Pseudoconvexity

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In mathematics, more precisely in the theory of functions of several complex variables, a pseudoconvex set is a special type of open set in the n-dimensional complex space Cn. Pseudoconvex sets are important, as they allow for classification of domains of holomorphy.

Let

G\subset {{\mathbb  {C}}}^{n}

be a domain, that is, an open connected subset. One says that G is pseudoconvex (or Hartogs pseudoconvex) if there exists a continuous plurisubharmonic function \varphi on G such that the set

\{z\in G\mid \varphi (z)<x\}

is a relatively compact subset of G for all real numbers x. In other words, a domain is pseudoconvex if G has a continuous plurisubharmonic exhaustion function. Every (geometrically) convex set is pseudoconvex.

When G has a C^{2} (twice continuously differentiable) boundary, this notion is the same as Levi pseudoconvexity, which is easier to work with. More specifically, with a C^{2} boundary, it can be shown that G has a defining function; i.e., that there exists \rho :{\mathbb  {C}}^{n}\to {\mathbb  {R}} which is C^{2} so that G=\{\rho <0\}, and \partial G=\{\rho =0\}. Now, G is pseudoconvex iff for every p\in \partial G and w in the complex tangent space at p that is,

\nabla \rho (p)w=\sum _{{i=1}}^{n}{\frac  {\partial \rho (p)}{\partial z_{j}}}w_{j}=0 we have
\sum _{{i,j=1}}^{n}{\frac  {\partial ^{2}\rho (p)}{\partial z_{i}\partial {\bar  {z_{j}}}}}w_{i}{\bar  {w_{j}}}\geq 0.

If G does not have a C^{2} boundary, the following approximation result can come in useful.

Proposition 1 If G is pseudoconvex, then there exist bounded, strongly Levi pseudoconvex domains G_{k}\subset G with C^{\infty } (smooth) boundary which are relatively compact in G, such that

G=\bigcup _{{k=1}}^{\infty }G_{k}.

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

The case n = 1

In one complex dimension, every open domain is pseudoconvex. The concept of pseudoconvexity is thus more useful in dimensions higher than 1.

See also

References

  • Lars Hörmander, An Introduction to Complex Analysis in Several Variables, North-Holland, 1990. (ISBN 0-444-88446-7).
  • Steven G. Krantz. Function Theory of Several Complex Variables, AMS Chelsea Publishing, Providence, Rhode Island, 1992.

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Further reading

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