Hefer's theorem

(Redirected from Hefer's lemma)

In several complex variables, Hefer's theorem is a result that represents the difference at two points of a holomorphic function as the sum of the products of the coordinate differences of these two points with other holomorphic functions defined in the Cartesian product of the function's domain.

The theorem bears the name of Hans Hefer. The result was published by Karl Stein and Heinrich Behnke under the name Hans Hefer.[1] In a footnote in the same article, it is written that Hans Hefer died on the eastern front and that the work was an excerpt from Hefer's dissertation which he defended in 1940.

Statement of the theorem

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Let   be a domain of holomorphy and   be a holomorphic function. Then, there exist holomorphic functions   defined on   so that

 

holds for every  .

The decomposition in the theorem is feasible also on many non-pseudoconvex domains.

Hefer's lemma

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The proof of the theorem follows from Hefer's lemma.[2][3]

Let   be a domain of holomorphy and   be a holomorphic function. Suppose that   is identically zero on the intersection of   with the  -dimensional complex coordinate space; i.e.

 .

Then, there exist holomorphic functions   defined on   so that

 

holds for every  .

References

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  1. ^ Hans Hefer (1950–51). "Zur Funktionentheorie mehrerer Veränderlichen. Über eine Zerlegung analytischer Funktionen und die Weilsche Integraldarstellung". Mathematische Annalen. 122 (3): 276–278. doi:10.1007/BF01342970. Retrieved 22 October 2024.
  2. ^ Boas, Harold. "Math 685 Notes Topics in Several Complex Variables" (PDF). Retrieved 22 October 2024.
  3. ^ Wiegerinck, Jan (23 August 2017). "Several Complex Variables" (PDF). Retrieved 22 October 2024.