In mathematics, the Erdős–Turán inequality bounds the distance between a probability measure on the circle and the Lebesgue measure, in terms of Fourier coefficients. It was proved by Paul Erdős and Pál Turán in 1948.[1][2]
Let μ be a probability measure on the unit circle R/Z. The Erdős–Turán inequality states that, for any natural number n,
where the supremum is over all arcs A ⊂ R/Z of the unit circle, mes stands for the Lebesgue measure,
are the Fourier coefficients of μ, and C > 0 is a numerical constant.
Application to discrepancy
editLet s1, s2, s3 ... ∈ R be a sequence. The Erdős–Turán inequality applied to the measure
yields the following bound for the discrepancy:
This inequality holds for arbitrary natural numbers m,n, and gives a quantitative form of Weyl's criterion for equidistribution.
A multi-dimensional variant of (1) is known as the Erdős–Turán–Koksma inequality.
Notes
edit- ^ Erdős, P.; Turán, P. (1948). "On a problem in the theory of uniform distribution. I." (PDF). Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen. 51: 1146–1154. MR 0027895. Zbl 0031.25402.
- ^ Erdős, P.; Turán, P. (1948). "On a problem in the theory of uniform distribution. II" (PDF). Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen. 51: 1262–1269. MR 0027895. Zbl 0032.01601.
Additional references
edit- Harman, Glyn (1998). Metric Number Theory. London Mathematical Society Monographs. New Series. Vol. 18. Clarendon Press. ISBN 0-19-850083-1. Zbl 1081.11057.