In mathematics, divided differences is an algorithm, historically used for computing tables of logarithms and trigonometric functions.[citation needed] Charles Babbage's difference engine, an early mechanical calculator, was designed to use this algorithm in its operation.[1]

Divided differences is a recursive division process. Given a sequence of data points , the method calculates the coefficients of the interpolation polynomial of these points in the Newton form.

Definition

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Given n + 1 data points   where the   are assumed to be pairwise distinct, the forward divided differences are defined as:  

To make the recursive process of computation clearer, the divided differences can be put in tabular form, where the columns correspond to the value of j above, and each entry in the table is computed from the difference of the entries to its immediate lower left and to its immediate upper left, divided by a difference of corresponding x-values:  

Notation

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Note that the divided difference   depends on the values   and  , but the notation hides the dependency on the x-values. If the data points are given by a function f,   one sometimes writes the divided difference in the notation  Other notations for the divided difference of the function ƒ on the nodes x0, ..., xn are:  

Example

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Divided differences for   and the first few values of  :  

Thus, the table corresponding to these terms upto two columns has the following form:  

Properties

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  • Linearity  
  • Leibniz rule  
  • Divided differences are symmetric: If   is a permutation then  
  • Polynomial interpolation in the Newton form: if   is a polynomial function of degree  , and   is the divided difference, then  
  • If   is a polynomial function of degree  , then  
  • Mean value theorem for divided differences: if   is n times differentiable, then   for a number   in the open interval determined by the smallest and largest of the  's.

Matrix form

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The divided difference scheme can be put into an upper triangular matrix:  

Then it holds

  •  
  •   if   is a scalar
  •  
    This follows from the Leibniz rule. It means that multiplication of such matrices is commutative. Summarised, the matrices of divided difference schemes with respect to the same set of nodes x form a commutative ring.
  • Since   is a triangular matrix, its eigenvalues are obviously  .
  • Let   be a Kronecker delta-like function, that is   Obviously  , thus   is an eigenfunction of the pointwise function multiplication. That is   is somehow an "eigenmatrix" of  :  . However, all columns of   are multiples of each other, the matrix rank of   is 1. So you can compose the matrix of all eigenvectors of   from the  -th column of each  . Denote the matrix of eigenvectors with  . Example   The diagonalization of   can be written as  

Polynomials and power series

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The matrix   contains the divided difference scheme for the identity function with respect to the nodes  , thus   contains the divided differences for the power function with exponent  . Consequently, you can obtain the divided differences for a polynomial function   by applying   to the matrix  : If   and   then   This is known as Opitz' formula.[2][3]

Now consider increasing the degree of   to infinity, i.e. turn the Taylor polynomial into a Taylor series. Let   be a function which corresponds to a power series. You can compute the divided difference scheme for   by applying the corresponding matrix series to  : If   and   then  

Alternative characterizations

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Expanded form

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With the help of the polynomial function   this can be written as  

Peano form

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If   and  , the divided differences can be expressed as[4]   where   is the  -th derivative of the function   and   is a certain B-spline of degree   for the data points  , given by the formula  

This is a consequence of the Peano kernel theorem; it is called the Peano form of the divided differences and   is the Peano kernel for the divided differences, all named after Giuseppe Peano.

Forward and backward differences

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When the data points are equidistantly distributed we get the special case called forward differences. They are easier to calculate than the more general divided differences.

Given n+1 data points   with   the forward differences are defined as  whereas the backward differences are defined as:   Thus the forward difference table is written as: whereas the backwards difference table is written as: 

The relationship between divided differences and forward differences is[5]  whereas for backward differences:[citation needed] 

See also

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References

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  1. ^ Isaacson, Walter (2014). The Innovators. Simon & Schuster. p. 20. ISBN 978-1-4767-0869-0.
  2. ^ de Boor, Carl, Divided Differences, Surv. Approx. Theory 1 (2005), 46–69, [1]
  3. ^ Opitz, G. Steigungsmatrizen, Z. Angew. Math. Mech. (1964), 44, T52–T54
  4. ^ Skof, Fulvia (2011-04-30). Giuseppe Peano between Mathematics and Logic: Proceeding of the International Conference in honour of Giuseppe Peano on the 150th anniversary of his birth and the centennial of the Formulario Mathematico Torino (Italy) October 2-3, 2008. Springer Science & Business Media. p. 40. ISBN 978-88-470-1836-5.
  5. ^ Burden, Richard L.; Faires, J. Douglas (2011). Numerical Analysis (9th ed.). Cengage Learning. p. 129. ISBN 9780538733519.
  • Louis Melville Milne-Thomson (2000) [1933]. The Calculus of Finite Differences. American Mathematical Soc. Chapter 1: Divided Differences. ISBN 978-0-8218-2107-7.
  • Myron B. Allen; Eli L. Isaacson (1998). Numerical Analysis for Applied Science. John Wiley & Sons. Appendix A. ISBN 978-1-118-03027-1.
  • Ron Goldman (2002). Pyramid Algorithms: A Dynamic Programming Approach to Curves and Surfaces for Geometric Modeling. Morgan Kaufmann. Chapter 4:Newton Interpolation and Difference Triangles. ISBN 978-0-08-051547-2.
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  NODES
INTERN 1
Note 3