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=Modulus (algebraic number theory)=
 
  
In [[mathematics]], in the field of [[algebraic number theory]], a '''modulus''' (or an '''extended ideal''') is a formal product of [[Place (mathematics)|place]]s of an [[algebraic number field]].  It is used to encode [[ramification]] data for [[abelian extension]]s of a number field.  
+
=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.
  
==Definition==
+
==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 ''K'' be an algebraic number field with ring of integers ''R''.  A ''modulus'' is a formal product
+
Let ''A'' be a set of positive integers &le; ''x'' and let ''P'' be a set of primesFor 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 &le; ''z''.  The object of the sieve is to estimate
  
:<math>\mathbf{m} = \prod_{\mathbf{p}} \mathbf{p}^{\nu(\mathbf{p})} </math>
+
:<math>S(A,P,z) = \left\vert A \setminus \bigcup_{p \in P(z)} A_p \right\vert . </math>
  
where '''p''' runs over all places of ''K'', finite or infinite, the exponents ν are zero except for finitely many '''p''', for real places '''r''' we have ν('''r''')=0 or 1 and for complex places ν=0.
+
We assume that |''A''<sub>''d''</sub>| may be estimated by
  
We extend the notion of [[congruence]] to this setting.  Let ''x'' and ''y'' be elements of ''K''.  For a finite place '''p''', that is, a prime ideal of the ring of integers, we define ''x'' and ''y'' to be congruent modulo '''p'''<sup>''n''</sup> if ''x''/''y'' is in the [[valuation ring]] ''R''<sub>'''p'''</sub> of '''p''' and congruent to 1 modulo '''p'''<sup>''n''</sup> in ''R''<sub>'''p'''</sub> in the usual sense of ring theory.  For a real place '''r''' we define ''x'' and ''y'' to be congruent modulo '''r''' if ''x''/''y'' is positive in the real embedding of ''K'' associated to ''r''.  Finally, we define ''x'' and ''y'' to be congruent modulo '''m''' if they are congruent modulo '''p'''<sup>ν('''p''')</sup> whenever ν('''p''') &gt; 0.
+
:<math> \left\vert A_d \right\vert = \frac{1}{f(d)} X + R_d . </math>
  
==Ray class group==
+
where ''f'' is a [[multiplicative function]] and ''X'' &nbsp; = &nbsp; |''A''|.  Let the function ''g'' be obtained from ''f'' by [[Möbius inversion formula|Möbius inversion]], that is
We split the modulus '''m''' into '''m'''<sub>fin</sub> and '''m'''<sub>inf</sub>, the product over the finite and infinite places respectively.  Define
 
  
:<math> K_{\mathbf{m}} = \left\lbrace a/b \in K \mid a,b \in R,~ ab ~\mbox{coprime to}~ \mathbf{m}_\mbox{fin} \right\rbrace ,</math>
+
:<math> g(n) = \sum_{d \mid n} \mu(d) f(n/d) </math>
:<math> K_{\mathbf{m},1} = \left\lbrace x \in K_{\mathbf{m}} \mid x \equiv 1 \pmod \mathbf{m} \right\rbrace .</math>
+
:<math> f(n) = \sum_{d \mid n} g(d) </math>
  
We call the group ''K''<sub>'''m''',1</sub> the '''ray modulo''' '''m'''.
+
where &mu; is the [[Möbius function]].
 +
Put
  
Further define the subgroup of the ideal group ''I''<sup>'''m'''</sup> to be the subgroup generated by ideals coprime to '''m'''<sub>fin</sub>.  The '''ray class group''' modulo '''m''' is the quotient ''I''<sup>'''m'''</sup> / i(''K''<sub>'''m''',1</sub>), where ''i'' is the map from ''K'' to principal ideals in the ideal group. A coset of i(''K''<sub>'''m''',1</sub>) is a '''ray class'''.
+
:<math> V(z) = \sum_{\begin{smallmatrix}d < z \\ d \mid P(z)\end{smallmatrix}} \frac{\mu^2(d)}{g(d)} . </math>
  
Hecke's original definition of [[Hecke character]]s may be interpreted in terms of [[Character (mathematics)|character]]s of the ray class group with respect to some modulus '''m'''.
+
Then
  
===Properties===
+
:<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>
* When '''m''' = 1, the ray class group is just the [[ideal class group]].
+
 
* The ray class group is finite.  Its order is the '''ray class number'''.
+
It is often useful to estimate ''V''(''z'') by the bound
* The ray class number divides the [[Class number (number theory)|class number]] of ''K''.
+
 
 +
:<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'' &le; ''x'' such that ''n'' is coprime to &phi;(''n'') is asymptotic to e<sup>-&gamma;</sup> ''x'' / log log log (''x'') .
  
 
==References==
 
==References==
* {{cite book | author=Harvey Cohn | title=A classical invitation to algebraic numbers and class fields | publisher=[[Springer-Verlag]] | year=1978 | isbn=0-387-90345-3 | pages=163-187 }}
+
* {{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 }}
* {{cite book | author=Harvey Cohn | title=Introduction to the construction of class fields | series=Cambridge studies in advanced mathematics | volume=6 | publisher=[[Cambridge University Press]] | year=1985 | isbn=0-521-24762-4 | pages=99 }}
+
* {{User:Richard Pinch/sandbox/Ref | author=George Greaves | title=Sieves in number theory | publisher=[[Springer-Verlag]] | date=2001 | isbn=3-540-41647-1}}
* {{cite book | author=Gerald J. Janusz | title=Algebraic Number Fields | publisher=[[Academic Press]] | series=Pure and Applied Mathematics | volume=55 | year=1973 | isbn=0-12-380250 | pages=107-113 }}
+
* {{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 }}
  
=Continuant=
+
=Separation axioms=
An  algebraic function of a sequence of variables which has applications in  [[generalized continued fraction]]s and as the determinant of a  [[tridiagonal matrix]].
+
In [[topology]], '''separation axioms''' describe classes of [[topological space]] according to how well the [[open set]]s of the topology distinguish between distinct points.
  
The $n$-th ''continuant'', $K(n)$, of a sequence $\mathbf{a} = a_1,\ldots,a_n,\ldots$  defined recursively by
 
$$
 
K(0) = 1 ;
 
$$
 
$$
 
K(1) = a_1 ;
 
$$
 
$$
 
K(n) = a_n K(n-1) + K(n-2) \ .
 
$$
 
It  may also be obtained by taking the sum of all possible products of  $a_1,\ldots,a_n$ in which any pairs of consecutive terms are deleted.
 
  
An  extended definition takes the continuant with respect to three  sequences $\mathbf a$, $\mathbf b$, $\mathbf c$, so that $K(n)$ is a  function of $a_1,\ldots,a_n$, $b_1,\ldots,b_{n-1}$,  $c_1,\ldots,c_{n-1}$.  In this case the [[recurrence relation]] becomes
+
==Terminology==
$$
+
A ''neighbourhood of a point'' ''x'' in a topological space ''X'' is a set ''N'' such that ''x'' is in the interior of ''N''; that is, there is an open set ''U'' such that <math>x \in U \subseteq N</math>.
K(0) = 1 ; 
+
A ''neighbourhood of a set'' ''A'' in ''X'' is a set ''N'' such that ''A'' is contained in the interior of ''N''; that is, there is an open set ''U'' such that <math>A \subseteq U \subseteq N</math>.
$$
 
$$
 
K(1) = a_1 ;
 
$$
 
$$
 
K(n) = a_n K(n-1) - b_{n-1}c_{n-1} K(n-2) \ .  
 
$$
 
Since  $b_r$ and $c_r$ enter into $K$ only as the product $b_r c_r$ there is no loss of generality in assuming that the $b_r$ are all equal to 1.
 
  
The simple continuant gives the value of a [[continued fraction]] of the form $[a_0;a_1,a_2,\ldots]$.  The $n$-th convergent is
+
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''.
$$
 
\frac{K(n+1,(a_0,\ldots,a_n))}{K(n,(a_1,\ldots,a_n))} \ .
 
$$
 
  
The extended continuant is the determinant of the tridiagonal matrix
+
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''.
$$
+
 
\begin{pmatrix}
+
==Axioms==
a_1 & b_1 &  0  &  0  & \ldots & 0 & 0 \\
+
A topological space ''X'' is
c_1 & a_2 & b_2 &  0  & \ldots & 0 & 0 \\
+
* '''T0''' if for any two distinct points there is an open set which contains just one
0  & c_2 & a_3 & b_3 & \ldots & 0 & 0 \\
+
* '''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''
\vdots & \ddots & \ddots & \ddots & & \vdots & \vdots \\
+
* '''T2''' if any two distinct points have disjoint neighbourhoods
0 & 0 & 0 & 0 & \ldots & c_{n-1} & a_n
+
* '''T2½''' if distinct points have disjoint closed neighbourhoods
\end{pmatrix} \ .
+
* '''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 [[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==
 
==References==
* Thomas Muir. ''A treatise on the theory of determinants''. (Dover Publications, 1960 [1933]), pp516-525.
+
* {{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=
 +
 
 +
In [[mathematics]], in the field of [[number theory]], the '''Turán sieve''' is 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 [[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.
  
=ABC conjecture=
+
Let ''A'' be a set of positive integers &le; ''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 &le; ''z''.  The object of the sieve is to estimate
  
In mathematics, the '''ABC conjecture''' relates the prime factors of two integers to those of their sum.  It was proposed by [[David Masser]] and [[Joseph Oesterlé]] in 1985.  It is connected with other problems of [[number theory]]: for example, the truth of the ABC conjecture would provide a new proof of [[Fermat's Last Theorem]].
+
:<math>S(A,P,z) = \left\vert A \setminus \bigcup_{p \in P(z)} A_p \right\vert . </math>
  
==Statement==
+
We assume that |''A''<sub>''d''</sub>| may be estimated, when ''d'' is a prime ''p'' by
Define the ''radical'' of an integer to be the product of its distinct prime factors
 
  
:<math> r(n) = \prod_{p|n} p \ . </math>
+
:<math> \left\vert A_p \right\vert = \frac{1}{f(p)} X + R_p  </math>
  
Suppose now that the equation <math>A + B + C = 0</math> holds for coprime integers <math>A,B,C</math>.  The conjecture asserts that for every <math>\epsilon > 0</math> there exists <math>\kappa(\epsilon) > 0</math> such that
+
and when ''d'' is a product of two distinct primes ''d'' = ''p'' ''q'' by
  
:<math> |A|, |B|, |C| < \kappa(\epsilon) r(ABC)^{1+\epsilon} \ . </math>
+
:<math> \left\vert A_{pq} \right\vert = \frac{1}{f(p)f(q)} X + R_{p,q} </math>
  
A weaker form of the conjecture states that
+
where ''X'' &nbsp; = &nbsp; |''A''| and ''f'' is a function with the property that 0 &le; ''f''(''d'') &le; 1.  Put
  
:<math> (|A| \cdot |B| \cdot |C|)^{1/3} < \kappa(\epsilon) r(ABC)^{1+\epsilon} \ . </math>
+
:<math> U(z) = \sum_{p \mid P(z)} f(p) . </math>
  
If we define
+
Then
  
:<math> \kappa(\epsilon) = \inf_{A+B+C=0,\ (A,B)=1} \frac{\max\{|A|,|B|,|C|\}}{N^{1+\epsilon}} \ , </math>
+
:<math> 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 . </math>
  
then it is known that <math>\kappa \rightarrow \infty</math> as <math>\epsilon \rightarrow 0</math>.
+
==Applications==
 +
* The [[Hardy–Ramanujan theorem]] that the [[normal order of an arithmetic function|normal order]] of &omega;(''n''), the number of distinct [[prime factor]]s of a number ''n'', is log(log(''n''));
 +
* Almost all integer polynomials (taken in order of height) are irreducible.
  
Baker introduced a more refined version of the conjecture in 1998. Assume as before that <math>A + B + C = 0</math> holds for coprime integers <math>A,B,C</math>.  Let <math>N</math> be the radical of <math>ABC</math> and <math>\omega</math> the number of distinct prime factors of <math>ABC</math>. Then there is an absolute constant <math>c</math> such that
+
==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 }}
 +
=Weierstrass preparation theorem=
 +
In [[algebra]], the '''Weierstrass preparation theorem''' describes a canonical form for [[formal power series]] over a [[complete local ring]].
  
:<math> |A|, |B|, |C| < c (\epsilon^{-\omega} N)^{1+\epsilon} \ . </math>
+
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
  
This form of the conjecture would give very strong bounds in the [[method of linear forms in logarithms]].
+
:<math>f = (X^n + b_{n-1}X^{n-1} + \cdots + b_0) u(x) , \,</math>
  
==Results==
+
where the ''b''<sub>''i''</sub> are in the maximal ideal ''m'' of ''O'' and ''u'' is a unit of ''O''[[''X'']].
It is known that there is an effectively computable <math>\kappa(\epsilon)</math> such that
 
  
:<math> |A|, |B|, |C| < \exp\left({ \kappa(\epsilon) N^{1/3} (\log N)^3 }\right) \ . </math>
+
The integer ''n'' defined by the theorem is the '''Weierstrass degree''' of ''f''.
  
 
==References==
 
==References==
* {{cite book | zbl=1046.11035 | last=Goldfeld | first=Dorian | authorlink=Dorian Goldfeld | chapter=Modular forms, elliptic curves and the abc-conjecture | editor=Wüstholz, Gisbert | title=A panorama in number theory or The view from Baker's garden. | location=Cambridge | publisher=Cambridge University Press | pages=128-147 | year=2002 | isbn=0-521-80799-9 }}
+
* {{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 }}
* {{cite book | last=Baker | first=Alan | authorlink=Alan Baker | chapter=Logarithmic forms and the $abc$-conjecture | pages=37-44 | editor=Győry, Kálmán (ed.) et al. | title=Number theory. Diophantine, computational and algebraic aspects. Proceedings of the international conference, Eger, Hungary, July 29-August 2, 1996 | location=Berlin | publisher=de Gruyter | year=1998 | isbn=3-11-015364-5 | zbl=0973.11047 }}
 
* {{cite journal | last=Stewart | first=C. L. | coauthors=Yu Kunrui | title=On the ''abc'' conjecture. II | journal=Duke Math. J. | volume=108 | number=1 | pages=169-181 | year=2001 | issn=0012-7094 | zbl=1036.11032 }}
 
  
=Szpiro's conjecture=
 
A conjectural relationship between the [[conductor of an elliptic curve|conductor]] and the [[discriminant of an elliptic curve|discriminant]] of an [[elliptic curve]].  In a general form, it is equivalent to the well-known [[ABC conjecture]].  It is named for [[Lucien Szpiro]] who formulated it in the 1980s.
 
  
The conjecture states that: given &epsilon; &gt; 0, there exists a constant ''C''(&epsilon;) such that for any elliptic curve ''E'' defined over '''Q''' with minimal discriminant &Delta; and conductor ''f'', we have
+
=Zipf distribution=
 +
In [[probability theory]] and [[statistics]], the '''Zipf distribution''' and '''zeta distribution''' refer to a class of [[discrete probability distribution]]s.  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.
  
:<math> \vert\Delta\vert \leq C(\varepsilon ) \cdot f^{6+\varepsilon }. \, </math>
+
The Zipf distribution with parameter ''n'' assigns probability proportional to 1/''r'' to an integer ''r'' &le; ''n'' and zero otherwise, with [[normalization]] factor ''H''<sub>''n''</sub>, the ''n''-th [[harmonic number]].
  
The '''modified Szpiro conjecture''' states that: given &epsilon; &gt; 0, there exists a constant ''C''(&epsilon;) such that for any elliptic curve ''E'' defined over '''Q''' with invariants ''c''<sub>4</sub>, ''c''<sub>6</sub> and conductor ''f'', we have
+
A Zipf-like distribution with parameters ''n'' and ''s'' assigns probability proportional to 1/''r''<sup>''s''</sup> to an integer ''r'' &le; ''n'' and zero otherwise, with normalization factor <math>\sum_{r=1}^n 1/r^s</math>.
  
:<math> \max\{\vert c_4\vert^3,\vert c_6\vert^2\} \leq C(\varepsilon )\cdot f^{6+\varepsilon }. \, </math>
+
The zeta distribution with parameter ''s'' assigns probability proportional to 1/''r''<sup>''s''</sup> to all integers ''r'' with normalization factor given by the [[Riemann zeta function]] 1/ζ(''s'').
  
 
==References==
 
==References==
 
+
* {{cite book | author=Michael Woodroofe | coauthors=Bruce Hill | title=On Zipf's law | journal=J. Appl. Probab. | volume=12 | pages=425-434 | year=1975 | id=Zbl 0343.60012 }}
* {{cite book | first=Serge | last=Lang | authorlink=Serge Lang | title=Survey of Diophantine geometry | publisher=[[Springer-Verlag]] | year=1997 | isbn=3-540-61223-8 | page=51 | zbl=0869.11051 | edition=Corrected 2nd printing }}
 
* {{cite journal | author=L. Szpiro | title=Seminaire sur les pinceaux des courbes de genre au moins deux | journal=Astérisque | volume=86 | issue=3 | year=1981 | pages=44-78 | zbl=0463.00009 }}
 
* {{cite journal | author=L. Szpiro | title=Présentation de la théorie d'Arakelov | journal=Contemp. Math. | volume=67 | year=1987 | pages=279-293 | zbl=0634.14012  }}
 

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 nx such that n is coprime to φ(n) is asymptotic to e 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

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 rn 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 rn 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

How to Cite This Entry:
Richard Pinch/sandbox-CZ. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Richard_Pinch/sandbox-CZ&oldid=30224