# Riemann theorem

Riemann's theorem on conformal mappings: Given any two simply-connected domains and of the extended complex plane , distinct from and also from with a point excluded from it, then an infinite number of analytic single-valued functions on can be found such that each one realizes a one-to-one conformal transformation of onto . In this case, for any pair of points , , and and any real number , , a unique function of this class can be found for which , . The condition geometrically means that each infinitely-small vector emanating from the point changes under the transformation into an infinitely-small vector the direction of which forms with the direction of the original vector the angle .

Riemann's theorem is fundamental in the theory of conformal mapping and in the geometrical theory of functions of a complex variable in general. In addition to its generalizations to multiply-connected domains, it finds wide application in the theory of functions of a complex variable, in mathematical physics, in the theory of elasticity, in aero- and hydromechanics, in electro- and magnetostatics, etc. This theorem was formulated by B. Riemann (1851) for the more general case of simply-connected and, generally speaking, non-single sheeted domains over the complex plane. Instead of using the normalizing conditions "fa= b, argf'a=a" of the conformal mapping , which guarantee its uniqueness, Riemann used for the same purpose the conditions "fa= b, fz=w" , where , and and are points of the boundaries of and , respectively, given in advance. The last conditions are not always correct, given the contemporary definition of a simply-connected domain. In proving his theorem, Riemann drew to a considerable degree on concepts of physics, which also convinced him of the importance of this theorem for applications. D. Hilbert made Riemann's proof mathematically precise by substantiating the so-called Dirichlet principle, which was used by Riemann in his proof.

#### References

[1] | B. Riemann, "Gesammelte mathematischen Abhandlungen" , Dover, reprint (1953) |

[2] | I.I. [I.I. Privalov] Priwalow, "Einführung in die Funktionentheorie" , 1–3 , Teubner (1958–1959) (Translated from Russian) MR0342680 MR0264037 MR0264036 MR0264038 MR0123686 MR0123685 MR0098843 Zbl 0177.33401 Zbl 0141.26003 Zbl 0141.26002 Zbl 0082.28802 |

[3] | G.M. Goluzin, "Geometric theory of functions of a complex variable" , Transl. Math. Monogr. , 26 , Amer. Math. Soc. (1969) (Translated from Russian) MR0247039 Zbl 0183.07502 |

#### Comments

This theorem is also called the Riemann mapping theorem.

#### References

[a1] | Z. Nehari, "Conformal mapping" , Dover, reprint (1975) MR0377031 Zbl 0071.07301 Zbl 0052.08201 Zbl 0048.31503 Zbl 0041.41201 |

Riemann's theorem on the rearrangement of terms of a series: If a series in which the terms are real numbers converges but does not converge absolutely, then for any number there is a rearrangement of the terms of this series such that the sum of the series obtained will be equal to . Furthermore, there is a rearrangement of the terms of the series such that its sum will be equal to one of the previously given signed infinities or , and also such that its sum will not be equal either to or to , but the sequences of its partial sums have given liminf and limsup , with (see Series).

*L.D. Kudryavtsev*

#### Comments

#### References

[a1] | K. Knopp, "Theorie und Anwendung der unendlichen Reihen" , Springer (1964) (English translation: Blackie, 1951 & Dover, reprint, 1990) MR0028430 Zbl 0124.28302 |

[a2] | W. Rudin, "Principles of mathematical analysis" , McGraw-Hill (1976) pp. 75–78 MR0385023 Zbl 0346.26002 |

#### Comments

Another "Riemann theorem" is the Riemann removable singularities theorem, see Removable set.

**How to Cite This Entry:**

Riemann theorem.

*Encyclopedia of Mathematics.*URL: http://www.encyclopediaofmath.org/index.php?title=Riemann_theorem&oldid=24555