Simple rational approximation: Difference between revisions

Browse history interactively

← Previous edit

Content deleted Content added

VisualWikitext

Revision as of 02:50, 22 June 2012 edit Braincricket (talk \| contribs) Extended confirmed users, Pending changes reviewers, Rollbackers 11,449 edits Typo fixing, typos fixed: well-known → well known using AWB (8062) ← Previous edit		Latest revision as of 04:03, 11 March 2025 edit undo Citation bot (talk \| contribs) Bots 5,865,648 edits Altered url. URLs might have been anonymized. \| Use this bot. Report bugs. \| Suggested by Dominic3203 \| Category:Interpolation \| #UCB_Category 39/59
(9 intermediate revisions by 8 users not shown)
Line 1: '''Simple rational approximation (SRA)''' is a subset of [[Interpolation\|interpolating]] methods using [[rational ~~functions~~function]]s. Especially, SRA interpolates a given function with a specific [[rational function]] whose [[~~poles~~pole (complex analysis)\|pole]]s and [[root of a function\|zeros]] are [[simple]], which means that there is no multiplicity in poles and zeros. Sometimes, it only implies simple poles. The main application of SRA lies in finding the [[root of a function\|zeros]] of [[secular function]]s. A [[divide-and-conquer algorithm]] to find the [[eigenvalues]] and [[eigenvectors]] for various kinds of [[Matrix (mathematics)\|matrices]] is well known in [[numerical analysis]]. In a strict sense, SRA implies a specific [[interpolation]] using simple rational functions as a part of the divide-and-conquer algorithm. Since such secular functions consist of a series of rational functions with simple poles, SRA is the best candidate to interpolate the zeros of the secular function. Moreover, based on previous researches, a simple zero that lies between two adjacent poles can be considerably well interpolated by using a two-dominant-pole rational function as an approximating function. == One-point third-order iterative method: Halley's formula == The origin of the interpolation with rational functions can be found in the previous work done by [[Edmond Halley]]. [[Halley's method\|Halley's formula]] is known as one-point third-order iterative method to solve <math>\,f(x)=0</math> by means of approximating a rational function defined by :<math>h(z)=\frac{a}{z+b}+c.</math> We can determine a, b, and c so that Line 11: :<math>x_{n+1}=x_{n}-\frac{f(x_n)}{f'(x_n)} \left({\frac{1}{1-\frac{f(x_n)f''(x_n)}{2(f'(x_n))^2}}}\right).</math> This is referred to as Halley's formula. This ''geometrical interpretation'' <math>h(z)</math> was derived by Gander (1978), where the equivalent iteration also was derived by applying Newton's method to :<math>g(x)=\frac{f(x)}{\sqrt{f'(x)}}=0.</math> We call this ''algebraic interpretation'' <math>g(x)</math> of Halley's formula. ~~There are no known explanation for how one is supposed to calculate a, b or c out of these equations.~~ ==One-point second-order iterative method: Simple rational approximation== Line 26 ⟶ 24: The algebraic interpretation of this iteration is obtained by solving :<math>g(x)=1-\frac{\alpha}{{f(x)}}=0.</math> This one-point second-order method is known to show a locally quadratic convergence if the root of the equation is simple. SRA strictly implies this one-point second-order interpolation by a simple rational function. We can notice that even third order method is a variation of Newton's method. We see the Newton's steps are multiplied by some factors. These factors are called the ''convergence factors'' of the variations, which are useful for analyzing the rate of convergence. See Gander (1978). == References == Line 51 ⟶ 49: \| title = The spectrum of a modified linear pencil \| volume = 46 \| year = 2003~~}}.~~\| doi-access = free }}. {{citation \| last1 = Gu \| first1 = Ming Line 62 ⟶ 61: \| title = A divide-and-conquer algorithm for the symmetric tridiagonal eigenproblem \| volume = 16 \| year = 1995}}\| url = https://zenodo.org/record/1236142 }}. {{citation \| last = Gander \| first = Walter