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Sharp bounds for a discrete John’s theorem

Published online by Cambridge University Press:  05 March 2024

Peter van Hintum*
Affiliation:
New College, University of Oxford, Oxford, UK
Peter Keevash
Affiliation:
Mathematical Institute, University of Oxford, Oxford, UK
*
Corresponding author: Peter van Hintum; Email: peter.vanhintum@new.ox.ac.uk
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Abstract

Tao and Vu showed that every centrally symmetric convex progression $C\subset \mathbb{Z}^d$ is contained in a generalized arithmetic progression of size $d^{O(d^2)} \# C$. Berg and Henk improved the size bound to $d^{O(d\log d)} \# C$. We obtain the bound $d^{O(d)} \# C$, which is sharp up to the implied constant and is of the same form as the bound in the continuous setting given by John’s theorem.

Type
Paper
Copyright
© The Author(s), 2024. Published by Cambridge University Press

1. Introduction

A classical theorem of John [Reference John2] shows that for any centrally symmetric convex set $K\subset \mathbb{R}^d$ , there exists an ellipsoid $E$ centred at the origin so that $E\subset K\subset \sqrt{d}E$ . This immediately implies that there exists a parallelotope $P$ so that $P\subset E\subset K\subset \sqrt{d}E\subset dP$ . In the discrete setting, quantitative covering results are of great interest in Additive Combinatorics, a prominent example being the Polynomial Freiman–Ruzsa Conjecture, which asks for effective bounds on covering sets of small doubling by convex progressions. In this context, a natural analogue of John’s theorem in $\mathbb{Z}^d$ would be covering centrally symmetric convex progressions by generalised arithmetic progressions. Here, a $d$ -dimensional convex progression is a set of the form $K\cap \mathbb{Z}^d$ , where $K\subset \mathbb{R}^d$ is convex and a $d$ -dimensional generalised arithmetic progression ( $d$ -GAP) is a translate of a set of the form $\left \{\sum _{i=1}^d m_ia_i\,:\, 1\leq m_i\leq n_i\right \}$ for some $n_i\in \mathbb{N}$ and $a_i\in \mathbb{Z}^d$ .

Tao and Vu [Reference Tao and Vu4, Reference Tao and Van5] obtained such a discrete version of John’s theorem, showing that for any origin-symmetric $d$ -dimensional convex progression $C\subset \mathbb{Z}^d$ there exists a $d$ -GAP $P$ so that $P\subset C\subset O(d)^{3d/2}\cdot P$ , where $m\cdot P\,:\!=\,\left \{\sum _{i=1}^m p_i\,:\, p_i\in P\right \}$ denotes the iterated sumset. Berg and Henk [Reference Berg and Henk1] improved this to $P\subset C\subset d^{O(\log (d))}\cdot P$ . Our focus will be on the covering aspect of these results, that is, minimising the ratio $\# P^{\prime}/ \# C$ , where $P^{\prime}$ is a $d$ -GAP covering $C$ . This ratio is bounded by $d^{O(d^2)}$ by Tao and Vu and by $d^{O(d\log d)}$ by Berg and Henk. We obtain the bound $d^{O(d)}$ , which is optimal.

Theorem 1.1. For any origin-symmetric convex progression $C\subset \mathbb{Z}^d$ , there exists a $d$ -GAP $P$ containing $C$ with $\# P\leq O(d)^{3d} \# C$ .

Corollary 1.2. For any origin-symmetric convex progression $C\subset \mathbb{Z}^d$ and linear map $\phi \,:\,\mathbb{R}^d\to \mathbb{R}$ , there exists a $d$ -GAP $P$ containing $C$ with $\# \phi (P)\leq O(d)^{3d} \# \phi (C)$ .

The optimality of Theorem 1.1 is demonstrated by the intersection of a ball $B$ with a lattice $L$ . Moreover, Lovett and Regev [Reference Lovett and Regev3] obtained a more emphatic negative result, disproving the GAP analogue of the Polynomial Freiman–Ruzsa Conjecture, by showing that by considering a random lattice $L$ one can find a convex $d$ -progression $C = B \cap L$ such that any $O(d)$ -GAP $P$ with $\# P \le \# C$ has $\# (P \cap C) \lt d^{-\Omega (d)} \# C$ . Our result can be viewed as the positive counterpart that settles this line of enquiry, showing that indeed $d^{\Theta (d)}$ is the optimal ratio for covering convex progressions by GAPs.

2. Proof

We start by recording two simple observations and a proposition on a particular basis of a lattice, known as the Mahler Lattice Basis.

Observation 2.1. Given an origin-symmetric convex set $K\subset \mathbb{R}^d$ , there exists a origin-symmetric parallelotope $Q$ and an origin-symmetric ellipsoid $E$ so that $\frac 1d Q\subset E\subset K\subset \sqrt{d}E\subset Q$ , so in particular $|Q|\leq d^{d}|K|$ .

This is a simple consequence of John’s theorem.

Observation 2.2. Let $X,X^{\prime}\in \mathbb{R}^{d\times d}$ be so that the rows of $X$ and $X^{\prime}$ generate the same lattice of full rank in $\mathbb{R}^d$ . Then $\exists T\in GL_n(\mathbb{Z})$ so that $TX=X^{\prime}$ .

This can be seen by considering the Smith Normal Form of the matrices $X$ and $X^{\prime}$ .

Proposition 2.3 (Corollary 3.35 from [Reference Tao and Vu4]). Given a lattice $\Lambda \subset \mathbb{R}^d$ of full rank, there exists a lattice basis $v_1,\dots, v_d$ of $\Lambda$ so that $\prod _{i=1}^{d} \|v_i\|_2 \leq O(d^{3d/2})\det\! (v_1,\dots, v_d)$ .

With these three results in mind, we prove the theorem.

Proof of Theorem 1.1. By passing to a subspace if necessary, we may assume that $C$ is full-dimensional. Write $C = K \cap \mathbb{Z}^d$ where $K\subset \mathbb{R}^d$ is origin-symmetric and convex. Use Observation 2.1 to find a parallelotope $Q\supset K$ so that $|Q|\leq d^d |K|$ . Let the defining vectors of $Q$ be $u_1,\dots,u_d$ , that is, $Q=\big\{\!\sum_i \lambda _i u_i\,:\, \lambda _i\in [{-}1,1]\big\}$ . Write $u_i^j$ for the $j$ -th coordinate of $u_i$ and write $U$ for the matrix $\big(u_i^j\big)$ with rows $u^j$ and columns $u_i$ .

Consider the lattice $\Lambda$ generated by the vectors $u^j$ (these are the vectors formed by the $j$ -th coordinates of the vectors $u_i$ ). Using Proposition 2.3 find a basis $v^1,\dots,v^d$ of $\Lambda$ so that $\prod _{j=1}^{d} ||v^j||_2\leq O\big(d^{3d/2}\big)\det\! \big(v^1,\dots, v^d\big)$ . Write $v^j_i$ for the $i$ -th coordinate of $v^j$ and write $V\,:\!=\,\big(v_i^j\big)$ . By Observation 2.2, we can find $T\in GL_n(\mathbb{Z})$ so that $TU=V$ , so that $T u_i = v_i$ for $1 \le i \le d$ and $T(\mathbb{Z}^d)=\mathbb{Z}^d$ .

Write $Q^{\prime}\,:\!=\,T(Q)=\big\{\!\sum_i \lambda _i v_i\,:\, \lambda _i\in [{-}1,1]\big\}$ and consider the smallest axis aligned box $B\,:\!=\,\prod_{i} [{-}a_i,a_i]$ containing $Q^{\prime}$ . Note that $a_j\leq \sum _{i} |v_i^j|=||v^{j}||_1\leq \sqrt{d}||v^{j}||_2$ . Hence, we find

\begin{align*} |B|&=2^d\prod _{i=1}^d a_i\leq 2^d\prod _{j=1}^d \sqrt{d}||v^j||_2\leq O(d)^{2d} \det\! \big(v^1,\dots,v^d\big)= O(d)^{2d} \det\! (v_1,\dots,v_d)=O(d)^{2d} |Q^{\prime}|. \end{align*}

Now we cover $C$ by a $d$ -GAP $P$ , constructed by the following sequence:

\begin{equation*}C=K\cap \mathbb {Z}^d\subset Q\cap \mathbb {Z}^d= T^{-1}(Q^{\prime})\cap \mathbb {Z}^d \subset T^{-1}(B)\cap \mathbb {Z}^d = T^{-1}\big(B\cap \mathbb {Z}^d\big) \,=\!:\, P.\end{equation*}

It remains to bound $\# P$ . As $C$ is full-dimensional each $a_i \ge 1$ , so

\begin{align*} \# P&=\# \big(B \cap \mathbb{Z}^d\big) \leq 2^d |B|\leq O(d)^{2d} |Q^{\prime}|= O(d)^{2d} |Q| \leq O(d)^{3d} |K|\leq O(d)^{3d} \# C, \end{align*}

where the last inequality follows from Minkowski’s First Theorem (see for instance equation (3.14) in [Reference Tao and Vu4]).

Proof of Corollary 1.2. Let $m\,:\!=\,\max _{x\in \mathbb{Z}}\#(\phi ^{-1}(x)\cap C)$ and note that $\# \phi (C)\geq \# C/ m$ . Analogously, let $m^{\prime}\,:\!=\,\max _{x\in \mathbb{Z}}\#(\phi ^{-1}(x)\cap P)$ so that $m^{\prime}\geq m$ . By translation, we may assume that $m^{\prime}$ is achieved at $x=0$ . Note that for any $x = \phi (p)$ with $p \in P$ and $p^{\prime} \in P \cap \phi ^{-1}(0)$ we have $p+p^{\prime} \in P+P$ with $\phi (p+p^{\prime})=x$ , so $\#\big(\phi ^{-1}(x)\cap (P+P)\big)\geq m^{\prime}$ . We conclude that

\begin{align*} \# \phi (P) &\leq \# (P+P)/m^{\prime}\leq 2^d \# P/m\leq O(d)^{3d}\# C/m\leq O(d)^{3d}\# \phi (C). \end{align*}

References

Berg, S. L. and Henk, M. (2019) Discrete analogues of John’s theorem. Moscow J. Comb. Number Theory 8(4) 367378.CrossRefGoogle Scholar
John, F. (1948) Extremum problems with inequalities as subsidiary conditions. In Studies and Essays, Presented to R. Courant on his 60th Birthday,. New York: Interscience, pp. 187204.Google Scholar
Lovett, S. and Regev, O. (2017) A counterexample to a strong variant of the Polynomial Freiman-Ruzsa Conjecture in Euclidean space. Discrete Anal. 8 379388.Google Scholar
Tao, T. and Vu, V. (2006) Additive Combinatorics. Cambridge University Press, Vol. 105.CrossRefGoogle Scholar
Tao, T. and Van, V. (2008) John-type theorems for generalized arithmetic progressions and iterated sumsets. Adv. Math. 219(2) 428449.CrossRefGoogle Scholar