Bergman space

In complex analysis, functional analysis and operator theory, a Bergman space, named after Stefan Bergman, is a function space of holomorphic functions in a domain D of the complex plane that are sufficiently well-behaved at the boundary and also absolutely integrable. Specifically, for $0 < p < \infty$ , the Bergman space $A p (D)$ is the space of all holomorphic functions $f$ in D for which the p-norm is finite:

\|f\|_{A^{p}(D)}:=\left(\int _{D}|f(x+iy)|^{p}\,\mathrm {d} x\,\mathrm {d} y\right)^{1/p}<\infty .

The quantity $\|f\|_{A^{p}(D)}$ is called the norm of the function $f$ ; it is a true norm if $p\geq 1$ , thus $A p (D)$ is the subspace of holomorphic functions of the space L^p(D). The Bergman spaces are Banach spaces for $0<p<\infty$ , which is a consequence of the following estimate that is valid on compact subsets K of D: $\sup _{z\in K}|f(z)|\leq C_{K}\|f\|_{L^{p}(D)}.$ Convergence of a sequence of holomorphic functions in $L p (D)$ thus implies compact convergence, and so the limit function is also holomorphic.

If $p = 2$ , then $A p (D)$ is a reproducing kernel Hilbert space, whose kernel is given by the Bergman kernel.

Special cases and generalisations

If the domain $D$ is bounded, then the norm is often given by:

\|f\|_{A^{p}(D)}:=\left(\int _{D}|f(z)|^{p}\,dA\right)^{1/p}\;\;\;\;\;(f\in A^{p}(D)),

where $A$ is a normalised Lebesgue measure of the complex plane, i.e. $dA = dz /Area(D)$ . Alternatively $dA = dz / π$ is used, regardless of the area of $D$ . The Bergman space is usually defined on the open unit disk $\mathbb {D}$ of the complex plane, in which case $A^{p}(\mathbb {D} ):=A^{p}$ . If $p=2$ , given an element $f(z)=\sum _{n=0}^{\infty }a_{n}z^{n}\in A^{2}$ , we have

\|f\|_{A^{2}}^{2}:={\frac {1}{\pi }}\int _{\mathbb {D} }|f(z)|^{2}\,dz=\sum _{n=0}^{\infty }{\frac {|a_{n}|^{2}}{n+1}},

that is, $A 2$ is isometrically isomorphic to the weighted ℓ^p(1/(n + 1)) space.^[1] In particular, not only are the polynomials dense in $A 2$ , but every function $f\in A^{2}$ can be uniformly approximated by radial dilations of functions $g$ holomorphic on a disk $D_{R}(0)$ , where $R>1$ and the radial dilation of a function is defined by $g_{r}(z):=g(rz)$ for $0<r<1$ .

Similarly, if $\mathbb {C}$ , the right (or the upper) complex half-plane, then:

\|F\|_{A^{2}(\mathbb {C} _{+})}^{2}:={\frac {1}{\pi }}\int _{\mathbb {C} _{+}}|F(z)|^{2}\,dz=\int _{0}^{\infty }|f(t)|^{2}{\frac {dt}{t}},

where $F(z)=\int _{0}^{\infty }f(t)e^{-tz}\,dt$ , that is, $\mathbb {C}$ is isometrically isomorphic to the weighted L^p_1/t (0,∞) space (via the Laplace transform).^[2]^[3]

The weighted Bergman space $A p (D)$ is defined in an analogous way,^[1] i.e.,

\|f\|_{A_{w}^{p}(D)}:=\left(\int _{D}|f(x+iy)|^{2}\,w(x+iy)\,dx\,dy\right)^{1/p},

provided that $w : D \to [0, \infty)$ is chosen in such way, that $A_{w}^{p}(D)$ is a Banach space (or a Hilbert space, if $p = 2$ ). In case where $D=\mathbb {D}$ , by a weighted Bergman space $A_{\alpha }^{p}$ ^[4] we mean the space of all analytic functions $f$ such that:

\|f\|_{A_{\alpha }^{p}}:=\left((\alpha +1)\int _{\mathbb {D} }|f(z)|^{p}\,(1-|z|^{2})^{\alpha }dA(z)\right)^{1/p}<\infty ,

and similarly on the right half-plane (i.e., $A_{\alpha }^{p}(\mathbb {C} _{+})$ ) we have:^[5]

\|f\|_{A_{\alpha }^{p}(\mathbb {C} _{+})}:=\left({\frac {1}{\pi }}\int _{\mathbb {C} _{+}}|f(x+iy)|^{p}x^{\alpha }\,dx\,dy\right)^{1/p},

and this space is isometrically isomorphic, via the Laplace transform, to the space $L^{2}(\mathbb {R} _{+},\,d\mu _{\alpha })$ ,^[6]^[7] where:

d\mu _{\alpha }:={\frac {\Gamma (\alpha +1)}{2^{\alpha }t^{\alpha +1}}}\,dt.

Here $Γ$ denotes the Gamma function.

Further generalisations are sometimes considered, for example $A_{\nu }^{2}$ denotes a weighted Bergman space (often called a Zen space^[3]) with respect to a translation-invariant positive regular Borel measure $\nu$ on the closed right complex half-plane ${\overline {\mathbb {C} _{+}}}$ , that is:

A_{\nu }^{p}:=\left\{f:\mathbb {C} _{+}\longrightarrow \mathbb {C} {\text{ analytic}}\;:\;\|f\|_{A_{\nu }^{p}}:=\left(\sup _{\varepsilon >0}\int _{\overline {\mathbb {C} _{+}}}|f(z+\varepsilon )|^{p}\,d\nu (z)\right)^{1/p}<\infty \right\}.

It is possible to generalise $A^{2}$ to the (weighted) Bergman space of vector-valued functions^[8], defined by $A_{\alpha }^{2}(\mathbb {D} ;{\mathcal {H}}):=\left\{\,f\colon \,\mathbb {D} \to {\mathcal {H}}\;|\;f{\text{ analytic and }}\|f\|_{2,\alpha }<+\infty \right\},$ and the norm on this space is given as $\|f\|_{2,\alpha }=\left(\int _{\mathbb {D} }\|f(z)\|_{\mathcal {H}}^{2}d\mu _{\alpha }(z)\right)^{\frac {1}{2}}.$ The measure $\mu _{\alpha }$ is the same as the previous measure on the weighted Bergman space over the unit disk, ${\mathcal {H}}$ is a Hilbert space. In this case, the space is a Banach space for $0<p\leq \infty$ and a (reproducing kernel) Hilbert space when $p=2$ .

Reproducing kernels

The reproducing kernel $k_{z}^{A^{2}}$ of $A 2$ at point $z\in \mathbb {D}$ is given by:^[1]

k_{z}^{A^{2}}(\zeta )={\frac {1}{(1-{\overline {z}}\zeta )^{2}}}\;\;\;\;\;(\zeta \in \mathbb {D} ),

and similarly, for $A^{2}(\mathbb {C} _{+})$ we have:^[5]

k_{z}^{A^{2}(\mathbb {C} _{+})}(\zeta )={\frac {1}{({\overline {z}}+\zeta )^{2}}}\;\;\;\;\;(\zeta \in \mathbb {C} _{+}),

In general, if $\varphi$ maps a domain $\Omega$ conformally onto a domain $D$ , then:^[1]

k_{z}^{A^{2}(\Omega )}(\zeta )=k_{\varphi (z)}^{{\mathcal {A}}^{2}(D)}(\varphi (\zeta ))\,{\overline {\varphi '(z)}}\varphi '(\zeta )\;\;\;\;\;(z,\zeta \in \Omega ).

In weighted case we have:^[4]

k_{z}^{A_{\alpha }^{2}}(\zeta )={\frac {\alpha +1}{(1-{\overline {z}}\zeta )^{\alpha +2}}}\;\;\;\;\;(z,\zeta \in \mathbb {D} ),

and:^[5]

k_{z}^{A_{\alpha }^{2}(\mathbb {C} _{+})}(\zeta )={\frac {2^{\alpha }(\alpha +1)}{({\overline {z}}+\zeta )^{\alpha +2}}}\;\;\;\;\;(z,\zeta \in \mathbb {C} _{+}).

In any reproducing kernel Bergman space, functions obey a certain property. It is called the reproducing property. This is expressed as a formula as follows: For any function $f\in A^{2}$ (respectively other Bergman spaces that are RKHS), it is true that $f(z)=\langle f,k_{z}^{A^{2}}\rangle _{2}=\int _{\mathbb {D} }{\frac {f(\zeta )}{(1-z{\overline {\zeta }})^{2}}}dA.$

References

^ ^a ^b ^c ^d Duren, Peter L.; Schuster, Alexander (2004), Bergman spaces, Mathematical Series and Monographs, American Mathematical Society, ISBN 978-0-8218-0810-8
^ Duren, Peter L. (1969), Extension of a theorem of Carleson (PDF), vol. 75, Bulletin of the American Mathematical Society, pp. 143–146
^ ^a ^b Jacob, Brigit; Partington, Jonathan R.; Pott, Sandra (2013-02-01). "On Laplace-Carleson embedding theorems". Journal of Functional Analysis. 264 (3): 783–814. arXiv:1201.1021. doi:10.1016/j.jfa.2012.11.016. S2CID 7770226.
^ ^a ^b Cowen, Carl; MacCluer, Barbara (1995-04-27), Composition Operators on Spaces of Analytic Functions, Studies in Advanced Mathematics, CRC Press, p. 27, ISBN 9780849384929
^ ^a ^b ^c Elliott, Sam J.; Wynn, Andrew (2011), "Composition Operators on the Weighted Bergman Spaces of the Half-Plane", Proceedings of the Edinburgh Mathematical Society, 54 (2): 374–379, arXiv:0910.0408, doi:10.1017/S0013091509001412, S2CID 18811195
^ Duren, Peter L.; Gallardo-Gutiérez, Eva A.; Montes-Rodríguez, Alfonso (2007-06-03), A Paley-Wiener theorem for Bergman spaces with application to invariant subspaces, vol. 39, Bulletin of the London Mathematical Society, pp. 459–466, archived from the original on 2015-12-24
^ Gallrado-Gutiérez, Eva A.; Partington, Jonathan R.; Segura, Dolores (2009), Cyclic vectors and invariant subspaces for Bergman and Dirichlet shifts (PDF), vol. 62, Journal of Operator Theory, pp. 199–214
^ Aleman, Alexandru; Constantin, Olivia (2004). "Hankel operators on Bergman spaces and similarity to contractions". International Mathematics Research Notices. 2004 (35): 1785–1801. doi:10.1155/S1073792804140105. ISSN 1687-0247.{{cite journal}}: CS1 maint: unflagged free DOI (link)

Bergman space

Special cases and generalisations

Reproducing kernels

References

Further reading

See also