Larger sieve

In number theory, the larger sieve is a sieve invented by Patrick X. Gallagher. The name denotes a heightening of the large sieve. Combinatorial sieves like the Selberg sieve are strongest, when only a few residue classes are removed, while the term large sieve means that this sieve can take advantage of the removal of a large number of up to half of all residue classes. The larger sieve can exploit the deletion of an arbitrary number of classes.

Statement edit

Suppose that ${\mathcal {S}}$ is a set of prime powers, N an integer, ${\mathcal {A}}$ a set of integers in the interval [1, N], such that for $q\in {\mathcal {S}}$ there are at most $g(q)$ residue classes modulo $q$ , which contain elements of ${\mathcal {A}}$ .

Then we have

|{\mathcal {A}}|\leq {\frac {\sum _{q\in {\mathcal {S}}}\Lambda (q)-\log N}{\sum _{q\in {\mathcal {S}}}{\frac {\Lambda (q)}{g(q)}}-\log N}},

provided the denominator on the right is positive.^[1]

Applications edit

A typical application is the following result, for which the large sieve fails (specifically for $\theta >{\frac {1}{2}}$ ), due to Gallagher:^[2]

The number of integers  $n\leq N$ , such that the order of  $n$  modulo  $p$  is  $\leq N^{\theta }$  for all primes  $p\leq N^{\theta +\epsilon }$  is  ${\mathcal {O}}(N^{\theta })$ .

If the number of excluded residue classes modulo $p$ varies with $p$ , then the larger sieve is often combined with the large sieve. The larger sieve is applied with the set ${\mathcal {S}}$ above defined to be the set of primes for which many residue classes are removed, while the large sieve is used to obtain information using the primes outside ${\mathcal {S}}$ .^[3]

Notes edit

^ Gallagher 1971, Theorem 1
^ Gallagher, 1971, Theorem 2
^ Croot, Elsholtz, 2004

References edit

Gallagher, Patrick (1971). "A larger sieve". Acta Arithmetica. 18: 77–81. doi:10.4064/aa-18-1-77-81.
Croot, Ernie; Elsholtz, Christian (2004). "On variants of the larger sieve". Acta Mathematica Hungarica. 103 (3): 243–254. doi:10.1023/B:AMHU.0000028411.04500.e2.

[1] Gallagher 1971, Theorem 1

[2] Gallagher, 1971, Theorem 2

[3] Croot, Elsholtz, 2004

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