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In complex analysis, a branch of mathematics, the Schwarz integral formula, named after Hermann Schwarz, allows one to recover a holomorphic function, up to an imaginary constant, from the boundary values of its real part.

Unit disc

Let ƒ = u + iv be a function which is holomorphic on the closed unit disc {z ∈ C | |z| ≤ 1}. Then

f (z) = \frac{1}{2 π i} \oint_{| ζ | = 1} \frac{ζ + z}{ζ - z} Re (f (ζ)) \frac{d ζ}{ζ} + i Im (f (0))

for all |z| < 1.

Upper half-plane

Let ƒ = u + iv be a function that is holomorphic on the closed upper half-plane {z ∈ C | Im(z) ≥ 0} such that, for some α > 0, |z^α ƒ(z)| is bounded on the closed upper half-plane. Then

f (z) = \frac{1}{π i} \int_{- \infty}^{\infty} \frac{u (ζ, 0)}{ζ - z} d ζ = \frac{1}{π i} \int_{- \infty}^{\infty} \frac{R e (f) (ζ + 0 i)}{ζ - z} d ζ

for all Im(z) > 0.

Note that, as compared to the version on the unit disc, this formula does not have an arbitrary constant added to the integral; this is because the additional decay condition makes the conditions for this formula more stringent.

Corollary of Poisson integral formula

The formula follows from Poisson integral formula applied to u:^[1]^[2]

u (z) = \frac{1}{2 π} \int_{0}^{2 π} u (e^{i ψ}) ℜ \frac{e^{i ψ} + z}{e^{i ψ} - z} d ψ for | z | < 1 .

By means of conformal maps, the formula can be generalized to any simply connected open set.

Notes and references

↑ Template:Cite web
↑ The derivation without an appeal to the Poisson formula can be found at: http://planetmath.org/encyclopedia/PoissonFormula.html

Ahlfors, Lars V. (1979), Complex Analysis, Third Edition, McGraw-Hill, ISBN 0-07-085008-9
Remmert, Reinhold (1990), Theory of Complex Functions, Second Edition, Springer, ISBN 0-387-97195-5
Saff, E. B., and A. D. Snider (1993), Fundamentals of Complex Analysis for Mathematics, Science, and Engineering, Second Edition, Prentice Hall, ISBN 0-13-327461-6

[1] Template:Cite web

[2] The derivation without an appeal to the Poisson formula can be found at: http://planetmath.org/encyclopedia/PoissonFormula.html

[1]

[2]

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+In [[complex analysis]], a branch of mathematics, the '''Schwarz integral formula''', named after [[Hermann Schwarz]], allows one to recover a [[holomorphic function]], [[up to]] an imaginary constant, from the boundary values of its real part.
+==Unit disc==
+Let ''ƒ''&nbsp;=&nbsp;''u''&nbsp;+&nbsp;''iv'' be a function which is holomorphic on the closed unit disc {''z''&nbsp;∈&nbsp;'''C'''&nbsp;|&nbsp;|''z''|&nbsp;≤&nbsp;1}.  Then
+: <math> f(z) = \frac{1}{2\pi i} \oint_{|\zeta| = 1} \frac{\zeta + z}{\zeta - z} \text{Re}(f(\zeta)) \, \frac{d\zeta}{\zeta}
++ i\text{Im}(f(0))</math>
+for all |''z''|&nbsp;<&nbsp;1.
+==Upper half-plane==
+Let ''ƒ''&nbsp;=&nbsp;''u''&nbsp;+&nbsp;''iv'' be a function that is holomorphic on the closed [[upper half-plane]] {''z''&nbsp;∈&nbsp;'''C'''&nbsp;|&nbsp;Im(''z'')&nbsp;≥&nbsp;0} such that, for some ''α''&nbsp;>&nbsp;0, |''z''<sup>''α''</sup>&nbsp;''ƒ''(''z'')| is bounded on the closed upper half-plane.  Then
+: <math>
+f(z)
+=
+\frac{1}{\pi i} \int_{-\infty}^\infty \frac{u(\zeta,0)}{\zeta - z} \, d\zeta
+=
+\frac{1}{\pi i} \int_{-\infty}^\infty \frac{Re(f)(\zeta+0i)}{\zeta - z} \, d\zeta
+</math>
+for all Im(''z'')&nbsp;>&nbsp;0.
+Note that, as compared to the version on the unit disc, this formula does not have an arbitrary constant added to the integral; this is because the additional decay condition makes the conditions for this formula more stringent.
+== Corollary of Poisson integral formula ==
+The formula follows from [[Poisson integral formula]] applied to&nbsp;''u'':<ref>
+{{cite web
+|url=http://books.google.com/books?id=NVrgftOGG1sC&pg=PA9&ots=FTpLISInOP&dq=Schwarz+formula&sig=tYdkW2Mq4IJg-gTIDWVCEI4HKCE
+|title=Lectures on Entire Functions - Google Book Search
+|publisher=books.google.com
+|accessdate=2008-06-26
+|last=
+|first=
+}}
+</ref><ref>The derivation without an appeal to the Poisson formula can be found at: http://planetmath.org/encyclopedia/PoissonFormula.html</ref>
+: <math>u(z) = \frac{1}{2\pi}\int_0^{2\pi} u(e^{i\psi}) \operatorname{Re} {e^{i\psi} + z \over e^{i\psi} - z} \, d\psi\text{ for }|z| < 1.</math>
+By means of conformal maps, the formula can be generalized to any simply connected open set.
+== Notes and references ==
+<references />
+* [[Lars Ahlfors|Ahlfors, Lars V.]] (1979), ''Complex Analysis'', Third Edition, McGraw-Hill, ISBN 0-07-085008-9
+* Remmert, Reinhold (1990), ''Theory of Complex Functions'', Second Edition, Springer, ISBN 0-387-97195-5
+* Saff, E. B., and A. D. Snider (1993), ''Fundamentals of Complex Analysis for Mathematics, Science, and Engineering'', Second Edition, Prentice Hall, ISBN 0-13-327461-6
+[[Category:Complex analysis]]