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Subspace coverings with multiplicities

Published online by Cambridge University Press:  18 May 2023

Anurag Bishnoi
Affiliation:
Delft Institute of Applied Mathematics, Technische Universiteit Delft, Delft, 2628 CD, Netherlands
Simona Boyadzhiyska
Affiliation:
School of Mathematics, University of Birmingham, Edgbaston, Birmingham, B15 2TT, UK
Shagnik Das*
Affiliation:
Department of Mathematics, National Taiwan University, Taipei, 10617, Taiwan
Tamás Mészáros
Affiliation:
Institut für Mathematik, Freie Universität Berlin, 14195 Berlin, Germany
*
Corresponding author: Shagnik Das; Email: shagnik@ntu.edu.tw
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Abstract

We study the problem of determining the minimum number $f(n,k,d)$ of affine subspaces of codimension $d$ that are required to cover all points of $\mathbb{F}_2^n\setminus \{\vec{0}\}$ at least $k$ times while covering the origin at most $k - 1$ times. The case $k=1$ is a classic result of Jamison, which was independently obtained by Brouwer and Schrijver for $d = 1$. The value of $f(n,1,1)$ also follows from a well-known theorem of Alon and Füredi about coverings of finite grids in affine spaces over arbitrary fields. Here we determine the value of this function exactly in various ranges of the parameters. In particular, we prove that for $k\geq 2^{n-d-1}$ we have $f(n,k,d)=2^d k-\left\lfloor{\frac{k}{2^{n-d}}}\right\rfloor$, while for $n \gt 2^{2^d k-k-d+1}$ we have $f(n,k,d)=n + 2^d k -d-2$, and obtain asymptotic results between these two ranges. While previous work in this direction has primarily employed the polynomial method, we prove our results through more direct combinatorial and probabilistic arguments, and also exploit a connection to coding theory.

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Paper
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Copyright
© The Author(s), 2023. Published by Cambridge University Press

1. Introduction

How many affine hyperplanes does it take to cover the vertices of the $n$ -dimensional Boolean hypercube, $\{0,1\}^n$ ? This simple question has an equally straightforward answer—one can cover all the vertices with a parallel pair of hyperplanes, while it is easy to see that a single plane can cover at most half the vertices, and so two planes are indeed necessary. However, the waters are quickly muddied with a minor twist to the problem.

Indeed, if one is instead asked to cover all the vertices except the origin, the parallel hyperplane construction is no longer valid. Given a moment’s thought, one might come up with the much larger family of $n$ hyperplanes given by $\{ \vec{x} \;:\; x_i = 1 \}$ for $i \in [n]$ . This fulfils the task and, surprisingly, turns out to be optimal [Reference Alon and Füredi1], although this is far from obvious. This problem has led to rich veins of research in both finite geometry and extremal combinatorics, and in what follows we survey its history before introducing our new results.

1.1. An origin story

When we work over the finite field $\mathbb{F}_{2}^{}$ , this problem is equivalent to the well-known blocking set problem from finite geometry, and it was in this guise that it was first studied. A blocking set in $\mathbb{F}_{2}^{n}$ is a set of points that meets every hyperplane, and the objective is to find a blocking set of minimum size. By translating, we may assume that our blocking set contains the origin $\vec{0}$ , and so the problem reduces to finding a collection of points that meets all hyperplanes avoiding the origin. Applying duality, we return to our original problem of covering the nonzero points of $\mathbb{F}_{2}^{n}$ with affine hyperplanes.

There is no reason to restrict our attention to the binary field $\mathbb{F}_{2}^{}$ , and we can generalise the problem to ask how many hyperplanes are needed to cover the nonzero points of $\mathbb{F}_{q}^{n}$ . Going even further, one may replace the hyperplanes with affine subspaces of codimension $d$ . In this generality, the problem was answered in the late 1970s by Jamison [Reference Jamison16], who proved that the minimum number of affine subspaces of codimension $d$ that cover all nonzero points in $\mathbb{F}_{q}^{n}$ while avoiding the origin is $q^d - 1 + (n-d)(q-1)$ . In particular, when $q = 2$ and $d=1$ , this lower bound is equal to $n$ , showing that the earlier construction with $n$ planes is optimal. A simpler proof of the case $d=1$ was independently provided by Brouwer and Schrijver [Reference Brouwer and Schrijver7].

While the finite geometry motivation naturally leads one to work over finite fields, one can also study the problem over infinite fields $\mathbb{F}_{}^{}$ . Of course, one would need infinitely many hyperplanes to cover all nonzero points of $\mathbb{F}_{}^{n}$ , which is why we instead ask how many hyperplanes are needed to cover the nonzero points of the hypercube $\{0,1\}^n \subseteq{\mathbb{F}_{}^{n}}$ . This problem was raised in the early 1990s by Komjáth [Reference Komjáth18], who, in order to prove some results in infinite Ramsey theory, showed that this quantity must grow with $n$ . Shortly afterwards, a celebrated result of Alon and Füredi [Reference Alon and Füredi1] established a tight bound in the more general setting of covering all but one point of a finite grid. They showed that, for any collection of finite subsets $S_1, S_2, \ldots, S_n$ of some arbitrary field $\mathbb{F}_{}^{}$ , the minimum number of hyperplanes needed to cover all but one point of $S_1 \times S_2 \times \ldots \times S_n$ is $\sum _i ( |{S_i}| - 1 )$ . If we take $S_i = \{0,1\}$ for all $i$ , this once again shows that one needs $n$ hyperplanes to cover the nonzero points of the hypercube.

1.2. The polynomial method

Despite these motivating applications to finite geometry and Ramsey theory, the primary reason this problem has attracted so much attention lies in the proof methods used. These hyperplane covers have driven the development of the polynomial method—indeed, in light of his early results, this is sometimes referred to as the Jamison method in finite geometry [Reference Bruen and Fisher9].

To see how polynomials come into play, suppose we have a set of hyperplanes $\{H_i \;:\; i \in [m] \}$ in $\mathbb{F}_{}^{n}$ , with the plane $H_i$ defined by $H_i = \{ \vec{x} \;:\; \vec{x} \cdot \vec{a}_i = c_i \}$ for some normal vector $\vec{a}_i \in{\mathbb{F}_{}^{n}}$ and some constant $c_i \in{\mathbb{F}_{}^{}}$ . We can then define the degree- $m$ polynomial $f(\vec{x}) = \prod _{i \in m} ( \vec{x} \cdot \vec{a}_i - c_i )$ , observing that $f(\vec{x}) = 0$ if and only if $\vec{x}$ is covered by one of the hyperplanes $H_i$ . Thus, lower bounds on the degrees of polynomials that vanish except at the origin translate to lower bounds on the number of hyperplanes needed to cover all nonzero points.

This approach has proven very robust, and lends itself to a number of generalisations. For instance, Kós, Mészáros and Rónyai [Reference Kós, Mészáros and Rónyai20] and Bishnoi, Clark, Potukuchi and Schmitt [Reference Bishnoi, Clark, Potukuchi and Schmitt5] considered variations over rings, while Blokhuis, Brouwer and Szőnyi [Reference Blokhuis, Brouwer and Szőnyi6] studied the problem for quadratic surfaces and Hermitian varieties in projective and affine spaces over $\mathbb{F}_{q}^{}$ .

1.3. Covering with multiplicity

In this paper, we shall remain in the original setting, but instead extend the problem to higher multiplicities. That is, we shall seek the minimum number of hyperplanes in $\mathbb{F}_{}^{n}$ needed to cover the nonzero points at least $k$ times, while covering the origin fewer times. Previous work in this direction has imposed the stricter condition of avoiding the origin altogether; Bruen [Reference Bruen8] considered this problem over finite fields, while Ball and Serra [Reference Ball and Serra4] and Kós and Rónyai [Reference Kós and Rónyai19] worked with finite grids over arbitrary fields, with some further generalisations recently provided by Geil and Matrínez-Penas [Reference Geil and Matrínez-Peñas12]. In all of these papers, the polynomial method described above was strengthened to obtain lower bounds for this problem with higher multiplicities. However, these lower bounds are most often not tight; Zanella [Reference Zanella26] discusses when Bruen’s bound is sharp, with some improvements provided by Ball [Reference Ball2].

Significant progress in this line of research was made recently when Clifton and Huang [Reference Clifton and Huang10] studied the special case of covering all nonzero points of $\{0,1\}^n \subseteq \mathbb{R}^n$ at least $k$ times, while leaving the origin uncovered. Observe that one can remove $k-1$ hyperplanes arbitrarily from such a cover, and the remainder will still cover each nonzero point at least once. Thus, by the Alon–Füredi theorem, we must be left with at least $n$ planes, giving a lower bound of $n+k-1$ . While it is not hard to see that this is tight for $k=2$ , Clifton and Huang used Ball and Serra’s Punctured Combinatorial Nullstellensatz [Reference Ball and Serra4] to improve the lower bound for larger $k$ . They showed that for $k = 3$ and $n \ge 2$ , the correct answer is $n + 3$ , while for $k \ge 4$ and $n \ge 3$ , the answer lies between $n + k + 1$ and $n + \binom{k}{2}$ ; additionally, they conjectured the upper bound to be correct when $n$ is large with respect to $k$ . However, they showed that this was far from the case when $n$ is fixed and $k$ is large; in this range, the answer is $(c_n + o(1))k$ , where $c_n$ is the $n$ th term in the harmonic series.

A major breakthrough was then made by Sauermann and Wigderson [Reference Sauermann and Wigderson24], who skipped the geometric motivation and resolved the polynomial problem directly. More precisely, they proved the following theorem.

Theorem 1.1. Let $k \ge 2$ and $n \ge 2k-3$ , and let $P \in \mathbb{R}[x_1, \ldots, x_n]$ be a polynomial having zeroes of multiplicity at least $k$ at all points in $\{0,1\}^n \setminus \{ \vec{0} \}$ , and such that $P$ does not have a zero of multiplicity at least $k-1$ at $\vec{0}$ . Then $P$ must have degree at least $n + 2k - 3$ . Furthermore, for every $\ell \in \{0, 1, \ldots, k-2\}$ , there exists a polynomial $P$ with degree exactly $n + 2k - 3$ having zeroes of multiplicity at least $k$ at all points in $\{0,1\}^n \setminus \{ \vec{0} \}$ , and such that $P$ has a zero of multiplicity exactly $\ell$ at $\vec{0}$ .

As an immediate corollary, this improves the lower bound in the Clifton–Huang result from $n+k+1$ to $n+2k-3$ . However, Theorem 1.1 establishes that $n+2k-3$ is also an upper bound for the polynomial problem, whereas Clifton and Huang conjecture that the answer for their problem should be $n + \binom{k}{2}$ . An affirmative answer to this conjecture would thus demonstrate separation between the algebraic polynomial problem and the geometric covering problem.

Even though Theorem 1.1 is stated for polynomials defined over $\mathbb{R}$ , Sauermann and Wigderson note that the proof works over any field of characteristic zero. However, the result need not hold over finite fields. In particular, they show the existence of a polynomial $P_4$ over $\mathbb{F}_{2}^{}$ of degree $n + 4$ with zeroes of multiplicity four at all nonzero points in $\mathbb{F}_{2}^{n}$ and with $P_4(\vec{0}) \neq 0$ . More generally, for every $k \ge 4$ , $P_k(\vec{x}) = x_1^{k-4} (x_1 - 1)^{k-4} P_4(\vec{x})$ is a binary polynomial of degree only $n + 2k - 4$ with zeroes of multiplicity $k$ at all nonzero points and of multiplicity $k-4$ at the origin. The correct behaviour of the problem over finite fields is left as an open problem.

Note also that Theorem 1.1 allows the origin to be covered up to $k-2$ times. Sauermann and Wigderson also considered the case where the origin must be covered with multiplicity exactly $k-1$ , showing that the minimum degree then increases to $n+2k-2$ . In contrast to Theorem 1.1, the proof of this result is valid over all fields.

1.4. Our results

In this paper, we study the problem of covering with multiplicity in $\mathbb{F}_{2}^{n}$ . We are motivated not only by the body of research described above, but also by the fact that, as we shall show in Proposition 3.3, when one forbids the origin from being covered, this problem is equivalent to finding linear binary codes of large minimum distance. As this classic problem from coding theory has a long and storied history of its own, and is likely to be very difficult, we shall instead work in the setting where we require all nonzero points in $\mathbb{F}_{2}^{n}$ to be covered at least $k$ times while the origin can be covered at most $k-1$ times.

In light of the previous results, we shall abstain from employing the polynomial method, and instead attack the problem more directly with combinatorial techniques. As an added bonus, our arguments readily generalise to covering points with codimension- $d$ affine subspaces, rather than just hyperplanes, thereby extending Jamison’s original results in the case $q=2$ . To be able to discuss our results more concisely, we first introduce some notation that we will use throughout the paper.

Given integers $k \ge 1$ and $n \ge d \ge 1$ , we say a multiset $\mathcal{H}$ of $(n-d)$ -dimensional affine subspaces in $\mathbb{F}_{2}^{n}$ is a $(k,d)$ -cover if every nonzero point of $\mathbb{F}_{2}^{n}$ is covered at least $k$ times, while $\vec{0}$ is covered at most $k-1$ times. We then define the corresponding extremal function $f(n,k,d)$ to be the minimum possible size of a $(k,d)$ -cover in $\mathbb{F}_{2}^{n}$ .

For instance, when we take $k = 1$ , we obtain the original covering problem, and from the work of Jamison [Reference Jamison16] we know $f(n,1,d) = n + 2^d - d - 1$ . At another extreme, if we take $d = n$ , then our affine subspaces are simply individual points, each of which must be covered $k$ times, and hence $f(n,k,n) = k ( 2^n - 1 )$ . We study this function for intermediate values of the parameters, determining it precisely when either $k$ is large with respect to $n$ and $d$ , or $n$ is large with respect to $k$ and $d$ , and deriving asymptotic results otherwise.

Theorem 1.2. Let $k \ge 1$ and $n \ge d \ge 1$ . Then:

  1. (a) If $k \ge 2^{n-d-1}$ , then $f(n,k,d) = 2^d k - \left \lfloor{ \frac{k}{2^{n-d}} }\right\rfloor$ .

  2. (b) If $k\geq 2$ and $n \gt 2^{2^d k - d - k + 1}$ , then $f(n,k,d) = n + 2^d k - d - 2$ .

  3. (c) If $k \ge 2$ and $n \ge \lfloor{\log _2 k}\rfloor + d + 1$ , then $n + 2^d k - d - \log _2\!(2k) \le f(n,k,d) \le n + 2^d k - d - 2$ .

There are a few remarks worth making at this stage. First, observe that, just as in the Clifton–Huang setting, the extremal function $f(n,k,d)$ exhibits different behaviour when $n$ is fixed and $k$ is large as compared to when $k$ is fixed and $n$ is large. Second, and perhaps most significantly, Theorem 1.2 demonstrates the gap between the hyperplane covering problem and the polynomial degree problem: our result shows that, for any $k\geq 4$ and sufficiently large $n$ , we have $f(n,k,1) = n + 2k - 3$ , whereas the answer to the corresponding polynomial problem is at most $n + 2k - 4$ , as explained after Theorem 1.1. Our ideas allow us to establish an even stronger separation in the case $k = 4$ —while the polynomial $P_4$ constructed by Sauermann and Wigderson, which has zeroes of multiplicity at least four at all nonzero points of $\mathbb{F}_{2}^{n}$ while not vanishing at the origin, has degree only $n + 4$ , we shall show in Corollary 3.5 that any hyperplane system with the corresponding covering properties must have size at least $n + \log _2 \left ( \tfrac 23 n \right )$ . Third, we see that in the intermediate range, when both $n$ and $k$ grow moderately, the bounds in (c) determine $f(n,k,d)$ up to an additive error of $\log _2\!(2k)$ , which is a lower-order term. Thus, $f(n,k,d)$ grows asymptotically like $n + 2^d k$ . Last of all, if one substitutes $k = 2^{n-d-1} - 1$ , the lower bound from (c) is larger than the value in (a). This shows that $k \ge 2^{n-d-1}$ is indeed the correct range for which the result in (a) is valid. In contrast, we believe the bound on $n$ in (b) is far from optimal, and discuss this in greater depth in the concluding remarks.

The remainder of this paper is devoted to the proof of Theorem 1.2, and is organised as follows. In Section 2 we prove part (a), determining the extremal function for large multiplicities. We prove part (b) in Section 3, handling the case when the dimension of the ambient space grows quickly. A key step in the proof is showing the intuitive, yet surprisingly not immediate, fact that $f(n,k,d)$ is strictly increasing in $n$ , as a result of which we shall also be able to deduce the bounds in (c). We end by presenting some concluding remarks and open problems in Section 4.

2. Covering with large multiplicity

In this section we prove Theorem 1.2(a), handling the case of large multiplicities. We begin by introducing some definitions and notation that we will use in the proof. To start with, it will be convenient to have some notation for affine hyperplanes. Given a nonzero vector $\vec{u}\in{\mathbb{F}_{2}^{n}}$ , let $H_{\vec{u}}$ denote the hyperplane $\{ \vec{x} \;:\; \vec{x} \cdot \vec{u} = 1 \}$ .

Next, it will sometimes be helpful to specify how many times the origin is covered. Hence, given integers $n \ge d \ge 1$ and $k \gt s \ge 0$ , we call a $(k,d)$ -cover in $\mathbb{F}_{2}^{n}$ a $(k,d;\;s)$ -cover if it covers the origin exactly $s$ times. Let us write $g(n,k,d;\;s)$ for the minimum possible size of a $(k,d;\;s)$ -cover in $\mathbb{F}_{2}^{n}$ and call a cover optimal if it has this minimum size. Clearly, we have $f(n,k,d)=\min _{0\leq s\lt k} g(n,k,d;\;s)$ , so any knowledge about this more refined function directly translates to our main focus of interest.

2.1. The lower bound

To start with, we prove a general lower bound, valid for all choices of parameters, that follows from a simple double-counting argument. This establishes the lower bound of Theorem 1.2(a).

Lemma 2.1. Let $n,k,d,s$ be integers such that $n \ge d \ge 1$ and $k \gt s \ge 0$ . Then

\begin{equation*} g(n,k,d;\;s) \geq 2^d k - \left \lfloor \frac {k-s}{2^{n-d}}\right \rfloor . \end{equation*}

In particular, $f(n,k,d) \ge 2^d k - \left\lfloor{\frac{k}{2^{n-d}}}\right\rfloor$ .

Proof. Let $\mathcal{H}$ be an optimal $(k,d;\;s)$ -cover of $\mathbb{F}_{2}^{n}$ , so that we have $g(n,k,d;\;s) = |{\mathcal{H}}|$ . We double-count the pairs $(\vec{x}, S)$ with $\vec{x} \in{\mathbb{F}_{2}^{n}}$ , $S \in \mathcal{H}$ , and $\vec{x} \in S$ . On the one hand, every affine subspace $S \in \mathcal{H}$ contains $2^{n-d}$ points, and so there are $2^{n-d} |{\mathcal{H}}|$ such pairs. On the other hand, since every nonzero point is covered at least $k$ times and the origin is covered $s$ times, there are at least $(2^n - 1)k+s$ such pairs. Thus $(2^n - 1 )k + s \le 2^{n-d} |{\mathcal{H}}|$ , and the claimed lower bound follows from solving for $|{\mathcal{H}}|$ and observing that $g(n,k,d;\;s)$ is an integer. The bound on $f(n,k,d)$ is obtained by noticing that our lower bound on $g(n,k,d;\;s)$ is increasing in $s$ , and is therefore minimised when $s = 0$ .

2.2. The upper bound construction

To prove the upper bound of Theorem 1.2(a), we must construct small $(k,d)$ -covers. As a first step, we introduce a recursive method for $(k,d;\;s)$ -covers that allows us to reduce to the $d = 1$ case.

Lemma 2.2. For integers $n \ge d \ge 2$ and $k \gt s \ge 0$ we have

\begin{equation*} g(n,k,d;\;s)\leq g(n-d+1,k,1;\;s)+2k(2^{d-1}-1), \end{equation*}

and, therefore,

\begin{equation*} f(n,k,d) \le f(n-d+1,k,1) + 2k(2^{d-1}-1). \end{equation*}

Proof. We first deduce the recursive bound on $g(n,k,d;\;s)$ . Let $S_0 \subseteq{\mathbb{F}_{2}^{n}}$ be an arbitrary $(n - d + 1)$ -dimensional (vector) subspace, and let $S_1, \ldots, S_{2^{d-1} - 1}$ be its affine translates, that, together with $S_0$ , partition $\mathbb{F}_{2}^{n}$ . For every $1\leq i\leq 2^{d-1}-1$ , partition $S_i \cong \mathbb{F}_2^{n - d+ 1}$ further into two subspaces, thereby obtaining a total of $2(2^{d - 1} - 1)$ affine subspaces of dimension $n - d$ . We start by taking $k$ copies of each of these affine subspaces. This gives us a multiset of $2k(2^{d - 1} - 1)$ subspaces, which cover every point outside $S_0$ exactly $k$ times and leave the points in $S_0$ completely uncovered.

It thus remains to cover the points within $S_0$ appropriately. Since $(n-d)$ -dimensional subspaces have relative codimension $1$ in $S_0$ , this reduces to finding a $(k,1;\;s)$ -cover within $S_0 \cong{\mathbb{F}_{2}^{n-d+1}}$ . By definition, we can find such a cover consisting of $g(n-d+1,k,1;\;s)$ subspaces. Adding these to our previous multiset gives a $(k,d;\;s)$ -cover of $\mathbb{F}_{2}^{n}$ of size $g(n-d+1,k,1;\;s) + 2k(2^{d-1} - 1)$ , as required.

To finish, since $f(n,k,d)=\min _s g(n,k,d;\;s)$ , and the recursive bound holds for each $s$ , it naturally carries over to the function $f(n,k,d)$ , giving .

Armed with this preparation, we can now resolve the problem for large multiplicities.

Proof of Theorem 1.2(a). The requisite lower bound, of course, is given by Lemma 2.1.

For the upper bound, we start by reducing to the case $d = 1$ . Indeed, suppose we already know the bound for $d=1$ ; that is, $f(n,k,1) \le 2k - \left\lfloor{ \frac{k}{2^{n-1}}}\right\rfloor$ for all $k \ge 2^{n-2}$ . Now, given some $n \ge d \ge 2$ and $k \ge 2^{n-d-1}$ , by Lemma 2.2 we have

\begin{equation*} f(n,k,d) \le f(n-d+1,k,1) + 2k(2^{d-1} -1) \le 2k - \left\lfloor {\frac {k}{2^{n-d+1-1}}}\right\rfloor + 2k(2^{d-1} -1) = 2^d k - \left\lfloor { \frac {k}{2^{n-d}}}\right\rfloor, \end{equation*}

as required.

Hence, it suffices to prove the bound in the hyperplane case. We begin with the lowest multiplicity covered by part (a), namely $k = 2^{n-2}$ . Consider the family $\mathcal{H}_0 = \{ H_{\vec{u}} \;:\; \vec{u} \in{\mathbb{F}_{2}^{n}}, u_n = 1 \}$ , where we recall that $H_{\vec{u}} = \{ \vec{x} \;:\; \vec{x} \cdot \vec{u} = 1 \}$ . Note that we then have $|{\mathcal{H}_0}| = 2^{n-1} = 2k = 2k - \left\lfloor{\frac{k}{2^{n-1}}}\right\rfloor$ , and none of these hyperplanes covers the origin. Given nonzero vectors $\vec{x} = (\vec{x}', x)$ and $\vec{u} = (\vec{u}',1)$ with $\vec{x}', \vec{u}' \in{\mathbb{F}_{2}^{n-1}}$ and $x \in{\mathbb{F}_{2}^{}}$ , we have $\vec{x} \cdot \vec{u} = 1$ if and only if $\vec{x}' \cdot \vec{u}' = 1-x$ . If $\vec{x}' \neq \vec{0}$ , precisely half of the choices for $\vec{u}'$ satisfy this equation; if $\vec{x}' = \vec{0}$ (and thus necessarily $x = 1$ ), the equation is satisfied by all choices of $\vec{u}'$ . Thus each nonzero point is covered at least $2^{n-2}$ times, and hence $\mathcal{H}_0$ is a $(2^{n-2},1)$ -cover of the desired size.

To extend the above construction to the range $2^{n-2}\leq k\lt 2^{n-1}$ , one can simply add an arbitrary choice of $k-2^{n-2}$ pairs of parallel hyperplanes. The resulting family will have $2^{n-1}+2\left (k-2^{n-2}\right )=2k=2k - \left\lfloor{\frac{k}{2^{n-1}}}\right\rfloor$ elements, every nonzero point is covered at least $k$ times, and the origin is covered $k-2^{n-2}\lt k$ times.

Finally, suppose $k\geq 2^{n-1}$ . Then we can write $k = a2^{n-1}+b$ for some $a\geq 1$ and $0\leq b \lt 2^{n-1}$ . We take $\mathcal{H}_1 = \{ H_{\vec{u}} \;:\; \vec{u} \in{\mathbb{F}_{2}^{n}} \setminus \{\vec{0}\} \}$ to be the set of all affine hyperplanes avoiding the origin, of which there are $2^n-1$ . Moreover, for each nonzero $\vec{x}$ , there are exactly $2^{n-1}$ vectors $\vec{u}$ with $\vec{x} \cdot \vec{u} = 1$ , and so each such point is covered $2^{n-1}$ times by the hyperplanes in $\mathcal{H}_1$ .

Now let $\mathcal{H}$ be the multiset of hyperplanes obtained by taking $a$ copies of $\mathcal{H}_1$ and appending an arbitrary choice of $b$ pairs of parallel planes. Each nonzero point is then covered $a2^{n-1} + b = k$ times, while the origin is only covered $b \lt 2^{n-1} \le k$ times, and so $\mathcal{H}$ is a $(k,1)$ -cover. Thus,

\begin{equation*} f(n,k,1) \le |{\mathcal {H}}| = a(2^n - 1) + 2b = 2(a 2^{n-1} + b) - a = 2k - \left\lfloor { \frac {k}{2^{n-1}}}\right\rfloor, \end{equation*}

proving the upper bound.

3. Covering high-dimensional spaces

In this section we turn our attention to the case when $n$ is large with respect to $k$ , with the aim of proving part (b) of Theorem 1.2. Furthermore, the results we prove along the way will allow us to establish the bounds in part (c) as well.

3.1. The upper bound construction

In this range, in contrast to the large multiplicity setting, it is the upper bound that is straightforward. This bound follows from the following construction, which is valid for the full range of parameters.

Lemma 3.1. Let $n,k,d$ be positive integers such that $n \ge d \ge 1$ and $k \ge 2$ . Then

\begin{equation*} f(n,k,d)\leq n + 2^d k - d - 2. \end{equation*}

Proof. We start by resolving the case $d=1$ and $k=2$ , for which we consider the family of hyperplanes $\mathcal{H} = \{ H_{\vec{e}_i} \;:\; i\in [n] \}\cup \{H_{\vec{1}}\}$ , where $\vec{e}_i$ is the $i$ th standard basis vector and $\vec{1}$ is the all-one vector. To see that this is a $(2,1$ )-cover of $\mathbb{F}_{2}^{n}$ , note first that the planes all avoid the origin. Next, if we have a nonzero vector $\vec{x}$ , it is covered by the hyperplanes $\{ H_{\vec{e}_i} \;:\; i\in [n] \}$ as many times as it has nonzero entries. Thus, all vectors of Hamming weight at least two are covered twice or more. The only remaining vectors are those of weight one, which are covered once by $\{ H_{\vec{e}_i} \;:\; i\in [n] \}$ , but these are all covered for the second time by $H_{\vec{1}}$ . Hence $\mathcal{H}$ is indeed a $(2,1)$ -cover, and is of the required size, namely $n+1$ .

Now we can extend this construction to the case $d=1$ and $k\geq 3$ by simply adding $k-2$ arbitrary pairs of parallel hyperplanes. The resulting family will be a $(k,1;\;k-2)$ -cover (and hence, in particular, a $(k,1)$ -cover) of size $n+2k-3$ , matching the claimed upper bound.

That leaves us with the case $d \ge 2$ , which we can once again handle by appealing to Lemma 2.2. In conjunction with the above construction, we have

\begin{equation*} f(n,k,d)\leq f(n-d+1,k,1)+2k(2^{d - 1} - 1)\leq n-d+1 +2k-3 + 2k(2^{d - 1} - 1), \end{equation*}

which simplifies to the required $n + 2^d k - d - 2$ .

3.2. Recursion, again

The upper bound in Lemma 3.1 is strictly increasing in $n$ . Our next step is to show that this behaviour is necessary—that is, the higher the dimension, the harder the space is to cover. Although intuitive, this fact turned out to be less elementary than expected, and our proof makes use of the probabilistic method.

Lemma 3.2. Let $n,k,d,s$ be integers such that $n\ge 2$ , $n \ge d \ge 1$ , and $k \gt s \ge 0$ . Then

\begin{equation*} g(n,k,d;\;s) \ge g(n-1,k,d;\;s) + 1. \end{equation*}

Proof. Let $\mathcal{H}$ be an optimal $(k,d;\;s)$ -cover of $\mathbb{F}_{2}^{n}$ . To prove the lower bound on its size, we shall construct from it a $(k,d;\;s)$ -cover $\mathcal{H}'$ of $\mathbb{F}_{2}^{n-1}$ , which must comprise of at least $g(n-1,k,d;\;s)$ subspaces. To obtain this cover of a lower-dimensional space, we restrict $\mathcal{H}$ to a random hyperplane $H \subseteq{\mathbb{F}_{2}^{n}}$ that passes through the origin. Since $\mathcal{H}$ is a $(k,d;\;s)$ -cover of all of $\mathbb{F}_{2}^{n}$ , it certainly covers $H \cong{\mathbb{F}_{2}^{n-1}}$ as well.

However, we require $\mathcal{H}'$ to be a $(k,d;\;s)$ -cover of $H$ , which must be built of affine subspaces of codimension $d$ relative to $H$ —that is, subspaces of dimension one less than those in $\mathcal{H}$ . Fortunately, when intersecting the subspaces $S \in \mathcal{H}$ with a hyperplane, we can expect their dimension to decrease by one. The exceptional cases are when $S$ is disjoint from $H$ , or when $S$ is contained in $H$ . In the former case, $S$ does not cover any points of $H$ , and can therefore be discarded from $\mathcal{H}'$ . In the latter case, we can partition $S$ into two subspaces $S = S_1 \cup S_2$ , where each $S_i$ is of codimension $d$ relative to $H$ , and replace $S$ with $S_1$ and $S_2$ in $\mathcal{H}'$ . By making these changes, we obtain a family $\mathcal{H}'$ of codimension- $d$ subspaces of $H$ . Moreover, these subspaces cover the points of $H$ exactly as often as those of $\mathcal{H}$ do, and thus $\mathcal{H}'$ is a $(k,d;\;s)$ -cover of $H$ .

When building this cover, though, we need to control its size. Let $X$ denote the set of subspaces $S \in \mathcal{H}$ that are disjoint from $H$ , and let $Y$ denote the set of subspaces $S \in \mathcal{H}$ that are contained in $H$ . We then have $|{ \mathcal{H}'}| = |{\mathcal{H}}| - |{X}| + |{Y}|$ . The objective, then, is to show that there is a choice of hyperplane $H$ for which $|{X}| \gt |{Y}|$ , in which case the cover $\mathcal{H}'$ we build is relatively small.

Recall that $H$ was a random hyperplane in $\mathbb{F}_{2}^{n}$ passing through the origin, which is to say it has a normal vector $\vec{u}$ chosen uniformly at random from ${\mathbb{F}_{2}^{n}}\setminus \{\vec{0}\}$ . To compute the expected sizes of $X$ and $Y$ , we consider the probability that a subspace $S \in \mathcal{H}$ is either disjoint from or contained in $H$ .

Let $S\in \mathcal{H}$ be arbitrary and suppose first that $\vec{0}\in S$ . We immediately have $\mathbb{P}(S\in X)=0$ , as in this case $\vec{0}\in S\cap H$ , so $S$ and $H$ cannot be disjoint. On the other hand, $\mathbb{P}(S\in Y)=\frac{2^d-1}{2^{n}-1}$ , as we have $S\subseteq H$ exactly when the normal vector $\vec{u}$ is a nonzero element of the $d$ -dimensional orthogonal complement, $S^{\perp }$ , of $S$ in $\mathbb{F}_{2}^{n}$ .

In the other case, when $\vec{0}\notin S$ , we can write $S$ in the form $T+\vec{v}$ , where $\vec{0} \in T \subseteq{\mathbb{F}_{2}^{n}}$ is an $(n-d)$ -dimensional vector subspace and $\vec{v} \in{\mathbb{F}_{2}^{n}}\setminus T$ . Then $S$ is disjoint from $H$ if and only if $\vec{u} \in T^{\perp }$ and $\vec{u} \cdot \vec{v} = 1$ . Since $\vec{v} \notin T$ , these are independent conditions, and so we have $\mathbb{P}(S \in X)=\frac{2^{d-1}}{2^{n}-1}$ . Similarly, in order to have $S \subseteq H$ , $\vec{u}$ must be a nonzero vector satisfying $\vec{u} \in T^{\perp }$ and $\vec{u} \cdot \vec{v} = 0$ , and so $\mathbb{P}(S\in Y)=\frac{2^{d-1}-1}{2^{n}-1}$ .

Now, using linearity of expectation, we have

\begin{align*} \mathbb{E} \left [ |{X}| - |{Y}| \right ] &= \sum _{S\in \mathcal{H}} \left (\mathbb{P}(S\in X)-\mathbb{P}(S\in Y)\right )\\[5pt] &= \sum _{S\in \mathcal{H}:\vec{0}\notin S} \left (\frac{2^{d-1}}{2^{n}-1}-\frac{2^{d-1}-1}{2^{n}-1}\right ) + \sum _{S\in \mathcal{H}:\vec{0}\in S} \left (0-\frac{2^d-1}{2^{n}-1}\right ) \\[5pt] &=\frac{|{\{S\in \mathcal{H}\;:\; \vec{0}\notin S\}}|-\left (2^d-1\right )|{\{S\in \mathcal{H}\;:\; \vec{0}\in S\}}|}{2^n-1} =\frac{|{\mathcal{H}}| - 2^d s}{2^n-1}, \end{align*}

where we used the fact that $\mathcal{H}$ is a $(k,d;\;s)$ -cover, and thus $|{\{S \in \mathcal{H}\;:\; \vec{0} \in S \}}| = s$ . We now apply the lower bound on $|{\mathcal{H}}|$ given by Lemma 2.1 to obtain

\begin{equation*} \mathbb {E} \left [ |{X}| - |{Y}| \right ] \geq \frac {2^d k - \left\lfloor {\frac {k-s}{2^{n-d}}}\right\rfloor -2^d s}{2^n-1} = \frac {2^d (k-s) - \left\lfloor {\frac {k-s}{2^{n-d}}}\right\rfloor }{2^n-1}\gt 0. \end{equation*}

Therefore, there must be a hyperplane $H$ for which $|{X}| - |{Y}| \ge 1$ . The corresponding cover of $H$ thus has size at most $|{\mathcal{H}}| - 1$ but, as a $(k,d;\;s)$ -cover of an $(n-1)$ -dimensional space, has size at least $g(n-1,k,d;\;s)$ . This gives $|{\mathcal{H}}| - 1 \ge |{\mathcal{H}'}| \ge g(n-1,k,d;\;s)$ , whence the required bound, $g(n,k,d;\;s) = |{\mathcal{H}}| \ge g(n-1,k,d;\;s) + 1$ .

While this inequality will be used in our proof of part (b) of Theorem 1.2, it also gives us what we need to prove the bounds in part (c).

Proof of Theorem 1.2(c). Lemma 3.1 gives us the upper bound, $f(n,k,d) \le n + 2^d k - d -2$ , which is in fact valid for all $k \ge 2$ and $n \ge d \ge 1$ .

When $n \ge \lfloor{\log _2 k}\rfloor + d + 1$ , we can prove the lower bound, $f(n,k,d) \ge n + 2^d k - d - \log _2\!(2k)$ , by induction on $n$ . For the base case, when $n = \lfloor{\log _2 k}\rfloor + d + 1$ , we appeal to Lemma 2.1, which gives

\begin{equation*} f(n,k,d) \ge 2^d k - \left\lfloor {\frac {k}{2^{n-d}}}\right\rfloor = 2^d k = n + 2^d k - d - \lfloor {\log _2 k}\rfloor - 1 \ge n + 2^d k - d - \log _2\!(2k). \end{equation*}

For the induction step we appeal to Lemma 3.2. First note that the lemma gives $f(n,k,d) = \min _s g(n,k,d;\;s) \ge \min _s\!( g(n-1,k,d;\;s) + 1 ) = f(n-1,k,d) + 1$ . Thus, using the induction hypothesis, for all $n \gt \lfloor{\log _2 k}\rfloor + d + 1$ we have

\begin{equation*} f(n,k,d) \ge f(n-1,k,d) + 1 \ge n-1 + 2^d k - d - \log _2\!(2k) + 1 = n + 2^d k - d - \log _2\!(2k), \end{equation*}

completing the proof.

At this stage, all that remains to be proven from Theorem 1.2 is the lower bound of part (b), a task we undertake in the following subsections.

3.3. A coding theory connection

In Lemma 3.2, we proved a recursive bound on $g(n,k,d;\;s)$ that is valid for all values of $s$ , the number of times the origin is covered. In this subsection, we establish the promised connection to coding theory, which is the key to our proof. Indeed, as observed in Corollary 3.7 below, it allows us to restrict our attention to only two feasible values of $s$ .

We begin with $(k,1;\;0)$ -covers of $\mathbb{F}_{2}^{n}$ , showing that, in this binary setting, hyperplane covers that avoid the origin are in direct correspondence with linear codes of large minimum distance. In the setting of multiple blocking sets, this connection to coding theory was observed by Landjev and Rousseva [Reference Landjev and Rousseva21], who used it to show that Bruen’s bound is far from being tight over $\mathbb{F}_2$ . We use a similar idea to obtain concrete bounds for $g(n,k,1;\;0)$ .

Proposition 3.3. A $(k,1;\;0)$ -cover of $\mathbb{F}_{2}^{n}$ of cardinality $m$ is equivalent to an $n$ -dimensional linear binary code of length $m$ and minimum distance at least $k$ .

Remark 3.4. In order to maintain consistency with earlier papers on hyperplane coverings, we deviate slightly from the standard coding theoretic notation, where $n$ usually stands for the length of the code, $k$ for its dimension, and $d$ for its minimum distance. In other words, our codes are $[m, n, k]$ -codes as opposed to the more standard $[n,k,d]$ -codes.

Proof. Let $\mathcal{H} = \{H_1, H_2, \ldots, H_m\}$ be a $(k,1;\;0)$ -cover of $\mathbb{F}_{2}^{n}$ . Since none of the hyperplanes cover the origin, for each $i \in [m]$ , $H_i$ has to be described by the equation $\vec{u}_i\cdot \vec{x} = 1$ for some $\vec{u}_i \in{\mathbb{F}_{2}^{n}} \setminus \{ \vec{0} \}$ . Let $A$ be the $m \times n$ matrix whose rows are $\vec{u}_1, \vec{u}_2, \ldots, \vec{u}_m$ . We claim that $A$ is the generator matrix of a linear binary code of dimension $n$ , length $m$ , and minimum distance at least $k$ . Since each $\vec{x} \in{\mathbb{F}_{2}^{n}} \setminus \{ \vec{0} \}$ is covered by at least $k$ of the planes, it follows that the vector $A \vec{x}$ has weight at least $k$ , which in turn is equivalent to the vectors in the column space of $A$ having minimum distance at least $k$ . Indeed, any vector $\vec{y}$ in the column space can be expressed in the form $A \vec{w}$ for some $\vec{w} \in{\mathbb{F}_{2}^{n}}$ . Thus, given two distinct vectors $\vec{y}_1, \vec{y}_2$ in the column space, their difference is of the form $A(\vec{w}_1 - \vec{w}_2)$ , where $\vec{x} = \vec{w}_1 - \vec{w}_2$ is nonzero. Hence this difference has weight at least $k$ ; i.e., the two vectors $\vec{y}_1$ and $\vec{y}_2$ have distance at least $k$ . The fact that the weight of $A\vec{x}$ is at least $k\geq 1$ for any $\vec{x}\neq 0$ also implies that the kernel of $A$ is trivial; therefore, the dimension of the column space of $A$ , and hence of the binary code generated by $A$ , is $n$ .

Conversely, given a linear binary code of dimension $n$ , length $m$ , and minimum distance at least $k$ , let $\vec{u}_1, \vec{u}_2, \ldots, \vec{u}_m$ be the rows of the generator matrix. By the same reasoning as above, the hyperplanes $H_i$ , $i\in [m]$ , defined by the equation $\vec{u}_i\cdot \vec{x} = 1$ , form a $(k,1;\;0)$ -cover of $\mathbb{F}_{2}^{n}$ .

Thus, the problem of finding a small $(k,1;\;0)$ -cover of $\mathbb{F}_{2}^{n}$ corresponds to finding an $n$ -dimensional linear code of minimum distance at least $k$ and small length. This is a central problem in coding theory [Reference van Lint14] and, as such, has been extensively studied (see for example [Reference Jiang and Vardy17, Reference Schrijver25] and the references therein). We can therefore leverage known bounds to bound the function $g(n,k,1;\;0)$ .

Corollary 3.5. For all $k \geq 2$ and $n \geq 1$ ,

\begin{equation*} g(n, k,1;\;0)\geq n + \left \lfloor \frac {k - 1}{2} \right \rfloor \log _2 \left ( \frac {2n}{k-1} \right ). \end{equation*}

Proof. Let $\mathcal{H}$ be an optimal $(k,1,0)$ -cover and let $\mathcal{C} \subseteq{\mathbb{F}_{2}^{m}}$ be the equivalent $n$ -dimensional linear binary code of length $m=|{\mathcal{H}}|$ and minimum distance at least $k$ , as described in Proposition 3.3. We can now appeal to the Hamming bound: since the code has minimum distance $k$ , the balls of radius $t = \left\lfloor{\frac{k-1}{2}}\right\rfloor$ around the $2^n$ points of $\mathcal{C}$ must be pairwise disjoint. As each ball has size $\sum _{i=0}^t \binom{m}{i}$ , and the ambient space has size $2^m$ , we get

\begin{equation*} 2^n\leq \frac {2^m}{\sum _{i=0}^t \binom {m}{i}}. \end{equation*}

We bound the denominator from below by

\begin{equation*} \sum _{i=0}^t \binom {m}{i}\geq \binom {m}{t} \ge \left ( \frac {m}{t} \right )^t \ge \left ( \frac {n}{t} \right )^t = 2^{t \log _2 \left (\tfrac {n}{t}\right )}, \end{equation*}

where the last inequality is valid provided $m\geq n$ , as it must be. Thus we conclude

\begin{equation*} g(n,k,1;\;0)=|\mathcal {H}|=m \ge n + t \log _2 \left (\frac {n}{t}\right ) \geq n + \left \lfloor \frac {k - 1}{2} \right \rfloor \log _2 \left ( \frac {2n}{k-1} \right ). \end{equation*}

Remark 3.6. Although it may seem that some of our bounds might be wasteful, one can deduce upper bounds from the Gilbert–Varshamov bound, which is obtained by considering a random linear code. In particular, if $n$ is large with respect to $k$ , one finds that . Narrowing the gap between these upper and lower bounds remains an active area of research in coding theory.

The above lower bound can be used to show that, if $n$ is large with respect to $k$ and $d$ , then every optimal $(k,d)$ -cover has to cover the origin many times. This corollary is critical to our proof of the upper bound.

Corollary 3.7. If $n \gt 2^{2^d k -k-d+ 1}$ , then any optimal $(k,d)$ -cover of $\mathbb{F}_2^n$ covers the origin at least $k-2$ times.

Proof. Let $S_1, \dots, S_m$ be an optimal $(k,d)$ -cover, and, if necessary, relabel the subspaces so that $S_1, \dots, S_s$ are the affine subspaces covering the origin. Suppose for a contradiction that $s \leq k - 3$ , and observe that if we delete the first $k-3$ subspaces, each nonzero point must still be covered at least thrice, while the origin is left uncovered. That is, $S_{k-2}, S_{k-1}, \ldots, S_m$ forms a $(3,d;\;0)$ -cover of $\mathbb{F}_{2}^{n}$ .

For each $k-2 \le j \le m$ , we can then extend $S_j$ to an arbitrary hyperplane $H_j$ that contains $S_j$ and avoids the origin. Then $\{H_{k-2}, H_{k-1}, \ldots, H_m\}$ is a $(3,1;\;0)$ -cover, and hence $m-k+3 \ge g(n,3,1;\;0)$ .

By Corollary 3.5, this, together with the assumption $n \gt 2^{2^d k -k-d+ 1}$ , implies

\begin{align*} f(n,k,d)&=m\geq g(n,3,1;\;0)+k-3\geq n +\log _2 n + k-3\gt n + 2^d k -k-d+ 1+k-3\\[5pt] &= n + 2^d k - d - 2, \end{align*}

which contradicts the upper bound from Lemma 3.1.

Remark 3.8. Observe that Corollary 3.7 in fact gives us some stability for large dimensions. If $n = 2^{2^d k - k - d + \omega (1)}$ , then the above calculation shows that any $(k,d)$ -cover that covers the origin at most $k-3$ times has size at least $n + 2^d k + \omega (1)$ . Thus, when $n = 2^{2^d k - k - d + \omega (1)}$ , any $(k,d)$ -cover that is even close to optimal must cover the origin at least $k-2$ times.

3.4. The lower bound

By Corollary 3.7, when trying to bound $f(n,k,d) = \min _s g(n,k,d;\;s)$ for large $n$ , we can restrict our attention to $s \in \{k-2,k-1\}$ . First we deal with the latter case.

Lemma 3.9. Let $n,k,d$ be positive integers such that $n \ge d \ge 1$ . Then

\begin{equation*} g(n,k,d;\;k-1)= n + 2^d k - d - 1. \end{equation*}

Proof. To prove the statement, we will show that, for all positive integers $n,k,d$ with $n \ge d \ge 1$ , we have $g(n+1,k,d;\;k-1) = g(n,k,d;\;k-1)+1$ . Combined with the simple observation that $g(d,k,d;\;k-1) =2^d k - 1$ for all $k \ge 1$ , since when $d = n$ we are covering with individual points, this fact will indeed imply the desired result.

By Lemma 3.2 we know that $g(n+1,k,d;\;k-1) \geq g(n,k,d;\;k-1)+1$ . For the other inequality, consider an optimal $(k,d;\;k-1)$ -cover $\mathcal{H}$ of $\mathbb{F}_2^n$ . For every $S\in \mathcal{H}$ , let $S'=S\times \{0,1\}$ , which is a codimension- $d$ affine subspace of $\mathbb{F}_{2}^{n+1}$ , and let $S_0$ be any $(n + 1 - d)$ -dimensional affine subspace of $\mathbb{F}_{2}^{n+1}$ that contains the vector $(0,\ldots,0,1)$ but avoids the origin. We claim that $\mathcal{H}'=\{ S' \;:\; S\in \mathcal{H}\}\cup \{S_0\}$ is a $(k,d;\;k-1)$ -cover of $\mathbb{F}_{2}^{n+1}$ . Indeed, for all $S\in \mathcal{H}$ , a point of the form $(\vec{x},t)$ is covered by $S'$ if and only if $\vec{x}$ is covered by $S$ . Hence, the collection $\{S' \;:\; S\in \mathcal{H}\}$ covers $\vec{0}$ exactly $k-1$ times and each point of the form $(\vec{x},t)$ with $\vec{x} \neq \vec{0}$ at least $k$ times. Finally, the point $(\vec{0},1)$ is covered $k-1$ times by the $\{S' \;:\; S\in \mathcal{H}\}$ and once by the subspace $S_0$ , so it is also covered the correct number of times. Hence $\mathcal{H}'$ is indeed a $(k,d;\;k-1)$ -cover of size $|\mathcal{H}|+1$ , and so the second inequality follows.

Remark 3.10. Recall that the special case of $d = 1$ , $g(n, k, 1;\; k - 1) = n + 2k - 2$ , also follows from [[Reference Sauermann and Wigderson24], Theorem 1.5].

The proof of Theorem 1.2(b) is now straightforward.

Proof of Theorem 1.2(b). The upper bound is given by Lemma 3.1. For the lower bound, first observe that for any valid choice of the parameters, we have $g(n,k,d;\;s+1)\leq g(n,k,d;\;s)+1$ , as adding any subspace containing the origin to a $(k,d;\;s)$ -cover yields a $(k,d;\;s+1)$ -cover. Then, by Corollary 3.7 and Lemma 3.9, we obtain

\begin{equation*} f(n,k,d)=\min \{g(n,k,d;\;k-2),g(n,k,d;\;k-1)\}\geq g(n,k,d;\;k-1)-1=n + 2^d k - d - 2, \end{equation*}

as desired.

4. Concluding remarks

In this paper, we investigated the minimum number of affine subspaces of a fixed codimension needed to cover all nonzero points of $\mathbb{F}_{2}^{n}$ at least $k$ times, while only covering the origin at most $k-1$ times. We were able to determine the answer precisely when $k$ is exponentially large with respect to $n$ , or when $n$ is exponentially large with respect to $k$ , and provided asymptotically sharp bounds for the range in between these extremes. In this final section, we highlight some open problems and avenues for further research.

Tightness of the general upper bound

As remarked upon in the introduction, we know that the bound on $k$ in part (a) of our main result is best possible. However, as we explain below, for part (b) we believe the upper bound of Lemma 3.1 should be tight for much smaller values of $n$ as well. For a more detailed discussion, we refer the reader to the arXiv version of this paper.

As we saw in Lemma 2.2, for our upper bounds we can generally reduce to the hyperplane setting, and so we shall focus on the $d=1$ case here. In this hyperplane setting, the upper bound of Lemma 3.1, valid for all $n \ge 1$ and $k \ge 2$ , has the simple form $n + 2k - 3$ . Using the recursive bound in Lemma 3.2, we observe that if $f(n_0,k,1) = n_0 + 2k - 3$ for some positive integer $n_0$ , then $f(n,k,1) = n + 2k - 3$ for all $n\geq n_0$ . Hence, for every $k$ , there is a well-defined threshold $n_0(k)$ such that $f(n,k,1) = n + 2k - 3$ if and only if $n \ge n_0(k)$ . Theorem 1.2(b) shows $n_0(k) \le 2^k + 1$ , while part (a) implies that $n_0(k) \gt \log _2 k + 2$ .

We can obtain a linear lower bound on $n_0(k)$ for $k\geq 4$ by considering the collection of hyperplanes in $\mathbb{F}_{2}^{k}$ containing $ H_{\vec{e}_i}$ and $H_{\vec{1}-\vec{e}_i}$ for each $i\in [k]$ , where $\vec{e}_i$ denotes the $i$ th standard basis vector and $\vec{1}$ the all-one vector, together with $k-4$ copies of the hyperplane $\vec{x}\cdot \vec{1}=0$ . This collection has size $3k-4$ and one can check that it forms a $k$ -cover of $\mathbb{F}_{2}^{k}$ , implying that $n_0(k)\geq k+1$ , and this is the best general construction we have that improves the simple $n + 2k -3$ bound. Indeed, while the extended binary Golay code, coupled with Proposition 3.3, shows that you can do better for $8 \le k \le 11$ , this is known to be a very efficient, but sporadic, code, and we cannot generalise the construction to larger $k$ . This leads us to ask the following question.

Question 4.1. Do we have $n_0(k) = k+1$ when $k \ge 12$ ?

Equivalently, we are asking whether $3k-2$ hyperplanes are needed in a $(k,1)$ -cover of $\mathbb{F}_{2}^{k+1}$ . We observe that, exploiting the coding connection once again, the Gilbert–Varshamov bound, discussed in Remark 3.6, shows that a random collection of $k+O(\log _2 k)$ hyperplanes forms a (3,1;0)-cover of $\mathbb{F}_{2}^{k+1}$ with high probability. Adding $k-3$ pairs of parallel planes then yields a $(k,1)$ -cover of size $3k + O(\log _2 k)$ , showing that there are numerous asymptotically optimal covers. Hence, we cannot hope for any strong stability when $n$ is comparable to $k$ , which could make the resolution of this question difficult, but as a first step one could attempt to reduce the exponential upper bound on $n_0(k)$ . Furthermore, while we have focused on the hyperplane case in Question 4.1, it would also be worth exploring the corresponding threshold $n_0(k,d)$ for $d \ge 2$ , as it would be very interesting if there were new constructions that appear when covering with affine subspaces of codimension $d$ .

Larger fields

In this paper we have worked exclusively over the binary field $\mathbb{F}_{2}^{}$ , but it is also natural to explore these subspace covering problems over larger finite fields, $\mathbb{F}_q$ for $q \gt 2$ . Let us denote the corresponding extremal function by $f_q(n, k, d)$ , which is the minimum cardinality of a multiset of $(n - d)$ -dimensional affine subspaces that cover all points of $\mathbb{F}_q^n \setminus \{\vec{0}\}$ at least $k$ times, and the origin at most $k - 1$ times. The work of Jamison [Reference Jamison16] establishes the initial values of this function, showing $f_q(n, 1, d) = (q - 1)(n - d) + q^d - 1$ . When it comes to multiplicities $k \ge 2$ , some of what we have done here can be transferred to larger fields as well.

To start, we can once again resolve the setting where the multiplicity $k$ is large with respect to the dimension $n$ . Indeed, the double-counting lower bound of Lemma 2.1 generalises immediately to this setting, giving $f_q(n, k, d) \geq q^d k - \left\lfloor{ \frac{k}{q^{n - d}} }\right\rfloor$ , and one can obtain a matching upper bound by taking multiple copies of every affine subspace.

In the other extreme, where $n$ is large with respect to $k$ , the problem remains wide open. We first note that the reduction to hyperplanes from Lemma 2.2 can be extended, giving $f_q(n, k, d) \leq f_q( n - d + 1, k, 1) + (q^{d - 1} - 1)kq$ . Thus, as before, it is best to first focus on the case $d = 1$ , where Jamison’s result gives $f_q(n, 1, 1) = (q - 1)n$ .

For an upper bound, let us start by considering $2$ -covers. It is once again true that if one takes the standard $1$ -covering by hyperplanes, consisting of all hyperplanes of the form $\{\vec{x}\;:\; x_i = c \}$ for some $i \in [n]$ and $c \in{\mathbb{F}_{q}^{}} \setminus \{0\}$ , the only nonzero vectors that are only covered once are those of Hamming weight $1$ . However, since the nonzero coordinate of these vectors can take any of $q-1$ different values, it takes a further $q-1$ hyperplanes to cover these again, and so we have $f_q(n,2,1) \le (q-1)(n+1)$ . Now, given a $(k-1)$ -cover of $\mathbb{F}_{q}^{n}$ , one can obtain a $k$ -cover by adding an arbitrary partition of $\mathbb{F}_{q}^{n}$ into $q$ parallel planes, and this yields $f_q(n,k) \le (q-1)(n+1) + q(k-2)$ . This construction is the direct analogue of that from Lemma 3.1, and so, as in Theorem 1.2(b), we expect it to be tight when $n$ is sufficiently large.

Question 4.2. For $n \ge n_0(k,q)$ , do we have $f_q(n,k,1) = (q-1)(n+1) + q(k-2)$ ?

As we already have the construction above, one needs to prove a matching lower bound. It would of course be very helpful to use some of the machinery we have developed here, and so we briefly explain where the difficulties therein lie. Key to our binary proof was the equivalence with codes of a certain minimum weight, but this breaks down over $\mathbb{F}_{q}^{}$ . While we can show that every $(k,1)$ -covering of $\mathbb{F}_{q}^{n}$ gives rise to a linear $q$ -ary $n$ -dimensional code of minimum distance at least $k(q-1)$ , the converse is not true. As a result, the coding theoretic bounds, which are of the form $n + O(k q \log _q n)$ , are not strong enough to give us information here.

Another main tool was the recursion over $n$ , showing that $f(n,k,1)$ is strictly increasing in $n$ . The same proof goes through here, and we can again show $f_q(n,k,1) \gt f_q(n-1,k,1)$ . However, from our bounds, we expect the stronger inequality $f_q(n,k,1) \ge f_q(n-1,k,1) + q - 1$ to hold. Intuitively, this is because when we restrict a $k$ -cover of $\mathbb{F}_{q}^{n}$ to ${\mathbb{F}_{q-1}^{n}} \subseteq{\mathbb{F}_{q}^{n}}$ , there are $q-1$ affine copies of $\mathbb{F}_{q-1}^{n}$ that are lost. However, this does not (appear to) come out of our probabilistic argument.

A simple general lower bound is obtained by noticing that removing $k-1$ hyperplanes from a $(k,1)$ -cover leaves us with at least a $(1,1)$ -cover, and so . This remains the best lower bound we know—in particular, even the case of $f_q(n,2,1)$ is unsolved. It would thus be of great interest to develop new tools to handle the $q$ -ary case, as these may also bear fruit when applied to the open problems in the binary setting, and we believe that new algebraic ideas may be useful here.

Polynomials with large multiplicity

Finally, speaking of algebraic methods, we return to our introductory discussion of the polynomial method. Recall that previous lower bounds in this area have been obtained by considering the more general problem of the minimum degree of a polynomial in ${\mathbb{F}_{}^{}}[x_1, x_2, \ldots, x_n]$ that vanishes with multiplicity at least $k$ at all nonzero points in some finite grid, and with lower multiplicity at the origin. Sauermann and Wigderson’s recent breakthrough, Theorem 1.1, resolves this polynomial problem for $n \ge 2k-3$ over fields of characteristic 0, while our results here show that, in the binary setting at least, there is separation between the hyperplane covering and the polynomial problems.

Despite this, we wonder whether the answers to the two problems might coincide in the range where the multiplicity $k$ is large with respect to the dimension $n$ . That is, can the simple double-counting hyperplane lower bound be strengthened to the polynomial setting? We would therefore like to close by emphasising a question of Sauermann and Wigderson [Reference Sauermann and Wigderson24], this time over $\mathbb{F}_{2}^{}$ .

Question 4.3. Given positive integers $k, n$ with $k \ge 2^{n-2}$ , let $P \in{\mathbb{F}_{2}^{}}[x_1, x_2, \ldots, x_n]$ be a polynomial that vanishes with multiplicity at least $k$ at every nonzero point, and with multiplicity at most $k-1$ at the origin. Must we then have $\deg\!(P) \ge 2k - \left\lfloor{\frac{k}{2^{n-1}}}\right\rfloor$ ?

Acknowledgements

This work was carried out when the authors were all working at the Institut für Mathematik of the Freie Universität Berlin, and we would like to thank the Combinatorics and Graph Theory research group for providing a fertile and enjoyable working environment. We are also grateful to the anonymous referees for their helpful suggestions.

Footnotes

Research supported by the Deutsche Forschungsgemeinschaft (DFG) Graduiertenkolleg “Facets of Complexity” (GRK 2434). Research supported in part by the Deutsche Forschungsgemeinschaft (DFG) project 415310276 and by the NSTC grant 111-2115-M-002-009-MY2. Research supported by the Deutsche Forschungsgemeinschaft (DFG) under Germany’s Excellence Strategy - The Berlin Mathematics Research Center MATH+ (EXC-2046/1, project ID: 390685689).

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