Kneser’s theorem for upper Banach density

Bihani, Prerna, and Jin, Renling. "Kneser’s theorem for upper Banach density." Journal de Théorie des Nombres de Bordeaux 18.2 (2006): 323-343. <http://eudml.org/doc/249642>.

@article{Bihani2006,
abstract = {Suppose $A$ is a set of non-negative integers with upper Banach density $\alpha $ (see definition below) and the upper Banach density of $A+A$ is less than $2\alpha $. We characterize the structure of $A+A$ by showing the following: There is a positive integer $g$ and a set $W$, which is the union of $\lceil 2\alpha g-1\rceil $ arithmetic sequences [We call a set of the form $a+d\{\mathbb\{N\}\}$ an arithmetic sequence of difference $d$ and call a set of the form $\lbrace a, a+d, a+2d,\ldots ,a+kd\rbrace $ an arithmetic progression of difference $d$. So an arithmetic progression is finite and an arithmetic sequence is infinite.] with the same difference $g$ such that $A+A\subseteq W$ and if $[a_n,b_n]$ for each $n$ is an interval of integers such that $b_n-a_n\rightarrow \infty $ and the relative density of $A$ in $[a_n,b_n]$ approaches $\alpha $, then there is an interval $[c_n,d_n]\subseteq [a_n,b_n]$ for each $n$ such that $(d_n-c_n)/(b_n-a_n)\rightarrow 1$ and $(A+A)\cap [2c_n,2d_n]=W\cap [2c_n,2d_n]$.},
affiliation = {Department of Mathematics University of Notre Dame Notre Dame, IN 46556, U.S.A.; Department of Mathematics College of Charleston Charleston, SC 29424, U.S.A.},
author = {Bihani, Prerna, Jin, Renling},
journal = {Journal de Théorie des Nombres de Bordeaux},
keywords = {Upper Banach density; inverse problem; nonstandard analysis; upper Banach density},
language = {eng},
number = {2},
pages = {323-343},
publisher = {Université Bordeaux 1},
title = {Kneser’s theorem for upper Banach density},
url = {http://eudml.org/doc/249642},
volume = {18},
year = {2006},
}

TY - JOUR
AU - Bihani, Prerna
AU - Jin, Renling
TI - Kneser’s theorem for upper Banach density
JO - Journal de Théorie des Nombres de Bordeaux
PY - 2006
PB - Université Bordeaux 1
VL - 18
IS - 2
SP - 323
EP - 343
AB - Suppose $A$ is a set of non-negative integers with upper Banach density $\alpha $ (see definition below) and the upper Banach density of $A+A$ is less than $2\alpha $. We characterize the structure of $A+A$ by showing the following: There is a positive integer $g$ and a set $W$, which is the union of $\lceil 2\alpha g-1\rceil $ arithmetic sequences [We call a set of the form $a+d{\mathbb{N}}$ an arithmetic sequence of difference $d$ and call a set of the form $\lbrace a, a+d, a+2d,\ldots ,a+kd\rbrace $ an arithmetic progression of difference $d$. So an arithmetic progression is finite and an arithmetic sequence is infinite.] with the same difference $g$ such that $A+A\subseteq W$ and if $[a_n,b_n]$ for each $n$ is an interval of integers such that $b_n-a_n\rightarrow \infty $ and the relative density of $A$ in $[a_n,b_n]$ approaches $\alpha $, then there is an interval $[c_n,d_n]\subseteq [a_n,b_n]$ for each $n$ such that $(d_n-c_n)/(b_n-a_n)\rightarrow 1$ and $(A+A)\cap [2c_n,2d_n]=W\cap [2c_n,2d_n]$.
LA - eng
KW - Upper Banach density; inverse problem; nonstandard analysis; upper Banach density
UR - http://eudml.org/doc/249642
ER -