hard to evaluate numerically, because the binomial coefficients grow rapidly for large . The relationship of these higher-order differences with the respective derivatives is straightforward, :\frac(x) = \frac+O(h) = \frac+O(h) = \frac + O\left(h^2\right). Higher-order differences can also be used to construct better approximations. As mentioned above, the first-order difference approximates the first-order derivative up to a term of order . However, the combination : \frac = - \frac approximates up to a term of order . This can be proven by expanding the above expression in
Taylor series In mathematics, the Taylor series or Taylor expansion of a function is an infinite sum of terms that are expressed in terms of the function's derivatives at a single point. For most common functions, the function and the sum of its Taylor serie ...
, or by using the calculus of finite differences, explained below. If necessary, the finite difference can be centered about any point by mixing forward, backward, and central differences.


Polynomials

For a given
polynomial In mathematics, a polynomial is an expression consisting of indeterminates (also called variables) and coefficients, that involves only the operations of addition, subtraction, multiplication, and positive-integer powers of variables. An exa ...
of degree , expressed in the function , with real numbers and and ''lower order terms'' (if any) marked as : P(x) = ax^n + bx^ + l.o.t. After pairwise differences, the following result can be achieved, where is a real number marking the arithmetic difference: \Delta_h^n x) = ah^nn! Only the coefficient of the highest-order term remains. As this result is constant with respect to , any further pairwise differences will have the value .


Inductive proof


Base case

Let be a polynomial of degree : \Delta_h x) = Q(x + h) - Q(x) = (x + h) + b-
x + b X, or x, is the twenty-fourth and third-to-last letter in the Latin alphabet, used in the modern English alphabet, the alphabets of other western European languages and others worldwide. Its name in English is ''"ex"'' (pronounced ), ...
= ah = ah^11! This proves it for the base case.


Step case

Let be a polynomial of degree where and the coefficient of the highest-order term be . Assuming the following holds true for all polynomials of degree : \Delta_h^ x) = ah^(m-1)! Let be a polynomial of degree . With one pairwise difference: \Delta_h x) = (x+h)^ + b(x+h)^ + l.o.t.- x^m + bx^ + l.o.t.= ahmx^ + l.o.t. = T(x) As , this results in a polynomial of degree , with as the coefficient of the highest-order term. Given the assumption above and pairwise differences (resulting in a total of pairwise differences for ), it can be found that: \Delta_h^ x) = ahm \cdot h^(m-1)! = ah^mm! This completes the proof.


Application

This identity can be used to find the lowest-degree polynomial that intercepts a number of points where the difference on the x-axis from one point to the next is a constant . For example, given the following points: We can use a differences table, where all cells to the right of the first , the following relation to the cells in the column immediately to the left exists for a cell , with the top-leftmost cell being at coordinate : (a+1, b+1) = (a, b) - (a, b+1) To find the first term, the following table can be used: This arrives at a constant . The arithmetic difference is , as established above. Given the number of pairwise differences needed to reach the constant, it can be surmised this is a polynomial of degree . Thus, using the identity above: 648 = a \cdot 3^3 \cdot 3! = a \cdot 27 \cdot 6 = a \cdot 162 Solving for , it can be found to have the value . Thus, the first term of the polynomial is . Then, subtracting out the first term, which lowers the polynomial's degree, and finding the finite difference again: Here, the constant is achieved after only 2 pairwise differences, thus the following result: -306 = a \cdot 3^2 \cdot 2! = a \cdot 18 Solving for , which is , the polynomial's second term is . Moving on to the next term, by subtracting out the second term: Thus the constant is achieved after only 1 pairwise difference: 108 = a \cdot 3^1 \cdot 1! = a \cdot 3 It can be found that and thus the third term of the polynomial is . Subtracting out the third term: Without any pairwise differences, it is found that the 4th and final term of the polynomial is the constant . Thus, the lowest-degree polynomial intercepting all the points in the first table is found: 4x^3 - 17x^2 + 36x - 19


Arbitrarily sized kernels

Using linear algebra one can construct finite difference approximations which utilize an arbitrary number of points to the left and a (possibly different) number of points to the right of the evaluation point, for any order derivative. This involves solving a linear system such that the
Taylor expansion In mathematics, the Taylor series or Taylor expansion of a function is an infinite sum of terms that are expressed in terms of the function's derivatives at a single point. For most common functions, the function and the sum of its Taylor serie ...
of the sum of those points around the evaluation point best approximates the Taylor expansion of the desired derivative. Such formulas can be represented graphically on a hexagonal or diamond-shaped grid. This is useful for differentiating a function on a grid, where, as one approaches the edge of the grid, one must sample fewer and fewer points on one side. The details are outlined in thes
notes
Th

constructs finite difference approximations for non-standard (and even non-integer) stencils given an arbitrary stencil and a desired derivative order.


Properties

* For all positive and \Delta^n_ (f, x) = \sum\limits_^ \sum\limits_^ \cdots \sum\limits_^ \Delta^n_h \left(f, x+i_1h+i_2h+\cdots+i_nh\right). * Leibniz rule: \Delta^n_h (fg, x) = \sum\limits_^n \binom \Delta^k_h (f, x) \Delta^_h(g, x+kh).


In differential equations

An important application of finite differences is in
numerical analysis Numerical analysis is the study of algorithms that use numerical approximation (as opposed to symbolic computation, symbolic manipulations) for the problems of mathematical analysis (as distinguished from discrete mathematics). It is the study of ...
, especially in
numerical differential equations Numerical may refer to: * Number * Numerical digit * Numerical analysis Numerical analysis is the study of algorithms that use numerical approximation (as opposed to symbolic computation, symbolic manipulations) for the problems of mathematical ...
, which aim at the numerical solution of ordinary and
partial differential equation In mathematics, a partial differential equation (PDE) is an equation which imposes relations between the various partial derivatives of a Multivariable calculus, multivariable function. The function is often thought of as an "unknown" to be sol ...
s. The idea is to replace the derivatives appearing in the differential equation by finite differences that approximate them. The resulting methods are called
finite difference method In numerical analysis, finite-difference methods (FDM) are a class of numerical techniques for solving differential equations by approximating derivatives with finite differences. Both the spatial domain and time interval (if applicable) are di ...
s. Common applications of the finite difference method are in computational science and engineering disciplines, such as
thermal engineering Thermal engineering is a specialized sub-discipline of mechanical engineering that deals with the movement of heat energy and transfer. The energy can be transferred between two mediums or transformed into other forms of energy. A thermal engineer ...
,
fluid mechanics Fluid mechanics is the branch of physics concerned with the mechanics of fluids ( liquids, gases, and plasmas) and the forces on them. It has applications in a wide range of disciplines, including mechanical, aerospace, civil, chemical and bio ...
, etc.


Newton's series

The
Newton series A finite difference is a mathematical expression of the form . If a finite difference is divided by , one gets a difference quotient. The approximation of derivatives by finite differences plays a central role in finite difference methods for the ...
consists of the terms of the Newton forward difference equation, named after
Isaac Newton Sir Isaac Newton (25 December 1642 – 20 March 1726/27) was an English mathematician, physicist, astronomer, alchemist, theologian, and author (described in his time as a "natural philosopher"), widely recognised as one of the grea ...
; in essence, it is the Newton interpolation formula, first published in his ''
Principia Mathematica The ''Principia Mathematica'' (often abbreviated ''PM'') is a three-volume work on the foundations of mathematics written by mathematician–philosophers Alfred North Whitehead and Bertrand Russell and published in 1910, 1912, and 1913. ...
'' in 1687, namely the discrete analog of the continuous Taylor expansion, which holds for any
polynomial In mathematics, a polynomial is an expression consisting of indeterminates (also called variables) and coefficients, that involves only the operations of addition, subtraction, multiplication, and positive-integer powers of variables. An exa ...
function and for many (but not all)
analytic function In mathematics, an analytic function is a function that is locally given by a convergent power series. There exist both real analytic functions and complex analytic functions. Functions of each type are infinitely differentiable, but complex an ...
s. (It does not hold when is
exponential type In complex analysis, a branch of mathematics, a holomorphic function is said to be of exponential type C if its growth is bounded by the exponential function ''e'C'', ''z'', for some real-valued constant ''C'' as , ''z'',  → ∞ ...
\pi. This is easily seen, as the sine function vanishes at integer multiples of \pi; the corresponding Newton series is identically zero, as all finite differences are zero in this case. Yet clearly, the sine function is not zero.) Here, the expression :\binom = \frac is the
binomial coefficient In mathematics, the binomial coefficients are the positive integers that occur as coefficients in the binomial theorem. Commonly, a binomial coefficient is indexed by a pair of integers and is written \tbinom. It is the coefficient of the t ...
, and :(x)_k=x(x-1)(x-2)\cdots(x-k+1) is the "
falling factorial In mathematics, the falling factorial (sometimes called the descending factorial, falling sequential product, or lower factorial) is defined as the polynomial :\begin (x)_n = x^\underline &= \overbrace^ \\ &= \prod_^n(x-k+1) = \prod_^(x-k) \,. \e ...
" or "lower factorial", while the
empty product In mathematics, an empty product, or nullary product or vacuous product, is the result of multiplying no factors. It is by convention equal to the multiplicative identity (assuming there is an identity for the multiplication operation in question ...
is defined to be 1. In this particular case, there is an assumption of unit steps for the changes in the values of of the generalization below. Note the formal correspondence of this result to
Taylor's theorem In calculus, Taylor's theorem gives an approximation of a ''k''-times differentiable function around a given point by a polynomial of degree ''k'', called the ''k''th-order Taylor polynomial. For a smooth function, the Taylor polynomial is the t ...
. Historically, this, as well as the
Chu–Vandermonde identity In combinatorics, Vandermonde's identity (or Vandermonde's convolution) is the following identity for binomial coefficients: :=\sum_^r for any nonnegative integers ''r'', ''m'', ''n''. The identity is named after Alexandre-Théophile Vandermo ...
, :(x+y)_n=\sum_^n \binom (x)_ \,(y)_k , (following from it, and corresponding to the
binomial theorem In elementary algebra, the binomial theorem (or binomial expansion) describes the algebraic expansion of powers of a binomial. According to the theorem, it is possible to expand the polynomial into a sum involving terms of the form , where the ...
), are included in the observations that matured to the system of
umbral calculus In mathematics before the 1970s, the term umbral calculus referred to the surprising similarity between seemingly unrelated polynomial equations and certain "shadowy" techniques used to "prove" them. These techniques were introduced by John Blis ...
. Newton series expansions can be superior to Taylor series expansions when applied to discrete quantities like quantum spins (see
Holstein–Primakoff transformation The Holstein–Primakoff transformation in quantum mechanics is a mapping to the spin operators from boson creation and annihilation operators, effectively truncating their infinite-dimensional Fock space to finite-dimensional subspaces. One impo ...
), bosonic operator functions or discrete counting statistics.Jürgen König and Alfred Hucht
''SciPost Phys. '' 10, 007 (2021)
To illustrate how one may use Newton's formula in actual practice, consider the first few terms of doubling the
Fibonacci sequence In mathematics, the Fibonacci numbers, commonly denoted , form a integer sequence, sequence, the Fibonacci sequence, in which each number is the sum of the two preceding ones. The sequence commonly starts from 0 and 1, although some authors start ...
One can find a
polynomial In mathematics, a polynomial is an expression consisting of indeterminates (also called variables) and coefficients, that involves only the operations of addition, subtraction, multiplication, and positive-integer powers of variables. An exa ...
that reproduces these values, by first computing a difference table, and then substituting the differences that correspond to (underlined) into the formula as follows, : \begin \begin \hline x & f=\Delta^0 & \Delta^1 & \Delta^2 \\ \hline 1&\underline& & \\ & &\underline& \\ 2&2& &\underline \\ & &2& \\ 3&4& & \\ \hline \end & \quad \begin f(x) & =\Delta^0 \cdot 1 +\Delta^1 \cdot \dfrac + \Delta^2 \cdot \dfrac \quad (x_0=1)\\ \\ & =2 \cdot 1 + 0 \cdot \dfrac + 2 \cdot \dfrac \\ \\ & =2 + (x-1)(x-2) \\ \end \end For the case of nonuniform steps in the values of , Newton computes the
divided differences In mathematics, divided differences is an algorithm, historically used for computing tables of logarithms and trigonometric functions. Charles Babbage's difference engine, an early mechanical calculator, was designed to use this algorithm in its o ...
, :\Delta _=y_j,\qquad \Delta _=\frac\quad \ni \quad \left\,\qquad \Delta 0_k=\Delta _ the series of products, :=1,\quad \quad P_=P_k\cdot \left( \xi -x_k \right) , and the resulting polynomial is the
scalar product In mathematics, the dot product or scalar productThe term ''scalar product'' means literally "product with a scalar as a result". It is also used sometimes for other symmetric bilinear forms, for example in a pseudo-Euclidean space. is an algebra ...
, :f(\xi ) = \Delta 0 \cdot P\left( \xi \right) . In analysis with -adic numbers,
Mahler's theorem In mathematics, Mahler's theorem, introduced by , expresses continuous ''p''-adic functions in terms of polynomials. Over any field of characteristic 0, one has the following result: Let (\Delta f)(x)=f(x+1)-f(x) be the forward difference operat ...
states that the assumption that is a polynomial function can be weakened all the way to the assumption that is merely continuous.
Carlson's theorem In mathematics, in the area of complex analysis, Carlson's theorem is a uniqueness theorem which was discovered by Fritz David Carlson. Informally, it states that two different analytic functions which do not grow very fast at infinity can not co ...
provides necessary and sufficient conditions for a Newton series to be unique, if it exists. However, a Newton series does not, in general, exist. The Newton series, together with the
Stirling series In mathematics, Stirling's approximation (or Stirling's formula) is an approximation for factorials. It is a good approximation, leading to accurate results even for small values of n. It is named after James Stirling, though a related but less ...
and the Selberg series, is a special case of the general difference series, all of which are defined in terms of suitably scaled forward differences. In a compressed and slightly more general form and equidistant nodes the formula reads :f(x)=\sum_\binom \sum_^k (-1)^\binomf(a+j h).


Calculus of finite differences

The forward difference can be considered as an operator, called the
difference operator In mathematics, a recurrence relation is an equation according to which the nth term of a sequence of numbers is equal to some combination of the previous terms. Often, only k previous terms of the sequence appear in the equation, for a parameter ...
, which maps the function to . This operator amounts to ::\Delta_h = T_h-I, where is the
shift operator In mathematics, and in particular functional analysis, the shift operator also known as translation operator is an operator that takes a function to its translation . In time series analysis, the shift operator is called the lag operator. Shift o ...
with step ''h'', defined by , and is the
identity operator Identity may refer to: * Identity document * Identity (philosophy) * Identity (social science) * Identity (mathematics) Arts and entertainment Film and television * ''Identity'' (1987 film), an Iranian film * ''Identity'' (2003 film), a ...
. The finite difference of higher orders can be defined in recursive manner as . Another equivalent definition is . The difference operator is a
linear operator In mathematics, and more specifically in linear algebra, a linear map (also called a linear mapping, linear transformation, vector space homomorphism, or in some contexts linear function) is a mapping V \to W between two vector spaces that pre ...
, as such it satisfies . It also satisfies a special Leibniz rule indicated above, . Similar statements hold for the backward and central differences. Formally applying the
Taylor series In mathematics, the Taylor series or Taylor expansion of a function is an infinite sum of terms that are expressed in terms of the function's derivatives at a single point. For most common functions, the function and the sum of its Taylor serie ...
with respect to , yields the formula : \Delta_h = hD + \frac h^2D^2 + \frac h^3D^3 + \cdots = \mathrm^ - I , where denotes the continuum derivative operator, mapping to its derivative . The expansion is valid when both sides act on
analytic function In mathematics, an analytic function is a function that is locally given by a convergent power series. There exist both real analytic functions and complex analytic functions. Functions of each type are infinitely differentiable, but complex an ...
s, for sufficiently small . Thus, , and formally inverting the exponential yields : hD = \log(1+\Delta_h) = \Delta_h - \tfrac \Delta_h^2 + \tfrac \Delta_h^3 - \cdots. This formula holds in the sense that both operators give the same result when applied to a polynomial. Even for analytic functions, the series on the right is not guaranteed to converge; it may be an
asymptotic series In mathematics, an asymptotic expansion, asymptotic series or Poincaré expansion (after Henri Poincaré) is a formal series of functions which has the property that truncating the series after a finite number of terms provides an approximation to ...
. However, it can be used to obtain more accurate approximations for the derivative. For instance, retaining the first two terms of the series yields the second-order approximation to mentioned at the end of the section ''Higher-order differences''. The analogous formulas for the backward and central difference operators are : hD = -\log(1-\nabla_h) \quad\text\quad hD = 2 \operatorname\left(\tfrac12\delta_h\right). The calculus of finite differences is related to the
umbral calculus In mathematics before the 1970s, the term umbral calculus referred to the surprising similarity between seemingly unrelated polynomial equations and certain "shadowy" techniques used to "prove" them. These techniques were introduced by John Blis ...
of combinatorics. This remarkably systematic correspondence is due to the identity of the commutators of the umbral quantities to their continuum analogs ( limits), A large number of formal differential relations of standard calculus involving functions thus ''map systematically to umbral finite-difference analogs'' involving . For instance, the umbral analog of a monomial is a generalization of the above falling factorial (
Pochhammer k-symbol In the mathematical theory of special functions, the Pochhammer ''k''-symbol and the ''k''-gamma function, introduced by Rafael Díaz and Eddy Pariguan are generalizations of the Pochhammer symbol and gamma function. They differ from the Pochhamme ...
), :~(x)_n\equiv \left(xT_h^\right)^n=x (x-h) (x-2h) \cdots \bigl(x-(n-1)h\bigr), so that :\frac (x)_n=n (x)_ , hence the above Newton interpolation formula (by matching coefficients in the expansion of an arbitrary function in such symbols), and so on. For example, the umbral sine is :\sin \left(x\,T_h^\right) = x -\frac + \frac - \frac + \cdots As in the
continuum limit In mathematical physics and mathematics, the continuum limit or scaling limit of a lattice model (physics), lattice model refers to its behaviour in the limit as the lattice spacing goes to zero. It is often useful to use lattice models to approxi ...
, the eigenfunction of also happens to be an exponential, :\frac(1+\lambda h)^\frac =\frac e^= \lambda e^ , and hence ''Fourier sums of continuum functions are readily mapped to umbral Fourier sums faithfully'', i.e., involving the same Fourier coefficients multiplying these umbral basis exponentials. This umbral exponential thus amounts to the exponential
generating function In mathematics, a generating function is a way of encoding an infinite sequence of numbers () by treating them as the coefficients of a formal power series. This series is called the generating function of the sequence. Unlike an ordinary seri ...
of the
Pochhammer symbol In mathematics, the falling factorial (sometimes called the descending factorial, falling sequential product, or lower factorial) is defined as the polynomial :\begin (x)_n = x^\underline &= \overbrace^ \\ &= \prod_^n(x-k+1) = \prod_^(x-k) \,. \e ...
s. Thus, for instance, the
Dirac delta function In mathematics, the Dirac delta distribution ( distribution), also known as the unit impulse, is a generalized function or distribution over the real numbers, whose value is zero everywhere except at zero, and whose integral over the entire ...
maps to its umbral correspondent, the cardinal sine function, :\delta (x) \mapsto \frac, and so forth.
Difference equation In mathematics, a recurrence relation is an equation according to which the nth term of a sequence of numbers is equal to some combination of the previous terms. Often, only k previous terms of the sequence appear in the equation, for a parameter ...
s can often be solved with techniques very similar to those for solving
differential equation In mathematics, a differential equation is an equation that relates one or more unknown functions and their derivatives. In applications, the functions generally represent physical quantities, the derivatives represent their rates of change, an ...
s. The inverse operator of the forward difference operator, so then the umbral integral, is the
indefinite sum In discrete calculus the indefinite sum operator (also known as the antidifference operator), denoted by \sum _x or \Delta^ , is the linear operator, inverse of the forward difference operator \Delta . It relates to the forward difference operator ...
or antidifference operator.


Rules for calculus of finite difference operators

Analogous to rules for finding the derivative, we have: * Constant rule: If is a constant, then ::\Delta c = 0 *
Linearity Linearity is the property of a mathematical relationship (''function'') that can be graphically represented as a straight line. Linearity is closely related to '' proportionality''. Examples in physics include rectilinear motion, the linear r ...
: if and are constants, ::\Delta (a f + b g) = a \,\Delta f + b \,\Delta g All of the above rules apply equally well to any difference operator, including as to . *
Product rule In calculus, the product rule (or Leibniz rule or Leibniz product rule) is a formula used to find the derivatives of products of two or more functions. For two functions, it may be stated in Lagrange's notation as (u \cdot v)' = u ' \cdot v + ...
: :: \begin \Delta (f g) &= f \,\Delta g + g \,\Delta f + \Delta f \,\Delta g \\ \nabla (f g) &= f \,\nabla g + g \,\nabla f - \nabla f \,\nabla g \end *
Quotient rule In calculus, the quotient rule is a method of finding the derivative of a function that is the ratio of two differentiable functions. Let h(x)=f(x)/g(x), where both and are differentiable and g(x)\neq 0. The quotient rule states that the derivat ...
: ::\nabla \left( \frac \right) = \frac \det \begin \nabla f & \nabla g \\ f & g \end \left( \det \right)^ :or ::\nabla\left( \frac \right)= \frac * Summation rules: ::\begin \sum_^ \Delta f(n) &= f(b+1)-f(a) \\ \sum_^ \nabla f(n) &= f(b)-f(a-1) \end See references..


Generalizations

*A generalized finite difference is usually defined as \Delta_h^\mu x) = \sum_^N \mu_k f(x+kh), where is its coefficient vector. An infinite difference is a further generalization, where the finite sum above is replaced by an
infinite series In mathematics, a series is, roughly speaking, a description of the operation of adding infinitely many quantities, one after the other, to a given starting quantity. The study of series is a major part of calculus and its generalization, math ...
. Another way of generalization is making coefficients depend on point : , thus considering weighted finite difference. Also one may make the step depend on point : . Such generalizations are useful for constructing different
modulus of continuity In mathematical analysis, a modulus of continuity is a function ω : , ∞→ , ∞used to measure quantitatively the uniform continuity of functions. So, a function ''f'' : ''I'' → R admits ω as a modulus of continuity if and only if :, f(x)-f ...
. *The generalized difference can be seen as the polynomial rings . It leads to difference algebras. *Difference operator generalizes to
Möbius inversion Moebius, Möbius or Mobius may refer to: People * August Ferdinand Möbius (1790–1868), German mathematician and astronomer * Theodor Möbius (1821–1890), German philologist * Karl Möbius (1825–1908), German zoologist and ecologist * Paul ...
over a
partially ordered set In mathematics, especially order theory, a partially ordered set (also poset) formalizes and generalizes the intuitive concept of an ordering, sequencing, or arrangement of the elements of a Set (mathematics), set. A poset consists of a set toget ...
. *As a convolution operator: Via the formalism of
incidence algebra In order theory, a field of mathematics, an incidence algebra is an associative algebra, defined for every locally finite partially ordered set and commutative ring with unity. Subalgebras called reduced incidence algebras give a natural constr ...
s, difference operators and other Möbius inversion can be represented by
convolution In mathematics (in particular, functional analysis), convolution is a operation (mathematics), mathematical operation on two function (mathematics), functions ( and ) that produces a third function (f*g) that expresses how the shape of one is ...
with a function on the poset, called the
Möbius function The Möbius function is a multiplicative function in number theory introduced by the German mathematician August Ferdinand Möbius (also transliterated ''Moebius'') in 1832. It is ubiquitous in elementary and analytic number theory and most oft ...
; for the difference operator, is the sequence .


Multivariate finite differences

Finite differences can be considered in more than one variable. They are analogous to
partial derivative In mathematics, a partial derivative of a function of several variables is its derivative with respect to one of those variables, with the others held constant (as opposed to the total derivative, in which all variables are allowed to vary). Part ...
s in several variables. Some partial derivative approximations are: :\begin f_(x,y) &\approx \frac \\ f_(x,y) &\approx \frac \\ f_(x,y) &\approx \frac \\ f_(x,y) &\approx \frac \\ f_(x,y) &\approx \frac . \end Alternatively, for applications in which the computation of is the most costly step, and both first and second derivatives must be computed, a more efficient formula for the last case is : f_(x,y) \approx \frac, since the only values to compute that are not already needed for the previous four equations are and .


See also


References

* Richardson, C. H. (1954): ''An Introduction to the Calculus of Finite Differences'' (Van Nostrand (1954)'
online copy
* Mickens, R. E. (1991): ''Difference Equations: Theory and Applications'' (Chapman and Hall/CRC)


External links

*

] * D. Gleich (2005),
''Finite Calculus: A Tutorial for Solving Nasty Sums''

Discrete Second Derivative from Unevenly Spaced Points
{{Calculus topics Finite differences, Numerical differential equations Mathematical analysis Factorial and binomial topics Linear operators in calculus Numerical analysis Non-Newtonian calculus