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Mergelyan's theorem
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(Theorem)
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So for any $\epsilon > 0$ one can find a polynomial $p(z) = \sum_{j=1}^n a_j z^j$ such that $\lvert f(z) - p(z) \rvert < \epsilon$ for all $z \in K.$
Do note that this theorem is not a weaker version of Runge's theorem. Here, we do not need $f$ to be holomorphic on a neighbourhood of $K,$ but just on the interior of $K.$ For example, if the interior of $K$ is empty, then $f$ just needs to be continuous on $K.$ Further, it could be that the closure of the interior of $K$ might not be all of $K.$ Consider $K = D \cup
[-10,10],$ where $D$ is the closed unit disc. Then $K$ has two lines coming out of either end of the disc and $f$ needs to only be continuous there.
Also note that this theorem is distinct from the Stone-Weierstrass theorem. The point here is that the polynomials are holomorphic in Mergelyan's theorem.
- 1
- John B. Conway. Functions of One Complex Variable I. Springer-Verlag, New York, New York, 1978.
- 2
- Walter Rudin. Real and Complex Analysis. McGraw-Hill, Boston, Massachusetts, 1987.
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"Mergelyan's theorem" is owned by jirka.
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Cross-references: point, Stone-Weierstrass theorem, disc, lines, unit disc, closed, closure, neighbourhood, Runge's theorem, theorem, variable, complex, polynomials, limit, interior, holomorphic, continuous function, connected, complement, complex plane, compact subset
There is 1 reference to this entry.
This is version 4 of Mergelyan's theorem, born on 2004-06-07, modified 2007-12-04.
Object id is 5897, canonical name is MergelyansTheorem.
Accessed 2207 times total.
Classification:
| AMS MSC: | 30E10 (Functions of a complex variable :: Miscellaneous topics of analysis in the complex domain :: Approximation in the complex domain) |
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Pending Errata and Addenda
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