Schwarz reflection principle: Difference between revisions

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In [[mathematics]], the '''Hausdorff moment problem''', named after [[Felix Hausdorff]], asks for necessary and sufficient conditions that a given sequence {&nbsp;''m''<sub>''n''</sub>&nbsp;:&nbsp;''n''&nbsp;=&nbsp;0,&nbsp;1,&nbsp;2,&nbsp;...&nbsp;}
be the sequence of [[moment (mathematics)|moments]]
 
:<math>m_n  = \int_0^1 x^n\,d\mu(x)\,</math>
 
of some [[Borel measure]] ''&mu;'' [[support (measure theory)|supported]] on the closed unit interval [0,&nbsp;1]. In the case ''m''<sub>0</sub>&nbsp;=&nbsp;1, this is equivalent to the existence of a [[random variable]] ''X'' supported on [0,&nbsp;1], such that '''E'''&nbsp;''X''<sup>n</sup>&nbsp;=&nbsp;''m''<sub>''n''</sub>.
 
The essential difference between this and other well-known moment problems is that this is on a bounded interval, whereas in the [[Stieltjes moment problem]] one considers a half-line [0, ∞), and in the [[Hamburger moment problem]] one considers the whole line (−∞, ∞).
 
In 1921, Hausdorff showed that {&nbsp;''m''<sub>''n''</sub>&nbsp;:&nbsp;''n''&nbsp;=&nbsp;0,&nbsp;1,&nbsp;2,&nbsp;...&nbsp;} is such a moment sequence if and only if the sequence is '''completely monotonic''', i.e., its difference sequences satisfy the equation
 
:<math>(-1)^k(\Delta^k m)_n \geq 0</math>
 
for all ''n'',''k'' &ge; 0. Here, &Delta; is the [[difference operator]] given by
 
:<math>(\Delta m)_n = m_{n+1} - m_n.</math>
 
The necessity of this condition is easily seen by the identity
:<math>(-1)^k(\Delta^k m)_n = \int_0^1 x^n (1-x)^k d\mu(x),</math>
which is ''&ge; 0'', being the integral of an almost sure non-negative function.
For example, it is necessary to have
 
:<math>\Delta^4 m_6 = m_6 - 4m_7 + 6m_8 - 4m_9 + m_{10} = \int x^6 (1-x)^4 d\mu(x) \geq 0.</math>
 
==See also==
* [[Total monotonicity]]
 
==References==
* Hausdorff, F. "Summationsmethoden und Momentfolgen. I." ''Mathematische Zeitschrift'' 9, 74-109, 1921.
* Hausdorff, F. "Summationsmethoden und Momentfolgen. II." ''Mathematische Zeitschrift'' 9, 280-299, 1921.
* Feller, W. "An Introduction to Probability Theory and Its Applications", volume II, John Wiley & Sons, 1971.
* [[James Alexander Shohat|Shohat, J.A]].; [[Jacob Tamarkin|Tamarkin, J. D.]] ''The Problem of Moments'', American mathematical society, New York, 1943.
 
==External links==
* [http://mathworld.wolfram.com/MomentProblem.html Moment Problem, on Mathworld]
 
[[Category:Probability theory]]
[[Category:Theory of probability distributions]]
[[Category:Mathematical problems]]

Revision as of 04:07, 22 May 2013

In mathematics, the Hausdorff moment problem, named after Felix Hausdorff, asks for necessary and sufficient conditions that a given sequence { mn : n = 0, 1, 2, ... } be the sequence of moments

mn=01xndμ(x)

of some Borel measure μ supported on the closed unit interval [0, 1]. In the case m0 = 1, this is equivalent to the existence of a random variable X supported on [0, 1], such that E Xn = mn.

The essential difference between this and other well-known moment problems is that this is on a bounded interval, whereas in the Stieltjes moment problem one considers a half-line [0, ∞), and in the Hamburger moment problem one considers the whole line (−∞, ∞).

In 1921, Hausdorff showed that { mn : n = 0, 1, 2, ... } is such a moment sequence if and only if the sequence is completely monotonic, i.e., its difference sequences satisfy the equation

(1)k(Δkm)n0

for all n,k ≥ 0. Here, Δ is the difference operator given by

(Δm)n=mn+1mn.

The necessity of this condition is easily seen by the identity

(1)k(Δkm)n=01xn(1x)kdμ(x),

which is ≥ 0, being the integral of an almost sure non-negative function. For example, it is necessary to have

Δ4m6=m64m7+6m84m9+m10=x6(1x)4dμ(x)0.

See also

References

  • Hausdorff, F. "Summationsmethoden und Momentfolgen. I." Mathematische Zeitschrift 9, 74-109, 1921.
  • Hausdorff, F. "Summationsmethoden und Momentfolgen. II." Mathematische Zeitschrift 9, 280-299, 1921.
  • Feller, W. "An Introduction to Probability Theory and Its Applications", volume II, John Wiley & Sons, 1971.
  • Shohat, J.A.; Tamarkin, J. D. The Problem of Moments, American mathematical society, New York, 1943.

External links

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