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{{Short description|Method of solving equations}}
In [[numerical analysis]], '''inverse quadratic interpolation''' is a [[root-finding algorithm]], meaning that it is an algorithm for solving equations of the form ''f''(''x'') = 0. The idea is to use [[polynomial interpolation|quadratic interpolation]] to approximate the [[inverse function|inverse]] of ''f''. This algorithm is rarely used on its own, but it is important because it forms part of the popular [[Brent's method]].
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:<math> f^{-1}(y) = \frac{(y-f_{n-1})(y-f_n)}{(f_{n-2}-f_{n-1})(f_{n-2}-f_n)} x_{n-2} + \frac{(y-f_{n-2})(y-f_n)}{(f_{n-1}-f_{n-2})(f_{n-1}-f_n)} x_{n-1} </math>
We are looking for a root of ''f'', so we substitute ''y'' = ''f''(''x'') = 0 in the above equation, and this results in the above recursion formula.
==Behaviour==
The asymptotic behaviour is very good: generally, the iterates ''x''<sub>''n''</sub> converge fast to the root once they get close. However, performance is often quite poor if
The order of this convergence is approximately 1.84 as can be proved by [[secant method]] analysis.
==Comparison with other root-finding methods==
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==References==
*[[James F. Epperson]], [https://books.google.com/books?id=Mp8-z5mHptcC&pg=PA182 An introduction to numerical methods and analysis], pages 182–185, Wiley-Interscience, 2007. {{isbn|978-0-470-04963-1}}
[[Category:Root-finding algorithms]]
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