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{{distinguish|Carleson's theorem}}
{{short description|Uniqueness theorem in complex analysis}}
{{short description|Uniqueness theorem in complex analysis}}
In [[mathematics]], in the area of [[complex analysis]], '''Carlson's theorem''' is a [[uniqueness theorem]] which was discovered by [[Fritz Carlson|Fritz David Carlson]]. Informally, it states that two different analytic functions which do not grow very fast at infinity can not coincide at the integers. The theorem may be obtained from the [[Phragmén–Lindelöf theorem]], which is itself an extension of the [[maximum-modulus theorem]].
In [[mathematics]], in the area of [[complex analysis]], '''Carlson's theorem''' is a [[uniqueness theorem]] which was discovered by [[Fritz Carlson|Fritz David Carlson]]. Informally, it states that two different analytic functions which do not grow very fast at infinity can not coincide at the integers. The theorem may be obtained from the [[Phragmén–Lindelöf theorem]], which is itself an extension of the [[maximum-modulus theorem]].
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==Statement==
==Statement==


Assume that {{math|''f''}} satisfies the following three conditions: the first two conditions bound the growth of {{math|''f''}} at infinity, whereas the third one states that {{math|''f''}} vanishes on the non-negative integers.
Assume that {{math|''f''}} satisfies the following three conditions. The first two conditions bound the growth of {{math|''f''}} at infinity, whereas the third one states that {{math|''f''}} vanishes on the non-negative integers.


* {{math|''f''(''z'')}} is an [[entire function]] of [[exponential type]], meaning that
# {{math|''f''(''z'')}} is an [[entire function]] of [[exponential type]], meaning that <math display="block">|f(z)| \leq C e^{\tau|z|}, \quad z \in \mathbb{C}</math> for some real values {{math|''C''}}, {{math|''τ''}}.
# There exists {{math|''c'' < {{pi}}}} such that <math display="block">|f(iy)| \leq C e^{c|y|}, \quad y \in \mathbb{R} </math>
# {{math|1=''f''(''n'') = 0}} for every non-negative integer {{math|''n''}}.


Then {{math|''f''}} is [[constant function|identically zero]].
::<math>|f(z)| \leq C e^{\tau|z|}, \quad z \in \mathbb{C}</math>

:for some real values {{math|''C''}}, {{math|''τ''}}.

* There exists {{math|''c'' < {{pi}}}} such that

::<math>|f(iy)| \leq C e^{c|y|}, \quad y \in \mathbb{R} </math>

* {{math|1=''f''(''n'') = 0}} for any non-negative integer {{math|''n''}}.

Then {{math|''f''}} is identically zero.


==Sharpness==
==Sharpness==
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The first condition may be relaxed: it is enough to assume that {{math|''f''}} is analytic in {{math|Re ''z'' > 0}}, continuous in {{math|Re ''z'' ≥ 0}}, and satisfies
The first condition may be relaxed: it is enough to assume that {{math|''f''}} is analytic in {{math|Re ''z'' > 0}}, continuous in {{math|Re ''z'' ≥ 0}}, and satisfies


:<math>|f(z)| \leq C e^{\tau|z|}, \quad \operatorname{Re} z > 0</math>
<math display="block">|f(z)| \leq C e^{\tau|z|}, \quad \operatorname{Re} z > 0</math>


for some real values {{math|''C''}}, {{math|''τ''}}.
for some real values {{math|''C''}}, {{math|''τ''}}.
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===Third condition===
===Third condition===
A result, due to {{harvtxt|Rubel|1956}}, relaxes the condition that {{math|''f''}} vanish on the integers. Namely, Rubel showed that the conclusion of the theorem remains valid if {{math|''f''}} vanishes on a subset {{math|''A'' ⊂ {{mset|0, 1, 2, }}}} of [[upper density]] 1, meaning that
A result, due to {{harvtxt|Rubel|1956}}, relaxes the condition that {{math|''f''}} vanish on the integers. Namely, Rubel showed that the conclusion of the theorem remains valid if {{math|''f''}} vanishes on a subset {{math|''A'' ⊂ {{mset|0, 1, 2, ...}}}} of [[upper density]] 1, meaning that


:<math> \limsup_{n \to \infty} \frac{\left| A \cap \{0,1,\cdots,n-1\} \right|}{n} = 1. </math>
<math display="block"> \limsup_{n \to \infty} \frac{\left| A \cap \{0,1,\ldots,n-1\} \right|}{n} = 1. </math>


This condition is sharp, meaning that the theorem fails for sets {{math|''A''}} of upper density smaller than 1.
This condition is sharp, meaning that the theorem fails for sets {{math|''A''}} of upper density smaller than 1.


==Applications==
==Applications==
Suppose {{math|''f''(''z'')}} is a function that possess all finite [[forward difference]]s <math>\Delta^n f(0)</math>. Consider then the [[Newton series]]
Suppose {{math|''f''(''z'')}} is a function that possesses all finite [[forward difference]]s <math>\Delta^n f(0)</math>. Consider then the [[Newton series]]


:<math>g(z)=\sum_{n=0}^\infty {z \choose n} \Delta^n f(0)</math>
<math display="block">g(z) = \sum_{n=0}^\infty {z \choose n} \, \Delta^n f(0)</math>


with <math>{z \choose n}</math> is the [[binomial coefficient]] and <math>\Delta^n f(0)</math> is the {{math|''n''}}-th [[forward difference]]. By construction, one then has that {{math|1=''f''(''k'') = ''g''(''k'')}} for all non-negative integers {{math|''k''}}, so that the difference {{math|1=''h''(''k'') = ''f''(''k'') − ''g''(''k'') = 0}}. This is one of the conditions of Carlson's theorem; if {{math|''h''}} obeys the others, then {{math|''h''}} is identically zero, and the finite differences for {{math|''f''}} uniquely determine its Newton series. That is, if a Newton series for {{math|''f''}} exists, and the difference satisfies the Carlson conditions, then {{math|''f''}} is unique.
with <math display="inline">{z \choose n}</math> is the [[binomial coefficient]] and <math>\Delta^n f(0)</math> is the {{math|''n''}}-th [[forward difference]]. By construction, one then has that {{math|1=''f''(''k'') = ''g''(''k'')}} for all non-negative integers {{math|''k''}}, so that the difference {{math|1=''h''(''k'') = ''f''(''k'') − ''g''(''k'') = 0}}. This is one of the conditions of Carlson's theorem; if {{math|''h''}} obeys the others, then {{math|''h''}} is identically zero, and the finite differences for {{math|''f''}} uniquely determine its Newton series. That is, if a Newton series for {{math|''f''}} exists, and the difference satisfies the Carlson conditions, then {{math|''f''}} is unique.


==See also==
==See also==
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* F. Carlson, ''Sur une classe de séries de Taylor'', (1914) Dissertation, Uppsala, Sweden, 1914.
* F. Carlson, ''Sur une classe de séries de Taylor'', (1914) Dissertation, Uppsala, Sweden, 1914.
* {{cite journal | last1 = Riesz | first1 = M. | author-link = M. Riesz | year = 1920 | title = Sur le principe de Phragmén–Lindelöf | journal = Proceedings of the Cambridge Philosophical Society | volume = 20 | pages = 205–107 }}, cor '''21'''(1921) p.&nbsp;6.
* {{cite journal | last1 = Riesz | first1 = M. | author-link = M. Riesz | year = 1920 | title = Sur le principe de Phragmén–Lindelöf | journal = Proceedings of the Cambridge Philosophical Society | volume = 20 | pages = 205–107 }}, cor '''21'''(1921) p.&nbsp;6.
* {{cite journal | last1 = Hardy | first1 = G.H. | author-link = G.H. Hardy | year = 1920 | title = On two theorems of F. Carlson and S. Wigert | url =https://zenodo.org/record/2485085/files/article.pdf | journal = Acta Mathematica | volume = 42 | pages = 327–339 | doi=10.1007/bf02404414}}
* {{cite journal | last1 = Hardy | first1 = G.H. | author-link = G.H. Hardy | year = 1920 | title = On two theorems of F. Carlson and S. Wigert | url =https://zenodo.org/record/2485085 | journal = Acta Mathematica | volume = 42 | pages = 327–339 | doi=10.1007/bf02404414| doi-access = free }}
* [[E.C. Titchmarsh]], ''The Theory of Functions (2nd Ed)'' (1939) Oxford University Press ''(See section 5.81)''
* [[E.C. Titchmarsh]], ''The Theory of Functions (2nd Ed)'' (1939) Oxford University Press ''(See section 5.81)''
* R. P. Boas, Jr., ''Entire functions'', (1954) Academic Press, New York.
* R. P. Boas, Jr., ''Entire functions'', (1954) Academic Press, New York.
* {{cite journal | last1 = DeMar | first1 = R. | year = 1962 | title = Existence of interpolating functions of exponential type | journal = Trans. Amer. Math. Soc. | volume = 105 | issue = 3| pages = 359–371 | doi=10.1090/s0002-9947-1962-0141920-6| doi-access = free }}
* {{cite journal | last1 = DeMar | first1 = R. | year = 1962 | title = Existence of interpolating functions of exponential type | journal = Trans. Amer. Math. Soc. | volume = 105 | issue = 3| pages = 359–371 | doi=10.1090/s0002-9947-1962-0141920-6| doi-access = free }}
* {{cite journal | last1 = DeMar | first1 = R. | year = 1963 | title = Vanishing Central Differences | journal = Proc. Amer. Math. Soc. | volume = 14 | pages = 64–67 | doi=10.1090/s0002-9939-1963-0143907-2| doi-access = free }}
* {{cite journal | last1 = DeMar | first1 = R. | year = 1963 | title = Vanishing Central Differences | journal = Proc. Amer. Math. Soc. | volume = 14 | pages = 64–67 | doi=10.1090/s0002-9939-1963-0143907-2| doi-access = free }}
* {{citation|mr=0081944|last=Rubel|first=L. A.|title=Necessary and sufficient conditions for Carlson's theorem on entire functions|journal=Trans. Amer. Math. Soc.|volume=83|issue=2|year=1956|pages=417&ndash;429|jstor=1992882|doi=10.1090/s0002-9947-1956-0081944-8|pmc=528143|pmid=16578453}}
* {{citation|mr=0081944|last=Rubel|first=L. A.|title=Necessary and sufficient conditions for Carlson's theorem on entire functions | journal=Trans. Amer. Math. Soc.|volume=83|issue=2|year=1956|pages=417&ndash;429|jstor=1992882 | doi=10.1090/s0002-9947-1956-0081944-8|pmc=528143|pmid=16578453}}


[[Category:Factorial and binomial topics]]
[[Category:Factorial and binomial topics]]

Latest revision as of 00:59, 28 July 2023

In mathematics, in the area of complex analysis, Carlson's theorem is a uniqueness theorem which was discovered by Fritz David Carlson. Informally, it states that two different analytic functions which do not grow very fast at infinity can not coincide at the integers. The theorem may be obtained from the Phragmén–Lindelöf theorem, which is itself an extension of the maximum-modulus theorem.

Carlson's theorem is typically invoked to defend the uniqueness of a Newton series expansion. Carlson's theorem has generalized analogues for other expansions.

Statement

[edit]

Assume that f satisfies the following three conditions. The first two conditions bound the growth of f at infinity, whereas the third one states that f vanishes on the non-negative integers.

  1. f(z) is an entire function of exponential type, meaning that for some real values C, τ.
  2. There exists c < π such that
  3. f(n) = 0 for every non-negative integer n.

Then f is identically zero.

Sharpness

[edit]

First condition

[edit]

The first condition may be relaxed: it is enough to assume that f is analytic in Re z > 0, continuous in Re z ≥ 0, and satisfies

for some real values C, τ.

Second condition

[edit]

To see that the second condition is sharp, consider the function f(z) = sin(πz). It vanishes on the integers; however, it grows exponentially on the imaginary axis with a growth rate of c = π, and indeed it is not identically zero.

Third condition

[edit]

A result, due to Rubel (1956), relaxes the condition that f vanish on the integers. Namely, Rubel showed that the conclusion of the theorem remains valid if f vanishes on a subset A ⊂ {0, 1, 2, ...} of upper density 1, meaning that

This condition is sharp, meaning that the theorem fails for sets A of upper density smaller than 1.

Applications

[edit]

Suppose f(z) is a function that possesses all finite forward differences . Consider then the Newton series

with is the binomial coefficient and is the n-th forward difference. By construction, one then has that f(k) = g(k) for all non-negative integers k, so that the difference h(k) = f(k) − g(k) = 0. This is one of the conditions of Carlson's theorem; if h obeys the others, then h is identically zero, and the finite differences for f uniquely determine its Newton series. That is, if a Newton series for f exists, and the difference satisfies the Carlson conditions, then f is unique.

See also

[edit]

References

[edit]
  • F. Carlson, Sur une classe de séries de Taylor, (1914) Dissertation, Uppsala, Sweden, 1914.
  • Riesz, M. (1920). "Sur le principe de Phragmén–Lindelöf". Proceedings of the Cambridge Philosophical Society. 20: 205–107., cor 21(1921) p. 6.
  • Hardy, G.H. (1920). "On two theorems of F. Carlson and S. Wigert". Acta Mathematica. 42: 327–339. doi:10.1007/bf02404414.
  • E.C. Titchmarsh, The Theory of Functions (2nd Ed) (1939) Oxford University Press (See section 5.81)
  • R. P. Boas, Jr., Entire functions, (1954) Academic Press, New York.
  • DeMar, R. (1962). "Existence of interpolating functions of exponential type". Trans. Amer. Math. Soc. 105 (3): 359–371. doi:10.1090/s0002-9947-1962-0141920-6.
  • DeMar, R. (1963). "Vanishing Central Differences". Proc. Amer. Math. Soc. 14: 64–67. doi:10.1090/s0002-9939-1963-0143907-2.
  • Rubel, L. A. (1956), "Necessary and sufficient conditions for Carlson's theorem on entire functions", Trans. Amer. Math. Soc., 83 (2): 417–429, doi:10.1090/s0002-9947-1956-0081944-8, JSTOR 1992882, MR 0081944, PMC 528143, PMID 16578453