Also available at http://amc.imfm.si ISSN 1855-3966 (printed edn.), ISSN 1855-3974 (electronic edn.) ARS MATHEMATICA CONTEMPORANEA 3 (2010) 165–175 A new construction for symmetric (4, 6)-configurations Leah Wrenn Berman ∗ Department of Mathematics & Statistics, University of Alaska Fairbanks Fairbanks, Alaska, USA Nadine Alise Burtt Department of Mathematics, University of Pittsburgh Pittsburgh, Pennsylvania, USA Received 16 November 2009, accepted 25 August 2010, published online 5 November 2010 Abstract Geometric (4, 6)-configurations are collections of points and straight lines, in the Eu- clidean plane, so that every point has four lines passing through it and every line has six points lying on it. In this paper, we present a new construction for (4, 6)-configurations which have high degrees of geometric symmetry, by superimposing 4-astral 4-configurations with certain properties. Keywords: Configurations, incidence geometry, symmetry. Math. Subj. Class.: 51E30, 05B30 1 Introduction A geometric (q, k)-configuration is a collection of points and straight lines in the Euclidean plane, so that every point lies on q lines and every line passes through k points; if q = k, we simply refer to k-configurations. If the number of points p and lines n is relevant to the discussion, we refer to a (pq, nk) configuration. We say that a (q, k)-configuration is symmetric if, under rotations and reflections of the plane mapping the configuration to itself, there are fewer symmetry classes of points than the number of points in the con- figuration, and similarly for lines: configurations that are highly symmetric have a small number of symmetry classes of points and lines. The modern study of geometric config- urations began about 20 years ago, with the discovery by Grünbaum and Rigby [13] of a ∗Corresponding author. E-mail addresses: lwberman@alaska.edu (Leah Wrenn Berman), naburtt@gmail.com (Nadine Alise Burtt) Copyright c© 2010 DMFA Slovenije 166 Ars Math. Contemp. 3 (2010) 165–175 highly symmetric drawing of a (214) configuration with three symmetry classes of points and lines; since then, there has been considerable work investigating 4-configurations with various properties (see, e.g., [5, 4, 6, 1, 7, 8, 11]). However, there has been relatively little investigation of configurations where q and k are not equal and [q, k] 6= [3, 4], al- though there are a few results in [3, 2], in a very constrained situation, where the config- urations have as much symmetry as possible, and there are some results in Grünbaum’s recent monograph on configurations [12, Section 4.4]. The current work presents a general method of constructing (4, 6)-configurations with four symmetry classes of lines and six symmetry classes of points, using as building blocks a reasonably well-understood class of 4-configurations called 4-astral configurations. Note that two examples of the type of (4, 6)-configurations discussed in this paper were presented without discussion in [12, Fig- ures 4.4.8 and 4.4.10(b)]. 2 Multiastral 4-configurations To construct (4, 6)-configurations, we will use multiastral—specifically 4-astral—4-confi- gurations as building blocks. These configurations have been studied fairly extensively (see e.g., [4, 7, 11, 12]; in [7] they were called polycyclic and in [4, 6] they were called celestial. The current termiology is that used in Branko Grünbaum’s recent monograph on configu- rations [12, Sections 1.5, 3.5–3.9]; the following discussion of multiastral configurations is adapted from that source as well, along with his survey article [11] and the first author’s article [4]. A multiastral 4-configuration is a collection of points and straight lines in the Euclidean plane so that every point has four lines, from each of two symmetry classes, passing through it. Moreover, every symmetry class of points has the same number of points, say m, in it, and the points in each symmetry class form concentric regular m-gons. The symmetry group of the entire configuration is dm, and every line contains two points from each of two m-gons. Multiastral 4-configurations are a generalization of astral 4-configurations, which are 4-configurations with precisely two symmetry classes of points and two symme- try classes of lines (see, e.g., [1, 12, 10, 9]). A 3-astral configuration is shown in Figure 1. Multiastral configurations with h symmetry classes of points and lines are called h- astral, and every h-astral configuration may be described by a configuration symbol of the form m#(s1, t1; s2, t2; . . . ; sh, th), where there are m points in each symmetry class of points and m lines in each symmetry class of lines. Using a configuration symbol, it is possible to construct a configuration uniquely (although several different configuration symbols may correspond to the same geometric configuration, depending on a choice of labelling). In order for a configuration symbol to be valid, it must satisfy four axioms (see [11, Section 3.5] for details). Axiom 1: h∑ i=1 si + ti is even Axiom 2: si 6= ti 6= si+1 for i = 1, . . . , h− 1 and, additionally, sh 6= th 6= s1 Axiom 3: ∏ cos(siπ/m) = ∏ cos(tiπ/m) L. W. Berman and N. A. Burtt: A new construction for symmetric (4, 6)-configurations 167 Figure 1: The 3-astral 4-configuration 9#(3, 1; 2, 3; 1, 2). Lines L0 and points v0 are blue, lines L1 and points v1 are red, and lines L2 and points v2 are green. Axiom 4: No proper subsequence (si, ti, si+1, ti+1, ..., sj) generates a valid configuration symbol m#(si, ti; si+1, ti+1; ...; sj , t∗) that satisfies Axioms 1 – 3, where 1 ≤ t∗ < m2 . A set of lines ` = {`0, `1, . . . , `m−1} is of span s with respect to a set of vertices {v0, v1, ..., vm−1} forming a regular m-gon if `i connects vi and vi+s, with indices taken modulo m. Given a set of lines ` of span s, the t-th intersections of those lines, collectively labelled (s//t) (also referred to as [[s, t]] in, e.g., [4, 6]), is found by starting at the “mid- point” of `0 (that is, the foot of the perpendicular line to `0 that passes through the center of the configuration) and counting leftward through t intersections of the lines ` with each other; see Figure 2. Given an m-gon and a set of lines of span s, allowable values for t are integers from 1 to m2 . Given a valid configuration symbol C = m#(s1, t1; s2, t2; ...; sh, th), the construction method to produce the configuration is as follows (adapted from the algorithm in [4]). Step 1: Begin with m points forming the vertices of a regular m-gon. Collectively, these vertices will be referred to as (vC)0. Typically, these vertices have coordinates( cos ( 2πi m ) , sin ( 2πi m )) for i = 0, 1, . . . ,m− 1. Step 2: Construct lines collectively known as (LC)0 of span s1 that connect these vertices. Step 3: Construct the t1-st intersections of the lines (LC)0 and call them (vC)1; they have symbol (s1//t1). 168 Ars Math. Contemp. 3 (2010) 165–175 Hs1L Hs2L Hs3L Hs4L Hs5L Figure 2: Lines of span s with respect to points v0 and other intersections of the span s lines, labelled (s//t). Here, m = 12, s = 3 and t = 1, 2, 3, 4, 5. The points v0 are shown in blue. O A B B' C x Figure 3: Determining the radius of a point with label C = (s//t) with respect to a regular convex m-gon with radius r. Since the blue lines are of span s, point B′ has coordinates (cos(2sπ/m), sin(2sπ/m)), so ∠BOA = sπm , where A is the foot of the perpendicular from the center O to the line BB′. If OB = r, then since cos(∠AOB) = OAOB , it follows that OA = r cos(sπ/m). Since C, which has label (s//t), is the t-th intersection of the span s lines, ∠AOC = tπm . Therefore, cos(∠AOC) = OA OC , so OC = r · cos(sπ/m) cos(tπ/m) . In the diagram, m = 7, s = 3 and t = 2. L. W. Berman and N. A. Burtt: A new construction for symmetric (4, 6)-configurations 169 Step 4: For i = 1, . . . , h−1, iteratively repeat the previous two steps: using vertices (vC)i, construct lines Li of span si+1, and let (vC)i+1 be the ti+1-st intersections of the lines Li, with label (si+1//ti+1). Because the symbol is valid, the points (vC)h must coincide with the original m points labelled (vC)0. The C subscripts may be dropped when the configuration that vi and Li refer to is either unambiguous or irrelevant. Adapting the discussion in [6], we say that a ray of an h-astral configuration is a diame- tral ray of the configuration if it emanates from the center of symmetry of the configuration (conventionally taken to be the origin) and passes through a point from the set v0. A ray is a mid-diametral ray if it is the rotation by an angle of πm of some diameter. If diametral rays can pass through a class of points, that class is said to be diametral or of type D, and likewise if mid-diametral rays can pass through the points they are said to be mid-diametral or of type MD. (In a typical configuration centered at the origin with one vertex in v0 lo- cated at (1, 0), diametral points have angle πim with i even, while mid-diametral points have angle πim for odd i.) If there are two classes of points and they both are diametral or both are mid-diametral, the classes of points are the same type. In Figure 1, the points v0 and v1 (blue and red) are type D, and thus of the same type, while the points v2 are type MD. In our construction of (4, 6)-configurations, it is useful to be able to determine the radius of the circumcircles passing through the regular m-gons formed by the vertices vi (the “radius of the vi”). Using elementary trigonometry, the radius of a point with label (s//t) with respect to a regular convex m-gon of radius r is r · cos ( sπ m ) cos ( tiπ m ) ; see Figure 3. Let ri be the radius of vertices with label vi, and suppose r0 = 1. Because of the iterative nature of the construction of h-astral configurations, the radius rj = j∏ i=1 cos ( siπ m ) cos ( tiπ m ) . Note that we take Axiom 3 as a necessary condition for the existence of a valid configura- tion because of the convention that r0 = 1, the requirement that v0 = vh, and using this value for rh. Often, h-astral configurations are classified by considering the cohort symbolm#S;T , where S = {s1, . . . , sh} and T = {t1, . . . , th}. Trivial h-astral configurations are those where S = T (as sets); Axioms 1 and 3 are satisfied without need for computation. Sys- tematic h-astral configurations are those where S 6= T , but the values of S and T are determined by dependence on distinct parameters. Sporadic h-astral configurations are neither trivial nor systematic. 3 Constructing symmetric (4, 6)-configurations Consider the trivial 4-astral configuration shown in Figure 4. This configuration consists of four symmetry classes of points and four symmetry classes of lines, with four points, two of each of two colors, on each line. However, there are extra four-valent intersections formed 170 Ars Math. Contemp. 3 (2010) 165–175 by the intersection of some of the lines: specifically, the blue and green lines (lines L0 and L2) and the red and magenta lines (lines L1 and L3) intersect two at a time. Adding these additional points would form a (4, 6)-configuration: each point would still have four lines passing through it, but each line would now have six points, from each of three symmetry classes, lying on it. We can further analyze this example by realizing that the (4, 6)-configuration thus formed may be considered as being constructed from two separate 4-astral configurations, which have the same sets of lines (although different labels), and the same points v0 and v2, but different points v1 and v3. Figure 5 shows such a situation: here the points v0 and v3, colored blue and green respectively, are the same in both configurations, and as sets the lines of the two configurations are the same as well, although the colors are switched. Definition 3.1. Two h-astral configurations X and Y are superimposable if they have the same sets of lines, geometrically, and the incidence structure formed from those lines and the collection of points from both configurations is a (4, 6)-configuration. The superimposibility of 9#(3, 1; 4, 2; 1, 3; 2, 4) and 9#(3, 2; 4, 1; 2, 3; 1, 4) is not co- incidental: in fact, there are infinitely many such pairs of superimposable configurations. To prove this, we will show that a particular pair of configurations X and Y is superim- posable, by showing that they have the same set of lines and that the points (vX )0 = (vY)0 and (vX )2 = (vY)2. To do this, we will need the following lemma, slightly restated from [6, Lemma 1]: Lemma 3.2. For a given i, if si ≡ ti mod 2, the points labelled vi, with symbol (si//ti), are the same type as the points labelled vi−1 (that is, (si−1//ti−1)), with indices taken modulo h; if si 6≡ ti mod 2, then the points vi and vi−1 are of opposite type. Theorem 3.3. Let X and Y be valid configurations with symbols X = m#(a, x1;x2, d; b, x3;x4, c) and Y = m#(a, y1; y2, b; d, y3; y4, c). If cos(x2π/m) cos(x1π/m) cos(dπ/m) = cos(y2π/m) cos(y1π/m) cos(bπ/m) (3.1) and x1 + x2 + y1 + y2 + d+ b is even, (3.2) then X and Y are superimposable. Proof. Suppose that x1 + x2 + y1 + y2 + d+ b is even and cos(x2π/m) cos(x1π/m) cos(dπ/m) = cos(y2π/m) cos(y1π/m) cos(bπ/m) . Let (vX )0 = (vY)0 = v0 be the set of points with coordinates( cos ( 2πi m ) , sin ( 2πi m )) for i = 0, 1, . . . ,m− 1. By the choice of symbol, (vX )0 and (vY)0 have lines of the same spans passing through them: that is, (LX )0 = (LY)0 and (LX )3 = (LY)3, which are lines of spans a and c, respectively, with respect to the points v0. L. W. Berman and N. A. Burtt: A new construction for symmetric (4, 6)-configurations 171 Figure 4: LHS: The trivial 4-astral (544, 366) configuration 9#(3, 1; 4, 2; 1, 3; 2, 4). There are additional four-valent intersections between the lines, specifically blue-green and red- magenta intersections, which are not points of the configuration; these are highlighted by the gray circles. RHS: Adding in the additional intersection points leads to a (4, 6)- configuration; the additional points are black and cyan. With different coloring, this con- figuration is shown as Figure 4.4.10 in [12]. Figure 5: The two superimposable configurations which when combined form the (4, 6)- configuration shown in the right-hand side of Figure 4. LHS: 9#(3, 1; 4, 2; 1, 3; 2, 4); RHS: 9#(3, 2; 4, 1; 2, 3; 1, 4). 172 Ars Math. Contemp. 3 (2010) 165–175 Figure 6: A (4, 6)-configuration formed from the nontrivial superimposable pair 12#(4, 2; 4, 3; 2, 5; 3, 1) and 12#(4, 3; 4, 2; 3, 5; 2, 1). Figure 7: A (5, 6)-configuration formed by adding diameters to the superpo- sition of 13#(5, 3; 4, 1; 3, 5; 1, 4) (blue, red, green, and magenta points) and 13#(5, 1; 4, 3; 1, 5; 3, 4) (blue, yellow, green, and cyan points). L. W. Berman and N. A. Burtt: A new construction for symmetric (4, 6)-configurations 173 Note that, again by the choice of symbol, the points (vX )2 have lines (LX )2 of span d and (LX )1 of span c passing through them; similarly, the points (vY)2 have lines (LY)2 of span d and (LY)1 of span c passing through them. Therefore, to show that X and Y are superimposable, it suffices to show that (vX )2 is the same set of points, geometrically, as (vY)2, which we will do by showing that they are of the same type and have the same radius. Lemma 3.2 states that vi−1 and vi are of the same type if si and ti have the same parity; that is, when si + ti is even. Following the type changes through the symbol, if (vX )2 and (vY)2 are of the same type, then a+ x1 + x2 + d and a+ y1 + y2 + b must have the same parity, since (vX )0 = (vY)0. Since we assumed that x1 + x2 + y1 + y2 + d+ b is even, it follows that (vX )2 and (vY)2 are of the same type. Now, let (rX )i and (rY)i be the radii of (vX )i and (vY)i respectively. By construction, (rX )0 = (rY)0 = 1. Then (rX )2 = (rX )1 · cos(x2π/m) cos(dπ/m) = cos(aπ/m) cos(x2π/m) cos(x1π/m) cos(dπ/m) and (rY)2 = (rY)1 · cos(y2π/m) cos(bπ/m) = cos(aπ/m) cos(y2π/m) cos(y1π/m) cos(bπ/m) . Since we assumed that cos(x2π/m) cos(x1π/m) cos(dπ/m) = cos(y2π/m) cos(y1π/m) cos(bπ/m) , it follows that (rX )2 = (rY)2, as desired. Corollary 3.4. Superimposable configurations X = m#(a, x1;x2, d; b, x3;x4, c) and Y = m#(a, y1; y2, b; d, y3; y4, c) satisfy cos(bπ/m) cos(x4π/m) cos(x3π/m) = cos(dπ/m) cos(y4π/m) cos(y3π/m) . (3.3) Proof. Since X and Y are both valid configurations, the radius r4 for each configuration must equal 1, because v4 = v0. Since X and Y are superimposable, (vX )2 ≡ (vY)2; call the common radius r. Then (rX )4 = r · cos ( bπ m ) cos ( x3π m ) · cos (x4πm ) cos ( cπ m ) and (rY)4 = r · cos ( dπ m ) cos ( y3π m ) · cos (y4πm ) cos ( cπ m ) . Since (rX )4 = (rY)4 = 1, the result follows. 174 Ars Math. Contemp. 3 (2010) 165–175 One very nice class of pairs of superimposable configurations are the trivial pairs X = m#(a, b; c, d; b, a; d, c) and Y = m#(a, d; c, b; d, a; b, c); these trivially satisfy Theorem 3.3. Figure 5 shows such a trivial pair. Figure 6 shows a (4, 6)-configuration formed from the nontrivial pair 12#(4, 2; 4, 3; 2, 5; 3, 1) and 12#(4, 3; 4, 2; 3, 5; 2, 1). 4 Generalizations and open questions Given a (4, 6)-configuration with three symmetry classes of points of one type and three of the other type, it is possible to construct symmetric (5, 6)-configurations by adding diame- ters; an example of such a configuration is shown in Figure 7. In particular, consider a superimposable pair of trivial configurations X = m#(a, b; c, d; b, a; d, c) and Y = m#(a, d; c, b; d, a; b, c). Suppose that a, b, d are of the same parity and c is of the opposite parity to a, b, d. Applying Lemma 3.2 several times, we conclude that (vX )0 = (vY)0 are type D, (vX )1 and (vY)1 are type D, since a ≡ b ≡ d mod 2, (vX )2 = (vY)2 is of type MD, since c 6≡ b mod 2 and c 6≡ d mod 2, and (vX )3 and (vY)3 are both of type MD, since a ≡ b ≡ d mod 2. Thus, in the superimposed (4, 6)- configuration, there are three classes of points of type D, namely (vX )0, (vX )1 and (vY)1, and three classes of points of type MD, (vX )2, (vX )3, and (vY)3, so if diameters (that is, lines connecting the origin and points in v0) are added to the configuration, each diameter will pass through six points. There are several interesting ways to generalize the notion of superimposibility. For example, consider two configurations to be superimposable if they • share the same point sets, but different line sets, but combine into some (q, k)- configuration • Have different point and line sets, but still combine to form a (q, k)-configuration Clearly, the (6, 4)-configurations formed as the polars of the (4, 6)-configurations con- structed above may be analyzed as being formed from two superimposable 4-astral config- urations which share the same point sets but different line sets. Question 1. A 4-astral configuration cohortm#S;T is reducible if S = {x1, x2, i, j} and T = {y1, y2, i, j} and m#S′;T ′ is a valid 2-astral configuration, where S′ = {x1, x2} and T ′ = {y1, y2}. So far, the only known nontrivial superimposable pairs are reducible (for example, the configurations which superimpose to form the (4, 6)-configuration in Fig- ure 6 both reduce to the configuration cohort 12#{4, 4}; {5, 1}.) Are there nonreducible pairs of superimposable 4-astral configurations? Question 2. Are there other interesting configurations which can be formed by superposi- tion, perhaps using h-astral configurations for h > 4? Question 3. Is it possible to construct interesting configurations by superimposing more than two configurations? Question 4. Is it possible to construct 6-configurations by superimposing multiple (4, 6)- or (6, 4)-configurations? L. W. Berman and N. A. Burtt: A new construction for symmetric (4, 6)-configurations 175 5 Acknowledgements The authors are grateful to the Ursinus College Summer Fellows program for providing support for this research. References [1] L. W. Berman, A characterization of astral (n4) configurations, Disc. Comp. Geom. 26 (2001), 603–612. [2] L. W. Berman, Even astral configurations, Electron. J. Combin. 11 (2004), #R37. [3] L. W. Berman, Some results on odd astral configurations. Electron. J. Combin. 13 (2006), #R27. [4] L. W. Berman, Movable (n4) Configurations, Electron. J. Combin. 13 (2006), #R104. [5] L. W. Berman, J. Bokowski, B. Grünbaum and T. Pisanski. Geometric “floral” configurations, Canadian Math. Bull. 52 (2009), 327–341. [6] L. W. Berman and B. Grünbaum, Deletion Constructions of Symmetric 4-Configurations, Part I, Contrib. Disc. Math. 5 (2010). [7] M. Boben and T. Pisanski, Polycyclic configurations, European J. Combin. 24 (2003), 431– 457. [8] J. Bokowski, B. Grünbaum and L. 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