Difference between revisions of "User:Richard Pinch/sandbox-CZ"
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| + | =Tau function= | ||
| + | In [[mathematics]], Ramanujan's '''tau function''' is an [[arithmetic function]] which may defined in terms of the [[Delta form]] by the formal infinite product | ||
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| + | :<math>q \prod_{n=1}^\infty \left(1-q^n\right)^{24} = \sum_n \tau(n) q^n .\,</math> | ||
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| + | Since Δ is a [[Hecke operator|Hecke]] [[eigenform]], the tau function is multiplicative, with [[formal Dirichlet series]] and Euler product | ||
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| + | :<math> \sum_n \tau(n) n^{-s} = \prod_p \left(1 - \tau(p) p^{-s} + p^{11-2s} \right)^{-1} .\,</math> | ||
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=Turan sieve= | =Turan sieve= | ||
Revision as of 06:51, 8 September 2013
Tau function
In mathematics, Ramanujan's tau function is an arithmetic function which may defined in terms of the Delta form by the formal infinite product
\[q \prod_{n=1}^\infty \left(1-q^n\right)^{24} = \sum_n \tau(n) q^n .\,\]
Since Δ is a Hecke eigenform, the tau function is multiplicative, with formal Dirichlet series and Euler product
\[ \sum_n \tau(n) n^{-s} = \prod_p \left(1 - \tau(p) p^{-s} + p^{11-2s} \right)^{-1} .\,\]
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
Tutte matrix
In graph theory, the Tutte matrix \(A\) of a graph G = (V,E) is a matrix used to determine the existence of a perfect matching: that is, a set of edges which is incident with each vertex exactly once.
If the set of vertices V has 2n elements then the Tutte matrix is a 2n × 2n matrix A with entries
- \[A_{ij} = \begin{cases} x_{ij}\;\;\mbox{if}\;(i,j) \in E \mbox{ and } i<j\\ -x_{ji}\;\;\mbox{if}\;(i,j) \in E \mbox{ and } i>j\\ 0\;\;\;\;\mbox{otherwise} \end{cases}\]
where the xij are indeterminates. The determinant of this skew-symmetric matrix is then a polynomial (in the variables xij, i<j ): this coincides with the square of the pfaffian of the matrix A and is non-zero (as a polynomial) if and only if a perfect matching exists. (It should be noted that this is not the Tutte polynomial of G.)
The Tutte matrix is a generalisation of the Edmonds matrix for a balanced bipartite graph.
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
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=30418