Several complex variables

In complex analysis, the theory of functions of several complex variables is the branch of mathematics dealing with complex-valued functions in the space Cn of n-tuples of complex numbers.

As in complex analysis of functions of one variable, which is the case n = 1, the functions studied are holomorphic or complex analytic so that, locally, they are power series in the variables zi. Equivalently, they are locally uniform limits of polynomials; or local solutions to the n-dimensional Cauchy–Riemann equations. For one complex variable, the any domain was the domain of holomorphy, but for Several complex variables, the any domain is not the domain of holomorphy, so the domain of holomorphy is one of the themes in this field. Also, the interesting phenomena that occur in several complex variables are fundamentally important to the study of compact complex manifolds and projective complex varieties and has a different flavour to complex analytic geometry in or on Stein manifolds.

Historical perspective

Many examples of such functions were familiar in nineteenth-century mathematics: abelian functions, theta functions, and some hypergeometric series. Naturally also any function of one variable that depends on some complex parameter is a candidate. The theory, however, for many years didn't become a full-fledged area in mathematical analysis, since its characteristic phenomena weren't uncovered. The Weierstrass preparation theorem would now be classed as commutative algebra; it did justify the local picture, ramification, that addresses the generalization of the branch points of Riemann surface theory.

With work of Friedrich Hartogs, and of Kiyoshi Oka in the 1930s, a general theory began to emerge; others working in the area at the time were Heinrich Behnke, Peter Thullen and Karl Stein. Hartogs proved some basic results, such as every isolated singularity is removable, for any analytic function

whenever n > 1. Naturally the analogues of contour integrals will be harder to handle: when n = 2 an integral surrounding a point should be over a three-dimensional manifold (since we are in four real dimensions), while iterating contour (line) integrals over two separate complex variables should come to a double integral over a two-dimensional surface. This means that the residue calculus will have to take a very different character.

After 1945 important work in France, in the seminar of Henri Cartan, and Germany with Hans Grauert and Reinhold Remmert, quickly changed the picture of the theory. A number of issues were clarified, in particular that of analytic continuation. Here a major difference is evident from the one-variable theory: while for any open connected set D in C we can find a function that will nowhere continue analytically over the boundary, that cannot be said for n > 1. In fact the D of that kind are rather special in nature (satisfying a condition called pseudoconvexity). The natural domains of definition of functions, continued to the limit, are called Stein manifolds and their nature was to make sheaf cohomology groups vanish. In fact it was the need to put (in particular) the work of Oka on a clearer basis that led quickly to the consistent use of sheaves for the formulation of the theory (with major repercussions for algebraic geometry, in particular from Grauert's work).

From this point onwards there was a foundational theory, which could be applied to analytic geometry, [note 1] automorphic forms of several variables, and partial differential equations. The deformation theory of complex structures and complex manifolds was described in general terms by Kunihiko Kodaira and D. C. Spencer. The celebrated paper GAGA of Serre[ref 1] pinned down the crossover point from géometrie analytique to géometrie algébrique.

C. L. Siegel was heard to complain that the new theory of functions of several complex variables had few functions in it, meaning that the special function side of the theory was subordinated to sheaves. The interest for number theory, certainly, is in specific generalizations of modular forms. The classical candidates are the Hilbert modular forms and Siegel modular forms. These days these are associated to algebraic groups (respectively the Weil restriction from a totally real number field of GL(2), and the symplectic group), for which it happens that automorphic representations can be derived from analytic functions. In a sense this doesn't contradict Siegel; the modern theory has its own, different directions.

Subsequent developments included the hyperfunction theory, and the edge-of-the-wedge theorem, both of which had some inspiration from quantum field theory. There are a number of other fields, such as Banach algebra theory, that draw on several complex variables.

The Cn space

is defined as the cartesian product of n complex planes , and when is a domain of holomorphy, can be regarded as a Stein manifold. It can be considered as an n-dimensional vector space over complex numbers, which gives its dimension 2n over R.[note 2] Hence, as a set, and as topological space, Cn is identical to R2n and its topological dimension is 2n.

In coordinate-free language, any vector space over complex numbers may be thought of as a real vector space of twice as many dimensions, where a complex structure is specified by a linear operator J (such that J 2 = I) which defines multiplication by the imaginary unit i.

Any such space, as a real space, is oriented. On the complex plane thought of as the Cartesian plane, multiplication to a complex number w = u + iv has the real matrix

a 2 × 2 real matrix that has the determinant

Likewise, if one expresses any finite-dimensional complex linear operator as a real matrix (which will be composed from 2×2 blocks of the aforementioned form), then its determinant equals to the square of absolute value of the corresponding complex determinant. It is a non-negative number, which implies that the (real) orientation of the space is never reversed by a complex operator. The same applies to Jacobians of holomorphic functions from Cn to Cn.

Connected space

Every product of a family of connected (resp. path-connected) spaces is connected (resp. path-connected).

Compact

From Tychonoff's theorem, the space mapped by the cartesian product consisting of any combination of compact spaces is a compact space.

Holomorphic functions

A function defined on a domain is called holomorphic if satisfies one of the following two conditions.[note 3][ref 2]

(i) If is continuous[note 4] on D[note 5]
(ii) For each variable , is holomorphic, namely,

 

 

 

 

(1)

which is a generalization of the Cauchy–Riemann equations (using a partial Wirtinger derivative), and has the origin of Riemann's differential equation methods.

Cauchy–Riemann equations

For each index λ let

and generalize the usual Cauchy–Riemann equation for one variable for each index λ, then we obtain

 

 

 

 

 

(2)

Let

through

the above equations (1) and (2) turn to be equivalent.

Cauchy's integral formula

f is meets condition continuous and separately homorphic on domain D. Each disk has a rectifiable curve , is piecewise smoothness, class Jordan closed curve. () Let be the domain surrounded by each . Cartesian product closure is . Also, take the polydisc so that it becomes . ( and let be the center of each disk.) Using Cauchy's integral formula of one variable repeatedly,

Because is a rectifiable Jordanian closed curve[note 6] and f is continuous, so the order of products and sums can be exchanged so the iterated integral can be calculated as a multiple integral. Therefore,

 

 

 

 

(3)

While in the one-variable case Cauchy's integral formula is an integral over the circumference of a disc with some radius r, in several variables case over the surface of a polydisc with radii 's as in (3).

Cauchy's evaluation formula

Because the order of products and sums is interchangeable, from (3) we get

 

 

 

 

(4)

f is differentiable any number of times and the derivative is continuous.

From (4), if is holomorphic, on polydisc and , the following evaluation equation is obtained.

Therefore, Liouville's theorem hold.

Power series expansion of holomorphic functions

If is holomorphic, on polydisc , from Cauchy's integral formula, we can see that it can be uniquely expanded to the next power series.

 

 

 

 

(5)

In addition, that satisfies the following conditions is called an analytic function.

For each point , is expressed as a power series expansion that is convergent on D :

We have already explained that holomorphic functions are analytic. Also, from the theorem derived by Weierstrass , we can see that the analytic function (convergent power series) is holomorphic.

If a sequence of functions which converges uniformly on compacta inside a domain D, the limit function f of also uniformly on compacta inside a domain D. Also, respective partial derivative of also compactly converges on domain D to the corresponding derivative of f.
[ref 3]
Radius of convergence of power series

It is possible to define a combination of positive real numbers such that the power series converges uniformly at and does not converge uniformly at .

In this way it is possible to have a similar radius of convergence[note 7] for a single complex variable, but there is a point where it converges outside the circle of convergence.[note 8]

Identity theorem

When the function f,g is holomorphic in the concatenated domain D,[note 9] even for several complex variables, the identity theorem[note 10] holds on the domain D, because it has a power series expansion the neighbourhood of holomorphic point. Therefore, the maximal principle hold. Also, the inverse function theorem and implicit function theorem hold.

Analytic continuation

Let U, V be open subsets in , and . Assume that and is a connected component of . If then f is said to be connected to V, and g is said to be analytic continuation of f. From the identity theorem, if g exists, for each way of choosing w it is unique. Whether or not the definition of this analytic continuation is well-defined should be considered whether the domains U,V and W can be defined well. Several complex variables have restrictions on this domain, and depending on the shape of the domain , all holomorphic functions f belonging to U are connected to V, and there may be not exist function f with as the natural boundary. In other words, U cannot be defined. There is called the Hartogs's phenomenon. Therefore, researching when domain boundaries become natural boundaries has become one of the main research themes of Several complex variables. Also, in the general dimension, there may be multiple intersections between U and V. That is, f is not connected as a monovalent holomorphic function, but as an multivalued holomorphic function. This means that W is not unique and has different properties in the neighborhood of the branch point than in the case of one variable.

Reinhardt domain

Power series expansion of Several complex variables have some points of convergence outside the circle of convergence, but it is possible to define a radius of convergence similar to that of one complex variable. The Reinhardt domain is considered in order to investigate the characteristics of the convergence domain of the power series, but when considering the Reinhardt domain, it can be seen that the convergence domain of the power series satisfies the convexity called Logarithmically-convex. There are various convexity for the convergence domain of Several complex variables.

A domain D in the complex space , , with centre at a point , with the following property: Together with any point , the domain also contains the set

A Reinhardt domain D with is invariant under the transformations , , . The Reinhardt domains constitute a subclass of the Hartogs domains (cf. Hartogs domain) and a subclass of the circular domains, which are defined by the following condition: Together with any , the domain contains the set

i.e. all points of the circle with centre and radius that lie on the complex line through and .

A Reinhardt domain D is called a complete Reinhardt domain if together with any point it also contains the polydisc

A complete Reinhardt domain is star-like with respect to its centre a. Therefore, the complete Reinhardt domain is simply connected, also when the complete Reinhardt domain is the boundary line, there is a way to prove Cauchy's integral theorem without using the Jordan curve theorem.

Logarithmically-convex

A Reinhardt domain D is called logarithmically convex if the image of the set

under the mapping

is a convex set in the real space . An important property of logarithmically-convex Reinhardt domains is the following: Every such domain in is the interior of the set of points of absolute convergence (i.e. the domain of convergence) of some power series in , and conversely: The domain of convergence of any power series in is a logarithmically-convex Reinhardt domain with centre . [note 11]

Thullen's classic results

Thullen's[ref 4] classical result says that a 2-dimensional bounded Reinhard domain containing the origin is biholomorphic to one of the following domains provided that the orbit of the origin by the automorphism group has positive dimension:

(1) (polydisc);

(2) (unit ball);

(3) (Thullen domain).

Hartogs's phenomenon

Let's look at the example on the Hartogs's extension theorem page in terms of the Reinhardt domain.

On the polydisk consisting of two disks when .

Internal domain of

Theorem Hartogs (1906)[ref 5] any holomorphic functions f on are analytically continued to . Namely, there is a holomorphic function F on such that on .

The convergence domain extends from to . i.e. The convergent domain of is extended to the smallest complete Reinhardt domain that can cover .

Sunada's results

Toshikazu Sunada (1978)[ref 6] established a generalization of Thullen's result:

Two n-dimensional bounded Reinhardt domains and are mutually biholomorphic if and only if there exists a transformation given by , being a permutation of the indices), such that .

Domain of holomorphy

The sets in the definition. Note: On this page, replace in the figure with D

When we increase a one complex variable that was to several complex variables, depending on the range of the domain, it may not be possible to define a holomorphic function such that the boundary of the domain becomes a natural boundary. Therefore we consider the domain where the boundaries of the domain are natural boundaries i.e. domain of holomorphy, the first result in the domain of holomorphy was the holomorphic convexity of H. Cartan and Thullen. Levi's problem shows that the pseudoconvex domain was a domain of holomorphy.[ref 7][ref 8][ref 9] Also Kiyoshi Oka's idéal de domaines indéterminés[ref 10] is interpreted by Cartan. In sheaf[ref 11] theory, the domain of holomorphy has come to be interpreted as the theory of Stein manifolds.[ref 12]

Definition

Function f is holomorpic on the domain , when f cannot directly connect to the domain outside D including the point of the domain boundary , the domain D is called the domain of holomorphy of f and the boundary is called the natural boundary of f. In other words, the domain of holomorphy D is the supremum of the domain where the holomorphic function f is holomorphic, and the domain D, which is holomorphic, cannot be extended any more. For Several complex variables, i.e. domain , the boundaries may not be natural boundaries. Hartogs' extension theorem gives an example of a domain where boundaries are not natural boundaries.

Formally, an open set D in the n-dimensional complex space is called a domain of holomorphy if there do not exist non-empty open sets and where V is connected, and such that for every holomorphic function f on D there exists a holomorphic function g on V with on U.

In the case, every open set is a domain of holomorphy: we can define a holomorphic function with zeros accumulating everywhere on the boundary of the domain, which must then be a natural boundary for a domain of definition of its reciprocal.

Holomorphically convex hull

The first result on the properties of the domain of holomorphy is the regular convexity of Henri Cartan and Peter Thullen (1932).[ref 13]

The holomorphically convex hull of a given compact set in the n-dimensional complex space is defined as follows.

Let be a domain (an open set and connected set), or alternatively for a more general definition, let be an dimensional complex analytic manifold. Further let stand for the set of holomorphic functions on G. For a compact set , the holomorphically convex hull of K is

One obtains a narrower concept of polynomially convex hull by taking instead to be the set of complex-valued polynomial functions on G. The polynomially convex hull contains the holomorphically convex hull.

The domain is called holomorphically convex if for every compact subset is also compact in G. Sometimes this is just abbreviated as holomorph-convex.

When , any domain is holomorphically convex since then is the union of with the relatively compact components of .

If satisfies the above holomorphically convexity it has the following properties. The radius of the polydisc satisfies condition also the compact set satisfies and is the domain. In the time that, any holomorphic function on the domain can be direct analytic continuated up to .

Levi convex (convex in regard to analytic surfaces)

For every sequence of analytic compact surfaces such that for some set we have . i.e. Approximate from the inside by analytic compact surfaces ( cannot be "touched from inside" by a sequence of analytic surfaces).

Pseudoconvex

Pseudoconvex Hartogs showed that is subharmonic for the radius of convergence when the Hartogs series is a one-variable . If such a relationship holds in the domain of holomorphy of Several complex variables, it looks like a more manageable condition than a holomorphically convex. The subharmonic function looks like a kind of convex function, so it was named by Levi as a pseudoconvex domain. Pseudoconvex domain are important, as they allow for classification of domains of holomorphy.

Definition of plurisubharmonic function

A function
with domain

is called plurisubharmonic if it is upper semi-continuous, and for every complex line

with
the function is a subharmonic function on the set
In full generality, the notion can be defined on an arbitrary complex manifold or even a Complex analytic space as follows. An upper semi-continuous function
is said to be plurisubharmonic if and only if for any holomorphic map

the function

is subharmonic, where denotes the unit disk.

Strictly plurisubharmonic function

Necessary and sufficient condition that the real-valued function u(z), that can be second-order differentiable with respect to z of one-variable complex function is subharmonic is . When the Hermitian matrix of u is positive-definite and -class, we call u a strict plural subharmonic function.

(Weakly) pseudoconvex (p-pseudoconvex)

Weak pseudoconvex[ref 14] is defined as : Let be a domain, that is, an open connected subset. One says that X is pseudoconvex (or Hartogs pseudoconvex) if there exists a continuous plurisubharmonic function on X such that the set is a relatively compact subset of X for all real numbers x. [note 12] i.e there exists a smooth plurisubharmonic exhaustion function .

Strongly pseudoconvex

Strongly pseudoconvex if there exists a smooth strictly plurisubharmonic exhaustion function ,i.e. is positive definite at every point. The strongly pseudoconvex domain is the pseudoconvex domain.[ref 14]

Levi-Krzoska pseudoconvexity

If boundary (i.e. When D is a strongly pseudoconvex domain.), it can be shown that D has a defining function; i.e., that there exists which is so that , and . Now, D is pseudoconvex iff for every and in the complex tangent space at p, that is,

, we have

If D does not have a boundary, the following approximation result can be useful.

Proposition 1 If D is pseudoconvex, then there exist bounded, strongly Levi pseudoconvex domains with (smooth) boundary which are relatively compact in D, such that

This is because once we have a as in the definition we can actually find a C exhaustion function.

Levi Strongly Pseudoconvex (Levi total Pseudoconvex)

If for every boundary point of D, there exists an analytic variety passing which lies entirely outside D in some neighborhood around , except the point itself. Domain D that satisfies these conditions is called Levi Strongly Pseudoconvex or Levi total Pseudoconvex.[ref 15]

Family of Oka's disk

Let n-functions be continuous on , holomorphic in when the parameter t is fixed in [0, 1], and assume that are not all zero at any point on . Then the set is called an analytic disc de-pending on a parameter t, and is called its shell. If and , Q(t) is called Family of Oka's disk.[ref 15]

Definition

When holds on any Family of Oka's disk, D is called Oka pseudoconvex.[ref 15]

Cartan pseudoconvex (local Levi property)

For every point there exist a neighbourhood U of x and f holomorphic on such that f cannot be extended to any neighbourhood of x. Such a property is called local Levi property, and the domain that satisfies this property is called the Cartan pseudoconvex domain. The Cartan pseudoconvex domain is itself a pseudoconvex domain and is a domain of holomorphy.[ref 15]

Equivalent conditions

For a domain the following conditions are equivalent.[note 13]:

  1. D is a domain of holomorphy.
  2. D is holomorphically convex.
  3. D is pseudoconvex.
  4. D is Levi convex.
  5. D is Cartan pseudoconvex.

Implications [note 14] are standard results (for , see Oka's lemma). Proving , i.e. constructing a global holomorphic function which admits no extension from non-extendable functions defined only locally. This is called the Levi problem (after E. E. Levi) and was first solved by Kiyoshi Oka, and then by Lars Hörmander using methods from functional analysis and partial differential equations (a consequence of -problem).

Properties of the domain of holomorphy

  • If are domains of holomorphy, then their intersection is also a domain of holomorphy.
  • If is an ascending sequence of domains of holomorphy, then their union is also a domain of holomorphy (see Behnke–Stein theorem).
  • If and are domains of holomorphy, then is a domain of holomorphy.
  • The first Cousin problem is always solvable in a domain of holomorphy; this is also true, with additional topological assumptions, for the second Cousin problem.

Coherent sheaf

Definition

The definition of the coherent sheaf is as follows.[ref 21]

A coherent sheaf on a ringed space is a sheaf satisfying the following two properties:

  1. is of finite type over , that is, every point in has an open neighborhood in such that there is a surjective morphism for some natural number ;
  2. for any open set , any natural number , and any morphism of -modules, the kernel of is of finite type.

Morphisms between (quasi-)coherent sheaves are the same as morphisms of sheaves of -modules.

Also, Jean-Pierre Serre (1955)[ref 21] proves that

If in an exact sequence of sheaves of -modules two of the three sheaves are coherent, then the third is coherent as well.

A quasi-coherent sheaf on a ringed space is a sheaf of -modules which has a local presentation, that is, every point in has an open neighborhood in which there is an exact sequence

for some (possibly infinite) sets and .

Oka's coherent theorem for sheaf of holomorphic functions

Kiyoshi Oka (1950)[ref 10] proved the following

Sheaf of holomorphic function germ on the analytic variety is the coherent sheaf. Therefore, is also a coherent sheaf. This theorem is also used to prove Cartan's theorems A and B.

Manifolds considered with Several complex variables

Stein manifold

Since the open Riemann surface always has a non-constant monovalent holomorphic function and satisfies the second axiom of countability, the Riemann surface was considered for embedding the one-dimensional complex plane into a analytic manifold. In fact, taking one point at infinity on the one-dimensional complex plane extended it to the Riemann sphere. The Whitney embedding theorem tells us that every smooth n-dimensional manifold can be embedded as a smooth submanifold of , whereas it is "rare" for a complex manifold to have a holomorphic embedding into . Consider for example any compact connected complex manifold X: any holomorphic function on it is constant by Liouville's theorem. Now that we know that for Several complex variables, complex manifolds do not always have holomorphic functions that are not constants, consider the conditions that have holomorphic functions. Now if we had a holomorphic embedding of X into , then the coordinate functions of would restrict to nonconstant holomorphic functions on X, contradicting compactness, except in the case that X is just a point. Complex manifolds that can be embedded in Cn are called Stein manifolds. Also Stein manifolds satisfy the second axiom of countability.

Stein manifold is a complex submanifold of the vector space of n complex dimensions. They were introduced by and named after Karl Stein (1951).[ref 22] A Stein space is similar to a Stein manifold but is allowed to have singularities. Stein spaces are the analogues of affine varieties or affine schemes in algebraic geometry. If the univalent domain on is connection to a manifold, can be regarded as a complex manifold and satisfies the separation condition described later, the condition for becoming a Stein manifold is to satisfy the holomorphic convexity. Therefore, the Stein manifold is the properties of the domain of definition of the (maximal) analytic continuation of an analytic function.

Definition

Suppose X is a paracompact complex manifolds of complex dimension and let denote the ring of holomorphic functions on X. We call X a Stein manifold if the following conditions hold:

  • X is holomorphically convex, i.e. for every compact subset , the so-called holomorphically convex hull,
is also a compact subset of X.
  • X is holomorphically separable, i.e. if are two points in X, then there exists such that
  • The open neighborhood of any point on the manifold has a holomorphic Chart to the .

Non-compact Riemann surfaces are Stein

Let X be a connected, non-compact Riemann surface. A deep theorem of Heinrich Behnke and Stein (1948)[ref 23] asserts that X is a Stein manifold.

Another result, attributed to Hans Grauert and Helmut Röhrl (1956), states moreover that every holomorphic vector bundle on X is trivial. In particular, every line bundle is trivial, so . The exponential sheaf sequence leads to the following exact sequence:

Now Cartan's theorem B shows that , therefore .

This is related to the solution of the second (multiplicative) Cousin problem.

Properties and examples of Stein manifolds

  • The standard[note 15] complex space is a Stein manifold.
  • Every domain of holomorphy in is a Stein manifold.
  • It can be shown quite easily that every closed complex submanifold of a Stein manifold is a Stein manifold, too.
  • The embedding theorem for Stein manifolds states the following: Every Stein manifold X of complex dimension can be embedded into by a biholomorphic proper map.

These facts imply that a Stein manifold is a closed complex submanifold of complex space, whose complex structure is that of the ambient space (because the embedding is biholomorphic).

  • Every Stein manifold of (complex) dimension n has the homotopy type of an n-dimensional CW-Complex.
  • In one complex dimension the Stein condition can be simplified: a connected Riemann surface is a Stein manifold if and only if it is not compact. This can be proved using a version of the Runge theorem for Riemann surfaces, due to Behnke and Stein.
  • Every Stein manifold is holomorphically spreadable, i.e. for every point , there are holomorphic functions defined on all of which form a local coordinate system when restricted to some open neighborhood of x.
  • The first Cousin problem can always be solved on a Stein manifold.
  • Being a Stein manifold is equivalent to being a (complex) strongly pseudoconvex manifold. The latter means that it has a strongly pseudoconvex (or plurisubharmonic) exhaustive function, i.e. a smooth real function on (which can be assumed to be a Morse function) with , such that the subsets are compact in X for every real number . This is a solution to the so-called Levi problem,[ref 24] named after E. E. Levi (1911). The function invites a generalization of Stein manifold to the idea of a corresponding class of compact complex manifolds with boundary called Stein domains. A Stein domain is the preimage . Some authors call such manifolds therefore strictly pseudoconvex manifolds.[ref 25]
  • Related to the previous item, another equivalent and more topological definition in complex dimension 2 is the following: a Stein surface is a complex surface X with a real-valued Morse function f on X such that, away from the critical points of f, the field of complex tangencies to the preimage is a contact structure that induces an orientation on Xc agreeing with the usual orientation as the boundary of That is, is a Stein filling of Xc.

Numerous further characterizations of such manifolds exist, in particular capturing the property of their having "many" holomorphic functions taking values in the complex numbers. See for example Cartan's theorems A and B, relating to sheaf cohomology.

In the GAGA set of analogies, Stein manifolds correspond to affine varieties.

Stein manifolds are in some sense dual to the elliptic manifolds in complex analysis which admit "many" holomorphic functions from the complex numbers into themselves. It is known that a Stein manifold is elliptic if and only if it is fibrant in the sense of so-called "holomorphic homotopy theory".

See also

Annotation

  1. a name adopted, confusingly, for the geometry of zeroes of analytic functions: this is not the analytic geometry learned at school
  2. The field of complex numbers is a 2-dimensional vector space over real numbers.
  3. This may seem nontrivial, but it's known as Osgood's lemma. Osgood's lemma can be proved from the establishment of Cauchy's integral formula, also Cauchy's integral formula can be proved by assuming separate holomorphicity and continuity, so it is appropriate to define it in this way.
  4. It is not separate continuous.
  5. Using Hartogs's theorem on separate holomorphicity, If condition (ii) is met, it will be derived to be continuous.
  6. According to the Jordan curve theorem, domain D is bounded closed set.
  7. This combination is generally not unique.
  8. If one of the variables is 0, then some terms, represented by the product of this variable, will be 0 regardless of the values taken by the other variables. Therefore, even if you take a variable that diverges when a variable is other than 0, it may converge.
  9. For several variables, the boundary of any domain is not always the natural boundary, so depending on how the domain is taken, there may not be a holomorphic function that makes that domain the natural boundary. See domain of holomorphy for an example of a condition where the boundary of a domain is a natural boundary.
  10. Note that from Hartogs' extension theorem, the zeros of holomorphic functions of several variables are not isolated points. Therefore, for several variables it is not enough that is satisfied at the accumulation point.
  11. The final paragraph reduces to: A Reinhardt domain is a domain of holomorphy if and only if it is logarithmically convex.
  12. This is a hullomorphically convex hull condition expressed by a plurisubharmonic function. For this reason, it is also called p-pseudoconvex or simply p-convex.
  13. In algebraic geometry, there is a problem whether it is possible to remove the singular point of the complex analytic space by performing an operation called modification[ref 16][ref 17] on the complex analytic space (when n = 2, the result by Hirzebruch,[ref 18] when n = 3 the result by Zariski[ref 19] for algebraic varietie.), but, Grauert and Remmert has reported an example of a domain that is neither pseudoconvex nor holomorphic convex, even though it is a domain of holomorphy. [ref 20]
  14. The Cartan–Thullen theorem
  15. ( is a projective complex varieties) does not become a Stein manifold, even if it satisfies the holomorphic convexity.

References

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  2. Osgood, William F. (1899), "Note über analytische Functionen mehrerer Veränderlichen", Mathematische Annalen, Springer Berlin / Heidelberg, 52: 462–464, doi:10.1007/BF01476172, ISSN 0025-5831, JFM 30.0380.02
  3. Solomentsev, E.D. (2001) [1994], "Weierstrass theorem", Encyclopedia of Mathematics, EMS Press
  4. Peter Thullen, Zu den Abbildungen durch analytische Funktionen mehrerer komplexer Veraenderlichen Die Invarianz des Mittelpunktes von Kreiskoerpern, Matt. Ann. 104 (1931), 244–259
  5. Hartogs, Fritz (1906), "Einige Folgerungen aus der Cauchyschen Integralformel bei Funktionen mehrerer Veränderlichen.", Sitzungsberichte der Königlich Bayerischen Akademie der Wissenschaften zu München, Mathematisch-Physikalische Klasse (in German), 36: 223–242, JFM 37.0443.01
  6. Tosikazu Sunada, Holomorphic equivalence problem for bounded Reinhaldt domains, Math. Ann. 235 (1978), 111–128
  7. In the case of Oka, Kiyoshi (1942), "Sur les fonctions analytiques de plusieurs variables. VI. Domaines pseudoconvexes", Tohoku Mathematical Journal, First Series, 49: 15–52, ISSN 0040-8735, Zbl 0060.24006
  8. Extension to Oka, Kiyoshi (1953), "Sur les fonctions analytiques de plusieurs variables. IX. Domaines finis sans point critique intérieur", Japanese journal of mathematics :transactions and abstracts, 23: 97–155, doi:10.4099/jjm1924.23.0_97, ISSN 0075-3432
  9. Extension to Hans J. Bremermann (1954), "Über die Äquivalenz der pseudokonvexen Gebiete und der Holomorphiegebiete im Raum vonn komplexen Veränderlichen", Mathematische Annalen, 106: 63–91, doi:10.1007/BF01360125
  10. Oka, Kiyoshi (1950), "Sur les fonctions analytiques de plusieurs variables. VII. Sur quelques notions arithmétiques", Bulletin de la Société Mathématique de France, 78: 1–27, doi:10.24033/bsmf.1408, ISSN 0037-9484, MR 0035831
  11. Numdam.org, Cartan, H., Eilenberg, Samuel., Serre, J-P., Séminaire Henri Cartan Tome 3 (SHC_1950-1951)
  12. Numdam.org, Cartan, H., Bruhat, F., Cerf, Jean., Dolbeault, P., Frenkel, Jean., Hervé, Michel., Malatian., Serre, J-P., Séminaire Henri Cartan Tome 4 (1951-1952)
  13. Henri Cartan&Peter Thullen (1932), "Zur Theorie der Singularitäten der Funktionen mehrerer komplexen Veränderlichen Regularitäts-und Konvergenzbereiche", Mathematische Annalen, 106: 617–647, doi:10.1007/BF01455905
  14. Complex Analytic and Differential Geometry p.49
  15. Sin HITOTUMATU (1958), "On some conjectures concerning pseudo-convex domains", Journal of the Mathematical Society of Japan, 6 (No.2): 177–195, doi:10.2969/jmsj/00620177, Zbl 0057.31503
  16. Heinrich Behnke & Karl Stein (1951), "Modifikationen komplexer Mannigfaltigkeiten und Riernannscher Gebiete", Mathematische Annalen, 124: 1–16, doi:10.1007/BF01343548, Zbl 0043.30301
  17. Onishchik, A.L. (2001) [1994], "Modification", Encyclopedia of Mathematics, EMS Press
  18. Friedrich Hirzebruch (1953), "Über vierdimensionaleRIEMANNsche Flächen mehrdeutiger analytischer Funktionen von zwei komplexen Veränderlichen", Mathematische Annalen, 126: 1–22, doi:10.1007/BF01343146, hdl:21.11116/0000-0004-3A47-C
  19. Oscar Zariski (1944), "Reduction of the Singularities of Algebraic Three Dimensional Varieties", Annals of Mathematics Second Series, 45 (No.3): 472–542, doi:10.2307/1969189
  20. Hans Grauert & Reinhold Remmert (1956), "Konvexität in der komplexen Analysis. Nicht-holomorph-konvexe Holomorphiegebiete und Anwendungen auf die Abbildungstheorie.", Commentarii Mathematici Helvetici volume, 31: 152–183, doi:10.1007/BF02564357, Zbl 0073.30301
  21. Serre, Jean-Pierre (1955), "Faisceaux algébriques cohérents", Annals of Mathematics, 61: 197–278, doi:10.2307/1969915, MR 0068874
  22. Stein, Karl (1951), "Analytische Funktionen mehrerer komplexer Veränderlichen zu vorgegebenen Periodizitätsmoduln und das zweite Cousinsche Problem", Math. Ann. (in German), 123: 201–222, doi:10.1007/bf02054949, MR 0043219
  23. In the case of Heinrich Behnke & Karl Stein (1948), "Entwicklung analytischer Funktionen auf Riemannschen Flächen", Mathematische Annalen, 120: 430–461, doi:10.1007/BF01447838, Zbl 0038.23502
  24. Onishchik, A.L. (2001) [1994], "Levi problem", Encyclopedia of Mathematics, EMS Press
  25. Hans Grauert (1958), "On Levi's Problem and the Imbedding of Real-Analytic Manifolds", Annals of Mathematics, Second Series, 68 (No.2): 460–472, doi:10.2307/1970257, Zbl 0108.07804

Textbooks

  • H. Behnke and P. Thullen, Theorie der Funktionen mehrerer komplexer Veränderlichen (1934)
  • Salomon Bochner and W. T. Martin Several Complex Variables (1948)
  • Forster, Otto (1981), Lectures on Riemann surfaces, Graduate Text in Mathematics, 81, New-York: Springer Verlag, ISBN 0-387-90617-7
  • Grauert, Hans; Remmert, Reinhold (1979), Theory of Stein spaces, Grundlehren der Mathematischen Wissenschaften, 236, Berlin-New York: Springer-Verlag, ISBN 3-540-90388-7, MR 0580152
  • B.V. Shabat, Introduction of complex analysis, 1–2, Moscow (1985) (In Russian)
    • V.S. Vladimirov, Methods of the theory of functions of many complex variables, M.I.T. (1966) (Translated from Russian)
  • Boris Vladimirovich Shabat, Introduction to Complex Analysis, AMS, 1992
  • Lars Hörmander (1990) [1966], An Introduction to Complex Analysis in Several Variables (3rd ed.), North Holland, ISBN 978-1-493-30273-4
  • Henri Cartan,Théorie élémentaire des fonctions analytiques d'une ou plusieurs variables complexes, Paris, Hermann, 1975.
  • "Holomorphic functions and integral representation in several complex variables", Springer (1986)
  • Steven G. Krantz, Function Theory of Several Complex Variables (1992)
  • R. Michael Range, Holomorphic Functions and Integral Representations in Several Complex Variables, Springer 1986, 1998
  • Volker Scheidemann, Introduction to complex analysis in several variables, Birkhäuser, 2005, ISBN 3-7643-7490-X

Encyclopedia of Mathematics

PlanetMath

This article incorporates material from Reinhardt domain on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License. This article incorporates material from Holomorphically convex on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License. This article incorporates material from Domain of holomorphy on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.

Further reading

  • Steven G. Krantz, What is Several Complex Variables? The American Mathematical Monthly Vol. 94, No. 3 (Mar., 1987), pp. 236–256 (21 pages) Published By: Taylor & Francis, Ltd. https://doi.org/10.2307/2323391
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