Difference between revisions of "Oka theorems"
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Theorems on the classical problems in the theory of functions of several complex variables, first proved by K. Oka between 1930 and 1950 (see [[#References|[1]]]). | Theorems on the classical problems in the theory of functions of several complex variables, first proved by K. Oka between 1930 and 1950 (see [[#References|[1]]]). | ||
− | 1) Oka's theorem on the [[Cousin problems|Cousin problems]]: The first Cousin problem is solvable in any [[Domain of holomorphy|domain of holomorphy]] in | + | 1) Oka's theorem on the [[Cousin problems|Cousin problems]]: The first Cousin problem is solvable in any [[Domain of holomorphy|domain of holomorphy]] in $\mathbf C^n$; the second Cousin problem is solvable in any domain of holomorphy $D\subset\mathbf C^n$ that is homeomorphic to $D_1\times\dotsb\times D_n$, where all domains $D_v\subset\mathbf C$, except for, possibly, one, are simply connected. |
2) Oka's theorem on the [[Levi problem|Levi problem]]: Any pseudo-convex Riemannian domain (cf. [[Pseudo-convex and pseudo-concave|Pseudo-convex and pseudo-concave]]) is a domain of holomorphy. | 2) Oka's theorem on the [[Levi problem|Levi problem]]: Any pseudo-convex Riemannian domain (cf. [[Pseudo-convex and pseudo-concave|Pseudo-convex and pseudo-concave]]) is a domain of holomorphy. | ||
− | Originally Oka proved these theorems in dimension | + | Originally Oka proved these theorems in dimension $n=2$; in the case of arbitrary dimension, the theorems were also proved by other mathematicians. |
− | 3) The Oka–Weil theorem: Let | + | 3) The Oka–Weil theorem: Let $D$ be a domain in $\mathbf C^n$ and let the compact set $K\subset D$ coincide with its hull with respect to the algebra $\mathcal O(D)$ of all functions holomorphic in $D$ (cf. [[Holomorphic envelope|Holomorphic envelope]]); then for any function $f$ holomorphic in a neighbourhood of $K$, and for any $\epsilon>0$, a function $F\in\mathcal O(D)$ can be found such that |
− | + | $$\max_K|f-F|<\epsilon.$$ | |
This fundamental theorem in the theory of holomorphic approximation is extensively used in complex and functional analysis. | This fundamental theorem in the theory of holomorphic approximation is extensively used in complex and functional analysis. | ||
− | 4) Oka's coherence theorem: Let | + | 4) Oka's coherence theorem: Let $\mathcal O$ be a sheaf of holomorphic functions on a complex manifold $X$; then for any natural number $p$, any locally finitely-generated subsheaf of the sheaf $\mathcal O^p=\mathcal O\times\dotsb\times\mathcal O$ ($p$ times) is a coherent [[Analytic sheaf|analytic sheaf]] (cf. [[Coherent sheaf|Coherent sheaf]]). |
− | This is one of the basic theorems of the so-called Oka–Cartan theory, which is used essentially in proving the Cartan theorems | + | This is one of the basic theorems of the so-called Oka–Cartan theory, which is used essentially in proving the Cartan theorems $A$ and $B$ (cf. [[Cartan theorem|Cartan theorem]]). |
====References==== | ====References==== |
Latest revision as of 13:49, 14 February 2020
Theorems on the classical problems in the theory of functions of several complex variables, first proved by K. Oka between 1930 and 1950 (see [1]).
1) Oka's theorem on the Cousin problems: The first Cousin problem is solvable in any domain of holomorphy in $\mathbf C^n$; the second Cousin problem is solvable in any domain of holomorphy $D\subset\mathbf C^n$ that is homeomorphic to $D_1\times\dotsb\times D_n$, where all domains $D_v\subset\mathbf C$, except for, possibly, one, are simply connected.
2) Oka's theorem on the Levi problem: Any pseudo-convex Riemannian domain (cf. Pseudo-convex and pseudo-concave) is a domain of holomorphy.
Originally Oka proved these theorems in dimension $n=2$; in the case of arbitrary dimension, the theorems were also proved by other mathematicians.
3) The Oka–Weil theorem: Let $D$ be a domain in $\mathbf C^n$ and let the compact set $K\subset D$ coincide with its hull with respect to the algebra $\mathcal O(D)$ of all functions holomorphic in $D$ (cf. Holomorphic envelope); then for any function $f$ holomorphic in a neighbourhood of $K$, and for any $\epsilon>0$, a function $F\in\mathcal O(D)$ can be found such that
$$\max_K|f-F|<\epsilon.$$
This fundamental theorem in the theory of holomorphic approximation is extensively used in complex and functional analysis.
4) Oka's coherence theorem: Let $\mathcal O$ be a sheaf of holomorphic functions on a complex manifold $X$; then for any natural number $p$, any locally finitely-generated subsheaf of the sheaf $\mathcal O^p=\mathcal O\times\dotsb\times\mathcal O$ ($p$ times) is a coherent analytic sheaf (cf. Coherent sheaf).
This is one of the basic theorems of the so-called Oka–Cartan theory, which is used essentially in proving the Cartan theorems $A$ and $B$ (cf. Cartan theorem).
References
[1] | K. Oka, "Sur les fonctions analytiques de plusieurs variables" , Iwanami Shoten (1961) |
[2] | L. Hörmander, "An introduction to complex analysis in several variables" , North-Holland (1973) |
[3] | R.C. Gunning, H. Rossi, "Analytic functions of several complex variables" , Prentice-Hall (1965) |
Comments
Reference [a2] is an annotated English translation of Oka's fundamental papers.
References
[a1] | S.G. Krantz, "Function theory of several complex variables" , Wiley (1982) |
[a2] | K. Oka, "Collected papers" , Springer (1984) |
[a3] | R.M. Range, "Holomorphic functions and integral representation in several complex variables" , Springer (1986) pp. Chapt. 1, Sect. 3 |
Oka theorems. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Oka_theorems&oldid=19092