Univalent function

In mathematics, in the branch of complex analysis, a holomorphic function on an open subset of the complex plane is called univalent if it is injective.[1][2]

Examples

The function f : z 2 z + z 2 {\displaystyle f\colon z\mapsto 2z+z^{2}} is univalent in the open unit disc, as f ( z ) = f ( w ) {\displaystyle f(z)=f(w)} implies that f ( z ) f ( w ) = ( z w ) ( z + w + 2 ) = 0 {\displaystyle f(z)-f(w)=(z-w)(z+w+2)=0} . As the second factor is non-zero in the open unit disc, z = w {\displaystyle z=w} so f {\displaystyle f} is injective.

Basic properties

One can prove that if G {\displaystyle G} and Ω {\displaystyle \Omega } are two open connected sets in the complex plane, and

f : G Ω {\displaystyle f:G\to \Omega }

is a univalent function such that f ( G ) = Ω {\displaystyle f(G)=\Omega } (that is, f {\displaystyle f} is surjective), then the derivative of f {\displaystyle f} is never zero, f {\displaystyle f} is invertible, and its inverse f 1 {\displaystyle f^{-1}} is also holomorphic. More, one has by the chain rule

( f 1 ) ( f ( z ) ) = 1 f ( z ) {\displaystyle (f^{-1})'(f(z))={\frac {1}{f'(z)}}}

for all z {\displaystyle z} in G . {\displaystyle G.}

Comparison with real functions

For real analytic functions, unlike for complex analytic (that is, holomorphic) functions, these statements fail to hold. For example, consider the function

f : ( 1 , 1 ) ( 1 , 1 ) {\displaystyle f:(-1,1)\to (-1,1)\,}

given by f ( x ) = x 3 {\displaystyle f(x)=x^{3}} . This function is clearly injective, but its derivative is 0 at x = 0 {\displaystyle x=0} , and its inverse is not analytic, or even differentiable, on the whole interval ( 1 , 1 ) {\displaystyle (-1,1)} . Consequently, if we enlarge the domain to an open subset G {\displaystyle G} of the complex plane, it must fail to be injective; and this is the case, since (for example) f ( ε ω ) = f ( ε ) {\displaystyle f(\varepsilon \omega )=f(\varepsilon )} (where ω {\displaystyle \omega } is a primitive cube root of unity and ε {\displaystyle \varepsilon } is a positive real number smaller than the radius of G {\displaystyle G} as a neighbourhood of 0 {\displaystyle 0} ).

See also

  • Biholomorphic mapping – Bijective holomorphic function with a holomorphic inversePages displaying short descriptions of redirect targets
  • De Branges's theorem – Statement in complex analysis; formerly the Bieberbach conjecture
  • Koebe quarter theorem – Statement in complex analysis
  • Riemann mapping theorem – Mathematical theorem
  • Nevanlinna's criterion – Characterization of starlike univalent holomorphic functions

Note

  1. ^ (Conway 1995, p. 32, chapter 14: Conformal equivalence for simply connected regions, Definition 1.12: "A function on an open set is univalent if it is analytic and one-to-one.")
  2. ^ (Nehari 1975)

References

  • Conway, John B. (1995). "Conformal Equivalence for Simply Connected Regions". Functions of One Complex Variable II. Graduate Texts in Mathematics. Vol. 159. doi:10.1007/978-1-4612-0817-4. ISBN 978-1-4612-6911-3.
  • "Univalent Functions". Sources in the Development of Mathematics. 2011. pp. 907–928. doi:10.1017/CBO9780511844195.041. ISBN 9780521114707.
  • Duren, P. L. (1983). Univalent Functions. Springer New York, NY. p. XIV, 384. ISBN 978-1-4419-2816-0.
  • Gong, Sheng (1998). Convex and Starlike Mappings in Several Complex Variables. doi:10.1007/978-94-011-5206-8. ISBN 978-94-010-6191-9.
  • Jarnicki, Marek; Pflug, Peter (2006). "A remark on separate holomorphy". Studia Mathematica. 174 (3): 309–317. arXiv:math/0507305. doi:10.4064/SM174-3-5. S2CID 15660985.
  • Nehari, Zeev (1975). Conformal mapping. New York: Dover Publications. p. 146. ISBN 0-486-61137-X. OCLC 1504503.

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