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In complex analysis, a branch of mathematics, the Hadamard three-circle theorem is a result about the behavior of holomorphic functions.

Let $f(z)$ be a holomorphic function on the annulus

r_{1}\leq \left|z\right|\leq r_{3}.

Let $M(r)$ be the maximum of $|f(z)|$ on the circle $|z|=r.$ Then, $\log M(r)$ is a convex function of the logarithm $\log(r).$ Moreover, if $f(z)$ is not of the form $cz^{\lambda }$ for some constants $\lambda$ and $c$ , then $\log M(r)$ is strictly convex as a function of $\log(r).$

The conclusion of the theorem can be restated as

\log \left({\frac {r_{3}}{r_{1}}}\right)\log M(r_{2})\leq \log \left({\frac {r_{3}}{r_{2}}}\right)\log M(r_{1})+\log \left({\frac {r_{2}}{r_{1}}}\right)\log M(r_{3})

for any three concentric circles of radii $r_{1}<r_{2}<r_{3}.$

History

A statement and proof for the theorem was given by J.E. Littlewood in 1912, but he attributes it to no one in particular, stating it as a known theorem. Harald Bohr and Edmund Landau attribute the theorem to Jacques Hadamard, writing in 1896; Hadamard published no proof.^[1]

Proof

The three circles theorem follows from the fact that for any real a, the function Re log(z^af(z)) is harmonic between two circles, and therefore takes its maximum value on one of the circles. The theorem follows by choosing the constant a so that this harmonic function has the same maximum value on both circles.

The theorem can also be deduced directly from Hadamard's three-line theorem.^[2]

Notes

^ Edwards 1974, Section 9.3
^ Ullrich 2008

References

Edwards, H.M. (1974), Riemann's Zeta Function, Dover Publications, ISBN 0-486-41740-9
Littlewood, J. E. (1912), "Quelques consequences de l'hypothese que la function ζ(s) de Riemann n'a pas de zeros dans le demi-plan Re(s) > 1/2.", Les Comptes rendus de l'Académie des sciences, 154: 263–266
E. C. Titchmarsh, The theory of the Riemann Zeta-Function, (1951) Oxford at the Clarendon Press, Oxford. (See chapter 14)
Ullrich, David C. (2008), Complex made simple, Graduate Studies in Mathematics, vol. 97, American Mathematical Society, pp. 386–387, ISBN 0821844792

This article incorporates material from Hadamard three-circle theorem on PlanetMath, which is licensed under the Creative Commons Attribution/Share-Alike License.

External links

"proof of Hadamard three-circle theorem"

[1] Edwards 1974, Section 9.3

[2] Ullrich 2008

[1]

[2]

@@ Line 1: / Line 1: @@
 In [[complex analysis]], a branch of [[mathematics]], the
 '''Hadamard three-circle theorem''' is a result about the behavior of [[holomorphic function]]s.
 Let <math>f(z)</math> be a holomorphic function on the [[annulus (mathematics)|annulus]]
 :<math>r_1\leq\left| z\right| \leq r_3.</math>
 Let <math>M(r)</math> be the [[maxima and minima|maximum]] of <math>|f(z)|</math> on the [[circle]] <math>|z|=r.</math> Then, <math>\log M(r)</math> is a [[convex function]] of the [[logarithm]] <math>\log (r).</math> Moreover, if <math>f(z)</math> is not of the form <math>cz^\lambda</math> for some [[Coefficient|constants]] <math>\lambda</math> and <math>c</math>, then <math>\log M(r)</math> is  strictly convex as a function of <math>\log (r).</math>
@@ Line 10: / Line 10: @@
 The conclusion of the [[theorem]] can be restated as
 :<math>\log\left(\frac{r_3}{r_1}\right)\log M(r_2)\leq
 \log\left(\frac{r_3}{r_2}\right)\log M(r_1)
 +\log\left(\frac{r_2}{r_1}\right)\log M(r_3)</math>
 for any three [[concentric circles]] of radii <math>r_1<r_2<r_3.</math>
 ==History==
-A statement and proof for the theorem was given by [[J.E. Littlewood]] in 1912, but he attributes it to no one in particular, stating it as a known theorem. [[Harald Bohr]] and [[Edmund Landau]] attribute the theorem to [[Jacques Hadamard]], writing in 1896; Hadamard  published no proof.{{ref|Ed74}}
+A statement and proof for the theorem was given by [[J.E. Littlewood]] in 1912, but he attributes it to no one in particular, stating it as a known theorem. [[Harald Bohr]] and [[Edmund Landau]] attribute the theorem to [[Jacques Hadamard]], writing in 1896; Hadamard  published no proof.<ref>{{harvnb|Edwards|1974|loc=Section 9.3}}</ref>
 ==Proof==
-The three circles theorem follows from the fact that for any real ''a'', the function Re log(''z''<sup>''a''</sup>''f''(''z'')) is harmonic between two circles, and therefore takes its maximum value on one of the circles. The theorem follows by choosing the constant ''a'' so that this harmonic function has the same maximum value on both circles.
+The three circles theorem follows from the fact that for any real ''a'', the function Re log(''z''<sup>''a''</sup>''f''(''z'')) is harmonic between two circles, and therefore takes its maximum value on one of the circles. The theorem follows by choosing the constant ''a'' so that this [[harmonic function]] has the same maximum value on both circles.
-The theorem can also be deduced  directly from [[Hadamard three-lines theorem|Hadamard's three-lines theorem]].<ref>{{harvnb|Ullrich|2008}}</ref>
+The theorem can also be deduced  directly from [[Hadamard three-line theorem|Hadamard's three-line theorem]].<ref>{{harvnb|Ullrich|2008}}</ref>
 ==See also==
-*[[maximum principle]]
+*[[Maximum principle]]
-*[[logarithmically convex function]]
+*[[Logarithmically convex function]]
 *[[Hardy's theorem]]
-*[[Hadamard three-lines theorem]]
+*[[Hadamard three-line theorem ]]
 *[[Borel–Carathéodory theorem]]
 *[[Phragmén–Lindelöf principle]]
@@ Line 34: / Line 34: @@
 ==Notes==
 {{reflist}}
-* {{note|Ed74}} [[Harold Edwards (mathematician)|H.M. Edwards]], ''Riemann's Zeta Function'', (1974) Dover Publications, ISBN 0-486-41740-9 ''(See section 9.3.)''
 ==References==
-*{{Citation | last1=Littlewood | first1=J. E. | title=Quelques consequences de l'hypothese que la function ζ(s) de Riemann n'a pas de zeros dans le demi-plan Re(s) > 1/2. | year=1912 | journal=[[Les Comptes rendus de l'Académie des sciences]] | volume=154 | pages=263–266}}
+* {{citation|first=H.M.|last=Edwards|authorlink=Harold Edwards (mathematician)|title=Riemann's Zeta Function|year=1974|publisher=Dover Publications|isbn=0-486-41740-9}}
+* {{Citation | last1=Littlewood | first1=J. E. | title=Quelques consequences de l'hypothese que la function ζ(s) de Riemann n'a pas de zeros dans le demi-plan Re(s) > 1/2. | year=1912 | journal=[[Les Comptes rendus de l'Académie des sciences]] | volume=154 | pages=263–266}}
 * [[E. C. Titchmarsh]], ''The theory of the Riemann Zeta-Function'', (1951) Oxford at the Clarendon Press, Oxford. ''(See chapter 14)''
-*{{citation|title=Complex made simple|volume= 97|series= Graduate studies in mathematics|first=	David C.|last= Ullrich|publisher=[[American Mathematical Society]]|year= 2008|id=ISBN 0821844792|pages=386–387}}
+* {{citation|title=Complex made simple|volume= 97|series= [[Graduate Studies in Mathematics]]|first=David C.|last= Ullrich|publisher=[[American Mathematical Society]]|year= 2008|isbn=0821844792|pages=386–387}}
 {{PlanetMath attribution|id=5605|title=Hadamard three-circle theorem}}
-==External links==
+== External links ==
-* {{PlanetMath reference|7943|proof of Hadamard three-circle theorem}}
+* [https://planetmath.org/proofofhadamardthreecircletheorem "proof of Hadamard three-circle theorem"]
+[[Category:Inequalities]]
 [[Category:Theorems in complex analysis]]
-[[fr:Théorème des trois cercles de Hadamard]]
-[[ja:アダマールの三円定理]]
-[[ru:Теорема Адамара о трёх кругах]]
-[[tr:Hadamard üç çember teoremi]]
-[[zh:阿达马三圆定理]]