In real analysis and complex analysis, branches of mathematics, the identity theorem for analytic functions states: given functions f and g analytic on a domain D (open and connected subset of or ), if f = g on some , where has an accumulation point in D, then f = g on D.[1]

Thus an analytic function is completely determined by its values on a single open neighborhood in D, or even a countable subset of D (provided this contains a converging sequence together with its limit). This is not true in general for real-differentiable functions, even infinitely real-differentiable functions. In comparison, analytic functions are a much more rigid notion. Informally, one sometimes summarizes the theorem by saying analytic functions are "hard" (as opposed to, say, continuous functions which are "soft").

The underpinning fact from which the theorem is established is the expandability of a holomorphic function into its Taylor series.

The connectedness assumption on the domain D is necessary. For example, if D consists of two disjoint open sets, can be on one open set, and on another, while is on one, and on another.

Lemma

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If two holomorphic functions   and   on a domain D agree on a set S which has an accumulation point   in  , then   on a disk in   centered at  .

To prove this, it is enough to show that   for all  , since both functions are analytic.

If this is not the case, let   be the smallest nonnegative integer with  . By holomorphy, we have the following Taylor series representation in some open neighborhood U of  :

 

By continuity,   is non-zero in some small open disk   around  . But then   on the punctured set  . This contradicts the assumption that   is an accumulation point of  .

This lemma shows that for a complex number  , the fiber   is a discrete (and therefore countable) set, unless  .

Proof

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Define the set on which   and   have the same Taylor expansion:  

We'll show   is nonempty, open, and closed. Then by connectedness of  ,   must be all of  , which implies   on  .

By the lemma,   in a disk centered at   in  , they have the same Taylor series at  , so  ,   is nonempty.

As   and   are holomorphic on  ,  , the Taylor series of   and   at   have non-zero radius of convergence. Therefore, the open disk   also lies in   for some  . So   is open.

By holomorphy of   and  , they have holomorphic derivatives, so all   are continuous. This means that   is closed for all  .   is an intersection of closed sets, so it's closed.

Full characterisation

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Since the Identity Theorem is concerned with the equality of two holomorphic functions, we can simply consider the difference (which remains holomorphic) and can simply characterise when a holomorphic function is identically  . The following result can be found in.[2]

Claim

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Let   denote a non-empty, connected open subset of the complex plane. For   the following are equivalent.

  1.   on  ;
  2. the set   contains an accumulation point,  ;
  3. the set   is non-empty, where  .

Proof

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The directions (1   2) and (1   3) hold trivially.

For (3   1), by connectedness of   it suffices to prove that the non-empty subset,  , is clopen (since a topological space is connected if and only if it has no proper clopen subsets). Since holomorphic functions are infinitely differentiable, i.e.  , it is clear that   is closed. To show openness, consider some  . Consider an open ball   containing  , in which   has a convergent Taylor-series expansion centered on  . By virtue of  , all coefficients of this series are  , whence   on  . It follows that all  -th derivatives of   are   on  , whence  . So each   lies in the interior of  .

Towards (2   3), fix an accumulation point  . We now prove directly by induction that   for each  . To this end let   be strictly smaller than the convergence radius of the power series expansion of   around  , given by  . Fix now some   and assume that   for all  . Then for   manipulation of the power series expansion yields

  (1)

Note that, since   is smaller than radius of the power series, one can readily derive that the power series   is continuous and thus bounded on  .

Now, since   is an accumulation point in  , there is a sequence of points   convergent to  . Since   on   and since each  , the expression in (1) yields

  (2)

By the boundedness of   on  , it follows that  , whence  . Via induction the claim holds. Q.E.D.

See also

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References

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  1. ^ For real functions, see Krantz, Steven G.; Parks, Harold R. (2002). A Primer of Real Analytic Functions (Second ed.). Boston: Birkhäuser. Corollary 1.2.7. ISBN 0-8176-4264-1.
  2. ^ Guido Walz, ed. (2017). Lexikon der Mathematik (in German). Vol. 2. Mannheim: Springer Spektrum Verlag. p. 476. ISBN 978-3-662-53503-5.
  • Ablowitz, Mark J.; Fokas A. S. (1997). Complex variables: Introduction and applications. Cambridge, UK: Cambridge University Press. p. 122. ISBN 0-521-48058-2.