2 $ (v, k, \lambda ) $ -difference sets and coverings of $ A_n $

In the following, when using notions from graph theory in our setting, we have in mind the graph representation $ \Gamma (A_n) $ of $ A_n $ , as introduced in Section 1. An $ (r, i, j) $ -cover in a graph $ \Gamma = (V, E) $ [Reference Axenovich1] is a set of its vertices $ S \subseteq V $ having the property that every element of $ S $ , respectively $ V \setminus S $ , is covered by exactly $ i $ , respectively $ j $ , balls of radius r centred at elements of $ S $ . Special cases of such sets, namely $ (1, i, j) $ covers, have also been studied in the context of domination in graphs [Reference Telle10]. Note also that an $ (r, 1, 1) $ -cover is a tiling of $ V $ with balls of radius $ r $ (in coding theory, this is known as an $ r $ -perfect code). An independent set in a graph $ \Gamma = (V, E) $ is a subset of its vertices $ I \subseteq V $ , no two of which are adjacent in $ \Gamma $ .

We now state our main result. The proof is a generalisation of the connection between lattice packing/tiling and so-called group splitting [Reference Stein and Szabó9].

Proof. Suppose that $ D = \{ d_0, d_1, \ldots , d_{n} \} $ is a $ (v, n+1, \lambda ) $ -difference set in an Abelian group $ G $ and consider the sublattice

(2.1) $$ \begin{align} {\mathcal L}_D = \bigg\{ \boldsymbol {x} \in A_{n} : \sum_{i=0}^{n} x_i d_i = 0 \bigg\} , \end{align} $$

where $ x_i d_i $ denotes the sum in $ G $ of $ |x_i| $ copies of $ d_i $ , respectively $ -d_i $ , if $ x_i> 0 $ , respectively $ x_i < 0 $ . Let us show that $ {\mathcal L}_D $ is a $ (1, 1, \lambda ) $ -cover of $ A_{n} $ . Consider a point $ \boldsymbol {y} = (y_0, y_1, \ldots , y_{n}) \notin {\mathcal L}_D $ , meaning that $ \sum _{i=0}^n y_i d_i = a \in G $ , $ a \neq 0 $ . The neighbours of $ \boldsymbol {y} $ are of the form $ \boldsymbol {y} + \boldsymbol {f}_{i,j} $ , $ i \neq j $ (recall that $ \boldsymbol {f}_{i,j} $ denotes the vector having $ 1 $ at the $ i $ th coordinate, $ -1 $ at the $ j $ th coordinate and zeros elsewhere). Because $ D $ is a difference set, $ -a \in G $ can be written as a difference of two elements from $ D $ in exactly $ \lambda $ ways, meaning that there are $ \lambda $ different pairs $ (s,t) $ for which $ d_s - d_t = -a $ , $ d_s, d_t \in D $ . For every such pair, consider the point $ \boldsymbol {z}_{s,t} = \boldsymbol {y} + \boldsymbol {f}_{s,t} $ . Note that $ \boldsymbol {z}_{s,t} \in {\mathcal L}_D $ because $ \sum _{i=0}^n z_i d_i = \sum _{i=0}^n y_i d_i + d_s - d_t = a - a = 0 $ . Therefore, there are exactly $ \lambda $ points in the lattice $ {\mathcal L}_D $ that are adjacent to $ \boldsymbol {y} $ , that is, such that balls of radius $ 1 $ around them cover $ \boldsymbol {y} $ . To show that the elements of $ {\mathcal L}_D $ are covered only by the balls around themselves (that is, $ {\mathcal L}_D $ is an independent set in $ \Gamma (A_n) $ ), note that if there were two points at distance $ 1 $ in $ {\mathcal L}_D $ , then, by the same argument as above, we would obtain $ d_s - d_t = 0 $ , that is, $ d_s = d_t $ for some $ s \neq t $ , which is not possible if $ | D | = n + 1 $ .

For the other direction, assume that $ {\mathcal L} $ is a $ (1, 1, \lambda ) $ -covering sublattice of $ A_{n} $ . Consider the quotient group $ G = A_{n} / {\mathcal L} $ and take $ D_{\mathcal L} = \{ d_0, d_1, \ldots , d_{n} \} \subseteq G $ , where $ d_i = [\kern2pt \boldsymbol {f}_{i,0}] \equiv \boldsymbol {f}_{i,0} + {\mathcal L} $ are cosets (elements of $ G $ ). Let us first check that all the $ d_i $ terms are distinct. Suppose that $ d_s = d_t $ for some $ s \neq t $ . This implies that ${ d_s - d_t = [\kern2pt \boldsymbol {f}_{s,t}] = [ \boldsymbol {0}] }$ , which means that $ \boldsymbol {f}_{s,t} \in {\mathcal L} $ . However, because $ \boldsymbol {0} \in {\mathcal L} $ and $ \boldsymbol {0} $ and $ \boldsymbol {f}_{s,t} $ are at distance $ 1 $ , this would contradict the fact that $ {\mathcal L} $ is an independent set in $ \Gamma (A_n) $ . Hence, $ | D_{\mathcal L} | = n + 1 $ . Now take any nonzero element of $ G $ , say $ [ \kern2pt\boldsymbol {y}] $ , $ \boldsymbol {y} \notin {\mathcal L} $ . By assumption, $ \boldsymbol {y} $ is covered by exactly $ \lambda $ elements of $ {\mathcal L} $ , that is, $ \boldsymbol {y} + \boldsymbol {f}_{s,t} \in {\mathcal L} $ for exactly $ \lambda $ vectors $ \boldsymbol {f}_{s,t} $ . Because $ \boldsymbol {f}_{s,t} = \boldsymbol {f}_{s,0} - \boldsymbol {f}_{t,0} $ , this means that $ d_t - d_s = [\kern2pt \boldsymbol {f}_{t,0}] - [\kern2pt \boldsymbol {f}_{s,0}] = [ \kern2pt\boldsymbol {y}] $ for exactly $ \lambda $ pairs $ (s,t) $ . Therefore, $ D_{\mathcal L} $ is a $ (v, n + 1, \lambda ) $ -difference set.

Note that we have not specified the order of the elements of $ D $ when defining the corresponding lattice $ {\mathcal L}_D $ in (2.1) because it would only affect it in an insignificant way. Note also that if we write $ d_i' = zd_i + g $ instead of $ d_i $ in (2.1), where $ z $ is a fixed integer coprime with $ v $ and $ g $ is a fixed element of $ G $ , the same lattice is obtained because

$$ \begin{align*} \sum_{i=0}^{n} x_i d_i = 0 \quad \Leftrightarrow \quad \sum_{i=0}^{n} x_i d_i' = 0 , \end{align*} $$

which follows from $ \sum _{i=0}^{n} x_i = 0 $ and $ \operatorname {gcd}(z, v) = 1 $ . (Recall that two difference sets $ D $ and $ D' $ in an Abelian group $ G $ are said to be equivalent [Reference Beth, Jungnickel and Lenz2, Remark 1.11, page 302] if $ D' = \{ zd + g: d \in D \} $ , for some $ z \in \mathbb {Z} $ coprime with $ v = |G| $ and some $ g \in G $ .)

Figure 2 A $ (1, 1, 2) $ -covering sublattice of $ A_2 $ , representing the difference set $ D = \{ 0, 1, 2 \} \subset \mathbb {Z}_4 $ .

Geometrically, the theorem states that balls of radius $ 1 $ around the points of the sublattice $ {\mathcal L}_D $ overlap in such a way that every point that does not belong to $ {\mathcal L}_D $ is covered by exactly $ \lambda $ balls. (The points in $ {\mathcal L}_D $ (centres of the balls) are covered by one ball only, and hence this notion is different from multitiling [Reference Gravin, Robins and Shiryaev5].) Note that increasing $ \lambda $ increases the density of the lattice $ {\mathcal L}_D $ in $ A_{n} $ . The densest such lattice is therefore obtained for $ \lambda = n + 1 $ (which is the maximum value because $ \lambda (v-1) = n(n+1) $ and ${n \leq v - 1}$ ). It corresponds to the trivial $ (v,v,v) $ -difference set $ D = G $ in an arbitrary Abelian group $ G $ .

Example 2.2. $ D = \{ 0, 1, 2 \} $ is a $ (4, 3, 2) $ -difference set in the cyclic group $ \mathbb {Z}_4 $ . A $ (1, 1, 2) $ -covering sublattice $ {\mathcal L}_D \subset A_2 $ corresponding to this difference set (see (2.1)) is illustrated in Figure 2. Points in $ {\mathcal L}_D $ are depicted as black and those in $ A_2\setminus {\mathcal L}_D $ as white dots. For illustration, Figure 3 shows an example of a $ (1, \boldsymbol {3}, 2) $ -covering sublattice of $ A_2 $ , which does not represent any difference set.

Figure 3 A $ (1, 3, 2) $ -covering sublattice of $ A_2 $ .

3 Planar difference sets and tilings of $ A_n $

A $ (v, k, 1) $ -difference set $ D \subseteq G $ is called planar (or simple). The condition $ \lambda = 1 $ means that every nonzero element of the group $ G $ can be expressed as a difference of two elements from $ D $ in a unique way. In this case, we necessarily have $ v = |G| = k^2 - k + 1 $ . The order of a planar difference set $ D $ of cardinality $ k $ is defined as $ k - 1 $ . These objects are very well-studied, and a large body of literature is devoted to their constructions and investigation of their properties [Reference Beth, Jungnickel and Lenz2]. One of the most well-known problems in the area concerning the existence of planar difference sets for specific sets of parameters is the so-called prime power conjecture [Reference Beth, Jungnickel and Lenz2, Conjecture 7.5, page 346], which states that a planar difference set of order $ n $ exists if and only if $ n $ is a prime power (counting $ n = 1 $ as a prime power). Existence of such sets for $ n = p^m $ , $ p $ prime, $ m \in \mathbb {N} $ , was demonstrated by Singer [Reference Singer8], but the necessity of this condition remains an open problem for over eight decades.

As we noted earlier, a $ (1, 1, 1) $ -cover of $ A_n $ is in fact a tiling of $ (A_n, d) $ with balls of radius $ 1 $ , meaning that every point in $ A_n $ is covered by exactly one ball. If the centres of the balls form a sublattice of $ A_n $ , then this is said to be a lattice tiling. We can now state what Theorem 2.1 reduces to in the special case $ \lambda = 1 $ .

Existence of such tilings when $ n $ is a prime power follows from the existence of the corresponding planar difference sets [Reference Singer8], but the necessity of this condition is open and is equivalent to the prime power conjecture.

A stronger conjecture would claim the above even for nonlattice tilings.

Example 3.3. Consider a planar difference set $ D = \{0, 1, 3, 9\} \subset \mathbb {Z}_{13} $ . The corresponding lattice tiling of $ (A_3, d) $ is illustrated in Figure 4(a). The figure shows the intersection of $ A_3 $ with the plane $ x_0 = 0 $ ; the intersections of a ball of radius $ 1 $ in $ (A_3, d) $ with the planes $ x_0 = \text {const.} $ are shown in Figure 4(b) as a clarification.

Figure 4 Lattice tiling of $ (A_3, d) $ corresponding to the difference set $ D = \{0, 1, 3, 9\} \subset \mathbb {Z}_{13} $ .

Corollary 3.1 and Example 3.3 were also stated in [Reference Kovačević and Tan6] by using coding theoretic terminology.

Another important unsolved problem in the field is the following: all Abelian planar difference sets live in cyclic groups [Reference Beth, Jungnickel and Lenz2, Conjecture 7.7, page 346]. Because the group $ G $ containing a difference set $ D $ which defines a lattice $ {\mathcal L}_D $ is isomorphic to $ A_n/{\mathcal L}_D $ , the statement that $ G $ is cyclic, that is, that it has a generator, is equivalent to the following statement.

The cyclic case. To conclude the paper, let us consider briefly the case of cyclic planar difference sets of order $ n $ , where it is assumed that the group we are working with is $ \mathbb {Z}_v $ , $ v = n^2 + n + 1 $ . As mentioned above, the restriction to cyclic groups might not be a restriction at all. So let $ D = \{ d_0, d_1, \ldots , d_n \} \subset \mathbb {Z}_v $ be a difference set and assume that $ d_0 = 0 $ , $ d_1 = 1 $ . (This is not a loss in generality because if $ D $ is a difference set, then there exist two elements, say $ d_0, d_1 \in D $ , such that $ d_1 - d_0 = 1 $ , so one can instead consider the equivalent difference set $ D' = \{ d_i - d_0 : d_i \in D \} $ which obviously contains $ 0 $ and $ 1 $ .) Let $ {\mathcal L}_D \subset \mathbb {Z} ^n $ be the lattice defined as in (2.1), but with the $ 0 $ -coordinate of all vectors left out (the latter is done for convenience, because $ d_0 = 0 $ ). Leaving out the $ 0 $ -coordinate essentially transforms the space $ (A_n, d) $ to $ (\mathbb {Z}^n, d^+ ) $ (see Remark 1.1). The generator matrix of the lattice $ {\mathcal L}_D $ can then be written in the following simple and explicit form:

$$ \begin{align*} B({\mathcal L}_D) = \begin{pmatrix} v & 0 & 0 & \cdots & 0 \\ -d_2 & 1 & 0 & \cdots & 0 \\ -d_3 & 0 & 1 & \cdots & 0 \\ \vdots & \vdots & \vdots & \ddots & \vdots \\ -d_n & 0 & 0 & \cdots & 1 \end{pmatrix} , \end{align*} $$

that is, the elements of the lattice are the vectors $ \boldsymbol {x} = \boldsymbol {\xi } \cdot B({\mathcal L}_D) $ , $ \boldsymbol {\xi } \in \mathbb {Z}^n $ . The generator matrix of the dual lattice $ {\mathcal L}_D^* $ is

$$ \begin{align*} B({\mathcal L}_D^*) = B({\mathcal L}_D)^{-{T}} = \begin{pmatrix} {1}/{v} & {d_2}/{v} & {d_3}/{v} & \cdots & {d_n}/{v} \\ 0 & 1 & 0 & \cdots & 0 \\ 0 & 0 & 1 & \cdots & 0 \\ \vdots & \vdots & \vdots & \ddots & \vdots \\ 0 & 0 & 0 & \cdots & 1 \end{pmatrix}. \end{align*} $$