Difference between revisions of "User:Richard Pinch/sandbox-CZ"
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− | = | + | =Selberg sieve= |
− | + | A technique for estimating the size of "sifted sets" of [[positive integer]]s which satisfy a set of conditions which are expressed by [[Congruence relation#Modular arithmetic|congruence]]s. It was developed by [[Atle Selberg]] in the 1940s. | |
− | : | + | ==Description== |
− | + | In terms of [[sieve theory]] the Selberg sieve is of ''combinatorial type'': that is, derives from a careful use of the [[inclusion-exclusion principle]]. Selberg replaced the values of the [[Möbius function]] which arise in this by a system of weights which are then optimised to fit the given problem. The result gives an ''upper bound'' for the size of the sifted set. | |
− | + | ||
− | + | Let ''A'' be a set of positive integers ≤ ''x'' and let ''P'' be a set of primes. For each ''p'' in ''P'', let ''A''<sub>''p''</sub> denote the set of elements of ''A'' divisible by ''p'' and extend this to let ''A''<sub>''d''</sub> the intersection of the ''A''<sub>''p''</sub> for ''p'' dividing ''d'', when ''d'' is a product of distinct primes from ''P''. Further let A<sub>1</sub> denote ''A'' itself. Let ''z'' be a positive real number and ''P''(''z'') denote the product of the primes in ''P'' which are ≤ ''z''. The object of the sieve is to estimate | |
− | + | ||
− | </ | + | :<math>S(A,P,z) = \left\vert A \setminus \bigcup_{p \in P(z)} A_p \right\vert . </math> |
− | + | ||
+ | We assume that |''A''<sub>''d''</sub>| may be estimated by | ||
+ | |||
+ | :<math> \left\vert A_d \right\vert = \frac{1}{f(d)} X + R_d . </math> | ||
− | + | where ''f'' is a [[multiplicative function]] and ''X'' = |''A''|. Let the function ''g'' be obtained from ''f'' by [[Möbius inversion formula|Möbius inversion]], that is | |
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− | = | + | :<math> g(n) = \sum_{d \mid n} \mu(d) f(n/d) </math> |
− | + | :<math> f(n) = \sum_{d \mid n} g(d) </math> | |
− | = | ||
− | |||
− | + | where μ is the [[Möbius function]]. | |
− | + | Put | |
− | :<math> | + | :<math> V(z) = \sum_{\begin{smallmatrix}d < z \\ d \mid P(z)\end{smallmatrix}} \frac{\mu^2(d)}{g(d)} . </math> |
− | + | Then | |
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− | + | :<math> S(A,P,z) \le \frac{X}{V(z)} + O\left({\sum_{\begin{smallmatrix} d_1,d_2 < z \\ d_1,d_2 \mid P(z)\end{smallmatrix}} \left\vert R_{[d_1,d_2]} \right\vert} \right) .</math> | |
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− | + | It is often useful to estimate ''V''(''z'') by the bound | |
− | |||
+ | :<math> V(z) \ge \sum_{d \le z} \frac{1}{f(d)} . \, </math> | ||
− | = | + | ==Applications== |
+ | * The [[Brun-Titchmarsh theorem]] on the number of primes in an arithmetic progression; | ||
+ | * The number of ''n'' ≤ ''x'' such that ''n'' is coprime to φ(''n'') is asymptotic to e<sup>-γ</sup> ''x'' / log log log (''x'') . | ||
− | + | ==References== | |
+ | * {{User:Richard Pinch/sandbox/Ref | author=Alina Carmen Cojocaru | coauthors=M. Ram Murty | title=An introduction to sieve methods and their applications | series=London Mathematical Society Student Texts | volume=66 | publisher=[[Cambridge University Press]] | isbn=0-521-61275-6 | pages=113-134 }} | ||
+ | * {{User:Richard Pinch/sandbox/Ref | author=George Greaves | title=Sieves in number theory | publisher=[[Springer-Verlag]] | date=2001 | isbn=3-540-41647-1}} | ||
+ | * {{User:Richard Pinch/sandbox/Ref | author=Heini Halberstam | coauthors=H.E. Richert | title=Sieve Methods | publisher=[[Academic Press]] | date=1974 | isbn=0-12-318250-6}} | ||
+ | * {{User:Richard Pinch/sandbox/Ref | author= Christopher Hooley | authorlink=Christopher Hooley | title=Applications of sieve methods to the theory of numbers | publisher=Cambridge University Press | date=1976 | isbn=0-521-20915-3| pages=7-12}} | ||
+ | * {{User:Richard Pinch/sandbox/Ref | author=Atle Selberg | authorlink=Atle Selberg | title=On an elementary method in the theory of primes | journal=Norske Vid. Selsk. Forh. Trondheim | volume=19 | year=1947 | pages=64-67 }} | ||
− | + | =Separation axioms= | |
+ | In [[topology]], '''separation axioms''' describe classes of [[topological space]] according to how well the [[open set]]s of the topology distinguish between distinct points. | ||
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− | + | ==Terminology== | |
− | + | A ''neighbourhood of a point'' ''x'' in a topological space ''X'' is a set ''N'' such that ''x'' is in the interior of ''N''; that is, there is an open set ''U'' such that <math>x \in U \subseteq N</math>. | |
− | + | A ''neighbourhood of a set'' ''A'' in ''X'' is a set ''N'' such that ''A'' is contained in the interior of ''N''; that is, there is an open set ''U'' such that <math>A \subseteq U \subseteq N</math>. | |
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− | + | Subsets ''U'' and ''V'' are ''separated'' in ''X'' if ''U'' is disjoint from the [[Closure (topology)|closure]] of ''V'' and ''V'' is disjoint from the closure of ''U''. | |
− | + | A '''Urysohn function''' for subsets ''A'' and ''B'' of ''X'' is a [[continuous function]] ''f'' from ''X'' to the real unit interval such that ''f'' is 0 on ''A'' and 1 on ''B''. | |
− | * | + | ==Axioms== |
− | * | + | A topological space ''X'' is |
− | * | + | * '''T0''' if for any two distinct points there is an open set which contains just one |
− | * | + | * '''T1''' if for any two points ''x'', ''y'' there are open sets ''U'' and ''V'' such that ''U'' contains ''x'' but not ''y'', and ''V'' contains ''y'' but not ''x'' |
− | * { | + | * '''T2''' if any two distinct points have disjoint neighbourhoods |
− | * | + | * '''T2½''' if distinct points have disjoint closed neighbourhoods |
− | * | + | * '''T3''' if a closed set ''A'' and a point ''x'' not in ''A'' have disjoint neighbourhoods |
+ | * '''T3½''' if for any closed set ''A'' and point ''x'' not in ''A'' there is a Urysohn function for ''A'' and {''x''} | ||
+ | * '''T4''' if disjoint closed sets have disjoint neighbourhoods | ||
+ | * '''T5''' if separated sets have disjoint neighbourhoods | ||
− | + | * '''Hausdorff''' is a synonym for T2 | |
− | * | + | * '''completely Hausdorff''' is a synonym for T2½ |
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− | + | * '''regular''' if T0 and T3 | |
+ | * '''completely regular''' if T0 and T3½ | ||
+ | * '''Tychonoff''' is completely regular and T1 | ||
− | + | * '''normal''' if T0 and T4 | |
+ | * '''completely normal''' if T1 and T5 | ||
+ | * '''perfectly normal''' if normal and every closed set is a [[G-delta set|G<sub>δ</sub>]] | ||
− | + | ==Properties== | |
+ | * A space is T1 if and only if each point ([[singleton]]) forms a closed set. | ||
+ | * ''Urysohn's Lemma'': if ''A'' and ''B'' are disjoint closed subsets of a T4 space ''X'', there is a Urysohn function for ''A'' and ''B'''. | ||
+ | ==References== | ||
+ | * {{User:Richard Pinch/sandbox/Ref | last1=Steen | first1=Lynn Arthur | last2=Seebach | first2=J. Arthur Jr. | title=Counterexamples in Topology | year=1978 | publisher=[[Springer-Verlag]] | location=Berlin, New York | isbn=0-387-90312-7 }} | ||
=Turan sieve= | =Turan sieve= | ||
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==References== | ==References== | ||
* {{cite book | author=Alina Carmen Cojocaru | coauthors=M. Ram Murty | title=An introduction to sieve methods and their applications | series=London Mathematical Society Student Texts | volume=66 | publisher=[[Cambridge University Press]] | isbn=0-521-61275-6 | pages=47-62 }} | * {{cite book | author=Alina Carmen Cojocaru | coauthors=M. Ram Murty | title=An introduction to sieve methods and their applications | series=London Mathematical Society Student Texts | volume=66 | publisher=[[Cambridge University Press]] | isbn=0-521-61275-6 | pages=47-62 }} | ||
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=Weierstrass preparation theorem= | =Weierstrass preparation theorem= | ||
In [[algebra]], the '''Weierstrass preparation theorem''' describes a canonical form for [[formal power series]] over a [[complete local ring]]. | In [[algebra]], the '''Weierstrass preparation theorem''' describes a canonical form for [[formal power series]] over a [[complete local ring]]. | ||
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==References== | ==References== | ||
− | * {{ | + | * {{User:Richard Pinch/sandbox/Ref | author=Serge Lang | authorlink=Serge Lang | title=Algebra | edition=3rd ed | publisher=[[Addison-Wesley]] | year=1993 | isbn=0-201-55540-9 | pages=208-209 }} |
Latest revision as of 19:14, 2 May 2020
Selberg sieve
A technique for estimating the size of "sifted sets" of positive integers which satisfy a set of conditions which are expressed by congruences. It was developed by Atle Selberg in the 1940s.
Description
In terms of sieve theory the Selberg sieve is of combinatorial type: that is, derives from a careful use of the inclusion-exclusion principle. Selberg replaced the values of the Möbius function which arise in this by a system of weights which are then optimised to fit the given problem. The result gives an upper bound for the size of the sifted set.
Let A be a set of positive integers ≤ x and let P be a set of primes. For each p in P, let Ap denote the set of elements of A divisible by p and extend this to let Ad the intersection of the Ap for p dividing d, when d is a product of distinct primes from P. Further let A1 denote A itself. Let z be a positive real number and P(z) denote the product of the primes in P which are ≤ z. The object of the sieve is to estimate
\[S(A,P,z) = \left\vert A \setminus \bigcup_{p \in P(z)} A_p \right\vert . \]
We assume that |Ad| may be estimated by
\[ \left\vert A_d \right\vert = \frac{1}{f(d)} X + R_d . \]
where f is a multiplicative function and X = |A|. Let the function g be obtained from f by Möbius inversion, that is
\[ g(n) = \sum_{d \mid n} \mu(d) f(n/d) \] \[ f(n) = \sum_{d \mid n} g(d) \]
where μ is the Möbius function. Put
\[ V(z) = \sum_{\begin{smallmatrix}d < z \\ d \mid P(z)\end{smallmatrix}} \frac{\mu^2(d)}{g(d)} . \]
Then
\[ S(A,P,z) \le \frac{X}{V(z)} + O\left({\sum_{\begin{smallmatrix} d_1,d_2 < z \\ d_1,d_2 \mid P(z)\end{smallmatrix}} \left\vert R_{[d_1,d_2]} \right\vert} \right) .\]
It is often useful to estimate V(z) by the bound
\[ V(z) \ge \sum_{d \le z} \frac{1}{f(d)} . \, \]
Applications
- The Brun-Titchmarsh theorem on the number of primes in an arithmetic progression;
- The number of n ≤ x such that n is coprime to φ(n) is asymptotic to e-γ x / log log log (x) .
References
- Alina Carmen Cojocaru; M. Ram Murty; An introduction to sieve methods and their applications, ser. London Mathematical Society Student Texts 66 , pp. 113-134, Cambridge University Press ISBN: 0-521-61275-6
- George Greaves; Sieves in number theory, , Springer-Verlag ISBN: 3-540-41647-1
- Heini Halberstam; H.E. Richert; Sieve Methods, , Academic Press ISBN: 0-12-318250-6
- Christopher Hooley; Applications of sieve methods to the theory of numbers, , pp. 7-12, Cambridge University Press ISBN: 0-521-20915-3
- Atle Selberg; On an elementary method in the theory of primes, Norske Vid. Selsk. Forh. Trondheim, 19 (1947), pp. 64-67
Separation axioms
In topology, separation axioms describe classes of topological space according to how well the open sets of the topology distinguish between distinct points.
Terminology
A neighbourhood of a point x in a topological space X is a set N such that x is in the interior of N; that is, there is an open set U such that \(x \in U \subseteq N\). A neighbourhood of a set A in X is a set N such that A is contained in the interior of N; that is, there is an open set U such that \(A \subseteq U \subseteq N\).
Subsets U and V are separated in X if U is disjoint from the closure of V and V is disjoint from the closure of U.
A Urysohn function for subsets A and B of X is a continuous function f from X to the real unit interval such that f is 0 on A and 1 on B.
Axioms
A topological space X is
- T0 if for any two distinct points there is an open set which contains just one
- T1 if for any two points x, y there are open sets U and V such that U contains x but not y, and V contains y but not x
- T2 if any two distinct points have disjoint neighbourhoods
- T2½ if distinct points have disjoint closed neighbourhoods
- T3 if a closed set A and a point x not in A have disjoint neighbourhoods
- T3½ if for any closed set A and point x not in A there is a Urysohn function for A and {x}
- T4 if disjoint closed sets have disjoint neighbourhoods
- T5 if separated sets have disjoint neighbourhoods
- Hausdorff is a synonym for T2
- completely Hausdorff is a synonym for T2½
- regular if T0 and T3
- completely regular if T0 and T3½
- Tychonoff is completely regular and T1
- normal if T0 and T4
- completely normal if T1 and T5
- perfectly normal if normal and every closed set is a Gδ
Properties
- A space is T1 if and only if each point (singleton) forms a closed set.
- Urysohn's Lemma: if A and B are disjoint closed subsets of a T4 space X, there is a Urysohn function for A and B'.
References
- Steen, Lynn Arthur; Seebach, J. Arthur Jr.; Counterexamples in Topology, (1978), Springer-Verlag ISBN: 0-387-90312-7
Turan sieve
In mathematics, in the field of number theory, the Turán sieve is a technique for estimating the size of "sifted sets" of positive integers which satisfy a set of conditions which are expressed by congruences. It was developed by Pál Turán in 1934.
Description
In terms of sieve theory the Turán sieve is of combinatorial type: deriving from a rudimentary form of the inclusion-exclusion principle. The result gives an upper bound for the size of the sifted set.
Let A be a set of positive integers ≤ x and let P be a set of primes. For each p in P, let Ap denote the set of elements of A divisible by p and extend this to let Ad the intersection of the Ap for p dividing d, when d is a product of distinct primes from P. Further let A1 denote A itself. Let z be a positive real number and P(z) denote the product of the primes in P which are ≤ z. The object of the sieve is to estimate
\[S(A,P,z) = \left\vert A \setminus \bigcup_{p \in P(z)} A_p \right\vert . \]
We assume that |Ad| may be estimated, when d is a prime p by
\[ \left\vert A_p \right\vert = \frac{1}{f(p)} X + R_p \]
and when d is a product of two distinct primes d = p q by
\[ \left\vert A_{pq} \right\vert = \frac{1}{f(p)f(q)} X + R_{p,q} \]
where X = |A| and f is a function with the property that 0 ≤ f(d) ≤ 1. Put
\[ U(z) = \sum_{p \mid P(z)} f(p) . \]
Then
\[ S(A,P,z) \le \frac{X}{U(z)} + \frac{2}{U(z)} \sum_{p \mid P(z)} \left\vert R_p \right\vert + \frac{1}{U(z)^2} \sum_{p,q \mid P(z)} \left\vert R_{p,q} \right\vert . \]
Applications
- The Hardy–Ramanujan theorem that the normal order of ω(n), the number of distinct prime factors of a number n, is log(log(n));
- Almost all integer polynomials (taken in order of height) are irreducible.
References
Weierstrass preparation theorem
In algebra, the Weierstrass preparation theorem describes a canonical form for formal power series over a complete local ring.
Let O be a complete local ring and f a formal power series in O''X''. Then f can be written uniquely in the form
\[f = (X^n + b_{n-1}X^{n-1} + \cdots + b_0) u(x) , \,\]
where the bi are in the maximal ideal m of O and u is a unit of O''X''.
The integer n defined by the theorem is the Weierstrass degree of f.
References
- Serge Lang; Algebra, (1993), pp. 208-209, Addison-Wesley ISBN: 0-201-55540-9
Zipf distribution
In probability theory and statistics, the Zipf distribution and zeta distribution refer to a class of discrete probability distributions. They have been used to model the distribution of words in words in a text , of text strings and keys in databases, and of the sizes of businesses and towns.
The Zipf distribution with parameter n assigns probability proportional to 1/r to an integer r ≤ n and zero otherwise, with normalization factor Hn, the n-th harmonic number.
A Zipf-like distribution with parameters n and s assigns probability proportional to 1/rs to an integer r ≤ n and zero otherwise, with normalization factor \(\sum_{r=1}^n 1/r^s\).
The zeta distribution with parameter s assigns probability proportional to 1/rs to all integers r with normalization factor given by the Riemann zeta function 1/ζ(s).
References
Richard Pinch/sandbox-CZ. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Richard_Pinch/sandbox-CZ&oldid=30422