This research studies the chromatic numbers of the suborbital graphs for the modular group and the extended modular group. We verify that the chromatic numbers of the graphs are 2 or 3. The forest conditions of the graphs for the extended modular group are also described in this paper.
Chiang Mai UniversityThailand Research Fund1. Introduction
Graph coloring is a special case of graph labeling which assigns labels to all vertices or edges of a given graph. In this special case, the labels are called colors. Vertex coloring is the study of how many colors can be assigned to the vertices of a graph verifying that no adjacent vertices are equally colored. Similarly, edge coloring assigns colors to edges of a graph that the same color cannot be painted to edges which have a common vertex.
The graph which can be assigned k colors on its vertices is said to be k-colorable. If k is the smallest number of colors, the graph is said to be k-chromatic and k is called the chromatic number of the graph. In the case of edges, we add the word “edge” to the terminologies, for example, k-edge-colorable, k-edge-chromatic, and edge chromatic number.
This paper studies coloring of suborbital graphs for the modular group and the extended modular group. The results of edge coloring are trivial, so we focus on vertex coloring. This study is separated into two parts in Sections 3 and 4. In Section 3, we provide the coloring results of the directed graph Gu,n, the suborbital graph for the modular group Γ. The graph was first constructed in [1] using the general concept introduced by Sims; see more in [2]. The authors showed that Gu,n was the disjoint union of isomorphic copies of their special subgraph Fu,n, the generalized Farey graph, coming from the use of the subgroup Γ0(n) of Γ. Then many properties of Gu,n were investigated through the studies on Fu,n. Certainly, vertex coloring of Gu,n is also examined through the study on Fu,n.
In 2013, the concept of suborbital graphs continued to the extended modular group Γ^, as in [3]. The notations are defined likewise. That is, G^u,n denotes the suborbital graph for the extended modular group Γ^, and F^u,n is a special subgraph of G^u,n coming from the subgroup Γ^0(n) of Γ^. Certainly, G^u,n is the disjoint union of isomorphic copies of F^u,n. The vertex coloring results of this case are described in Section 4. The forest conditions for the graph F^u,n, which are necessary in vertex coloring, are also studied in this section.
Note that the graph in the context of coloring is loopless. Thus, coloring of the suborbital graphs with loops will not be mentioned.
2. Preliminaries
In this section, we provide some necessary backgrounds used in coloring. Some backgrounds of suborbital graphs may not be mentioned in this research. We start this section with the definition of the modular group. The modular group Γ is the projective special linear group PSL(2,Z), the group of 2×2 matrices of unit determinant with integer coefficients such that every matrix A is identified with its negative -A. Therefore, Γ is the quotient of the special linear group SL(2,Z) by its center {±I}, where I is the identity matrix of order 2. In other words, the elements of PSL(2,Z) are represented by the pairs of matrices ±abcd, where a,b,c,d∈Z and ad-bc=1. We usually leave out the signs of the representations for convenience.
From another point of view, the group Γ may be presented as a group of transformations. In this manner, it is the group of linear fractional transformations on H2={z∈C:Im(z)>0} where the composition of functions is the group operation. Certainly, the group in this manner and PSL(2,Z) are isomorphic. In other words, PSL(2,Z) is considered as a group acting on H2 by linear fractional transformation, that is,(1)abcd·z⟼az+bcz+d,where z∈H2 and abcd∈PSL(2,Z). This action can be also extended to the set Q^=Q∪{∞} as follows: (2)abcd·xy⟼ax+bycx+dy,where x/y is an irreducible fraction representing an element of Q^. In this case, ∞ is represented by -1/0 and 1/0. Certainly, the fractions representing the elements of Q^ are not unique since x/y=-x/-y. However, it does not affect the action of Γ on Q^. Notice that the action of Γ on Q^ is transitive; that is, Q^ has only one orbit under the action of Γ.
The extended modular group Γ^ is a group generated by Γ and the hyperbolic reflection z↦-z¯. In the forms of matrix representations, Γ^=〈Γ,100-1〉, that is,(3)Γ^=abcd:a,b,c,d∈Z,ad-bc=±1.On the set Q^, the complex conjugate is ineffective. Then the action of Γ^ on Q^ is the same as that of the group Γ.
In [1], a suborbital graph for Γ on Q^ was established. The vertex set is defined to be the set Q^. The set of directed edges depends on a pair v,w∈Q^. It is defined to be the orbit Γ(v,w)={γ(v,w)=(γ(v),γ(w)):γ∈Γ} where the action of Γ on the Cartesian Q^×Q^ is the component-wise action extended from that on Q^. In this research, we let v1→v2 denote a directed edge from v1 to v2; that is, there exists the edge v1→v2 of the graph if (v1,v2)∈Γ(v,w). Since Γ acts on Q^ transitively, there is an element γ∈Γ such that γ(v)=∞. Certainly, γ(w)∈Q^, so it can be represented as a reduced fraction u/n with nonnegative denominator. This implies that (∞,u/n)=γ(v,w)∈Γ(v,w). Hence Γ(∞,u/n)=Γ(v,w). Then the suborbital graph is simply denoted by Gu,n. The case n=0 is the case of trivial suborbital graphs. There is one loop at every vertex. The coloring of this case will not be mentioned. In the case n≥1, edges of the graph are defined to be the upper half-circles and the vertical half-lines in H2 joining elements of Q^; see Figure 1 for examples. In this case, the graph Fu,n is determined. It is a restriction of Gu,n on the orbit (Γ0(n))(∞), where Γ0(n) is a congruence subgroup of Γ defined by (4)Γ0n=abcd∈Γ:c≡0modn.Note that (Γ0(n))(∞)={x/y∈Q^:y≡0modn}. In fact, Fu,n is a suborbital graph for Γ0(n) on (Γ0(n))(∞). The following remark is the result obtained directly after constructing the Γ-invariant equivalence relation related to Γ0(n); see more details in [1].
Example of edges of Gu,n.
Remark 1.
Gu,n is the disjoint union of m=|Γ:Γ0(n)| isomorphic copies of Fu,n, where |Γ:Γ0(n)| is the index of the subgroup Γ0(n) in the group Γ.
In the case n=1, we have G1,1=F1,1. This graph is called the Farey graph and denoted by F. We see that Γ contains 1b01, b∈Z, a translation along the real axis. Then Fu,1=Gu,1=G1,1 for every u∈Z.
Likewise, in [3], the author used the notation G^u,n to denote the suborbital graph for Γ^ on Q^, and F^u,n is the subgraph of G^u,n on the orbit (Γ^0(n))(∞) where Γ^0(n) is a subgroup of Γ^ determined by(5)Γ^0n=abcd∈Γ^:c≡0modn.Certainly, Γ^0(n)=〈Γ0(n),100-1〉. Then (Γ^0(n))(∞)={x/y∈Q^:y≡0modn}. Remark 1 is also true for this version.
Next, we introduce other necessary definitions used in this research. A path in a directed graph is a finite or infinite sequence of different vertices such that every two successive vertices in the sequence are adjacent in the graph. In the finite case, a path is said to be finite. The initial vertex and the final vertex of a finite path are allowed to be equal. For the infinite case, we consider only a path containing the initial vertex. This path is said to be semi-infinite. We use the notations v1→v2→⋯→vm and v1→v2→v3→⋯ to denote finite and semi-infinite paths with the initial vertex v1, respectively. Note that some arrows in the notations may be reversed.
If the initial vertex and the final vertex of a finite path are equal, we say that the path is closed. A closed path consisting of m≥3 vertices is called a circuit. If m=3, a circuit is called a triangle. We distinguish triangles into two families with respect to the directions of edges. A triangle of the form v1→v2→v3→v1 is said to be directed. If a triangle contains two edges of opposite directions, for instance, v1→v2←v3→v1, we call it anti-directed. The graph is called a forest if it contains no loops and circuits.
The following proposition shows that there are a countably infinite number of colors to be assigned on the edges of the graphs Fu,n, Gu,n, F^u,n, and G^u,n. This is due to the fact that there are infinitely many edges incident to the vertex ∞ by translations in the underline groups. We elaborate this in the detail of the proof. In this case, we say that the graphs are ℵ0-edge-chromatic.
Proposition 2.
Fu,n, Gu,n, F^u,n, and G^u,n are ℵ0-edge-chromatic.
Proof.
We know that Γ and Γ^ contain all translations γk:z↦z+k, where k∈Z. Then there are infinitely many edges of the graphs Gu,n and G^u,n incident to ∞, that is, γk(∞→u/n)=∞→u+kn/n, where k∈Z. We can see easily that u+kn/n is also a vertex of Fu,n and F^u,n for every k∈Z. Thus, all edges ∞→u+kn/n also belong to Fu,n and F^u,n. Then we need to paint these all edges by different countable colors. The proof is finally completed because of countability of Q^×Q^.
3. Chromatic Numbers of Suborbital Graphs for the Modular Group
In this section, we provide the vertex coloring results of the graphs Fu,n and Gu,n. We start this section with some useful properties of Fu,n obtained in [1]. We state these properties of the graph Fu,n in the two lemmas below. The first one provides the results of graph isomorphism. The second describes the relation between edge conditions of the Farey graph F and the Farey sequences. Notice that the Farey sequence of order m≥1, denoted by Fm, is a sequence of reduced fractions x/y∈Q sorted in increasing order where |y|≤m.
Lemma 3.
(1) Fu,n is isomorphic to F-u,n by the mapping v↦-v. (2) If m∣n, Fu,n is isomorphic to a subgraph of Fu,m by the mapping v↦nv/m.
Lemma 4.
Let r/s,x/y∈Q. Then the three conditions below are equivalent:
The fractions are adjacent vertices in F.
ry-sx=±1.
The fractions are consecutive terms in the Farey sequence Fm for some m.
From [1, Theorem 5.1], we know that Fu,n contains directed triangles if and only if u2±u+1≡0modn and contains anti-directed triangles only for n=1. Therefore, Fu,n contains triangles if and only if u2±u+1≡0modn. Surprisingly, by considering triangles of the graph, we can check whether the graph is a forest or not. In [4], the author proved that Gu,n is a forest if and only if it contains no triangles. The author proved it through the subgraph Fu,n but concluded for Gu,n by using Remark 1. In this paper, we prefer to write it in the version of Fu,n which is more useful in our work.
Lemma 5.
Fu,n is a forest if and only if it contains no triangles; that is, u2±u+1≢0modn.
Considering the second result of Lemma 3, we see that every graph Fu,n can be embedded as a subgraph of F. Thus, we will study the Farey graph F first and then apply the result to the general case. Now, consider the Farey graph. We know that F1,1 and F-1,1 are identical. Then the first result of Lemma 3 implies that F is symmetric with respect to the imaginary axis; see Figure 2. Moreover, the graph is periodic with period one along the real axis. This is a consequence of the fact that Γ contains the translation z↦z+1. Thus, we first paint vertices of the graph in the interval [0,1] and then use the reflection and translations to assign colors to the whole graph.
Farey graph F.
To paint the vertices of F in the interval [0,1], we need to introduce the well-known notion, the Farey tree whose vertices form the set of all rationals in [0,1]. All vertices of the tree can be constructed by using the mediants of fractions. Let r/s, x/y be a pair of fractions, called parents. Their mediant is the fraction given by r+x/s+y, called a child. The following remark includes some facts of the fractions and their mediants used to construct the vertex set of the Farey tree. Its edges will not be mentioned in this paper; see more in [5–7] about the Farey tree.
Remark 6.
(1) If r/s≤x/y and s,y>0, then r/s≤r+x/s+y≤x/y. (2) If rx-sy=±1, then the fractions r/s, x/y and their mediant r+x/s+y are reduced.
We are now ready to talk more about the vertex set of the Farey tree. The notations are followed from [7]. Let FT1=Q1=0/1,1/1. For every n≥2, FTn and Qn are constructed inductively; that is, Qn is the set of all mediants of every two consecutive fractions in FTn-1, and let FTn=FTn-1∪Qn written as the set of fractions sorted in increasing order. Qn is called the set of Farey fractions of level n. By this method, we finally obtain the vertex set ⋃n≥0FTn=Q∩[0,1] of the Farey tree; see [8, Lemma 2.4]. The following result is a consequence of the preceding remark closely related to Lemma 4.
Remark 7.
For each n∈N, every pair of successive fractions r/s and x/y in FTn satisfies the identity ry-sx=±1, so they are all reduced.
We see that a child is adjacent to its parents in the Farey graph F. When a child appears, it always lies between their parents. Then a child in Qn and nonparents in FTn are certainly not consecutive terms in the Farey sequence Fm for every m∈N. We apply this fact to Lemma 4, so they are not adjacent vertices in the graph F. We are now ready to prove the theorem.
Theorem 8.
The Farey graph F is 3-chromatic.
Proof.
From the discussion above, we first consider the graph on the strip 0≤Re(z)≤1. We start with Q1 and then color every vertex level by level. Obviously, the vertices ∞, 0, and 1 are adjacent to one another. Thus, we paint them by different colors c1, c2, and c3, respectively. One can check that there is not any vertex of F in (0,1) adjacent to ∞. We then go to the next level Q2=1/2 and paint the vertex 1/2 by the color c1. We now obtain that three consecutive vertices in FT2={0,1/2,1} are painted by three different colors, c2, c1, c3, respectively. For the next level Q3, we can color each vertex by the one remaining color different from those of its parents in FT2. Continue this process inductively, so all vertices of F in the interval [0,1] will be painted by only the three colors c1, c2, and c3. After that we extend the color labels to other vertices of the graph in the interval [-1,0) by the reflection across the imaginary axis and then extend to the whole graph by using the translations z→z+2k where k∈Z.
The next three corollaries are results for the graphs Fu,n and Gu,n. The first one is obtained by combining Lemma 3 with the previous theorem. The lemma implies that Fu,n is isomorphic to a subgraph of F which is 3-chromatic. Therefore, we have the following.
Corollary 9.
Fu,n is 3-colorable.
The first result in the next corollary occurs when the graph Fu,n is a forest. The other case is obtained from that the graph contains triangles together with the preceding corollary.
Corollary 10.
Let χ be the chromatic number of Fu,n; then,
χ=2 if u2±u+1≢0modn,
χ=3 if u2±u+1≡0modn.
Since Gu,n is the union of isomorphic copies of Fu,n, we obtain the results on the chromatic numbers for Gu,n as follows.
Corollary 11.
Let χ be the chromatic number of Gu,n; then,
χ=2 if u2±u+1≢0modn,
χ=3 if u2±u+1≡0modn.
4. Chromatic Numbers of Suborbital Graphs for the Extended Modular Group
This section provides the vertex coloring results for graphs F^u,n and G^u,n. Two lemmas below, edge conditions for Fu,n and F^u,n, are the useful results obtained in [1] and [3], respectively. They provide the relation between Fu,n and F^u,n that we can use to extend the results from the previous section.
Lemma 12.
There is an edge r/s→x/y in Fu,n if and only if
x≡urmodn and ry-sx=n,
x≡-urmodn and ry-sx=-n.
Lemma 13.
There is an edge r/s→x/y in F^u,n if and only if one of the following conditions is true:
x≡urmodn and ry-sx=n.
x≡-urmodn and ry-sx=-n.
x≡urmodn and ry-sx=-n.
x≡-urmodn and ry-sx=n.
We see that the first two conditions of Lemma 13 are edge conditions for Fu,n and the others are for F-u,n. Thus, the graph F^u,n seems to be the union of the graphs Fu,n and F-u,n. In this case, the edge set of F^u,n is the union, in the context of sets, of the edge sets of those two graphs. That is, r/s→x/y is an edge of F^u,n if and only if r/s→x/y is an edge of Fu,n or F-u,n. We know from [4, Lemma 1] that, for every n≥1, Gu,n=Gu¯,n if and only if u≡u¯modn. This fact can be applied for Fu,n. Therefore, we obtain the following proposition immediately.
Proposition 14.
If u≡u¯modn, then F^u,n=F^u¯,n.
Further, the isomorphism results of Fu,n, see Lemma 3, can be extended directly to the case of F^u,n.
Proposition 15.
(1) F^u,n is isomorphic to F^-u,n by the mapping v↦-v. In fact, F^u,n=F^-u,n. (2) If m∣n, F^u,n is isomorphic to a subgraph of F^u,m by the mapping v↦nv/m.
At this point, it is not difficult to see that F^u,1=F^1,1. Since F1,1=F-1,1, F^u,1 is actually the Farey graph F. As we introduce in Section 2, all vertices of a suborbital graph in this study are on the real axis of the complex plane, and edges are represented by upper half-circles or the vertical half-line in H2 joining two reduced fractions in Q^. We say that two edges of the graph cross in H2 if they meet in H2 in this representation. By [1, Corollary 4.2], there are not edges of the Farey graph F crossing in H2. Then, after applying the second result of the preceding proposition, we obtain the following corollary immediately.
Corollary 16.
No edges of F^u,n cross in H2.
In the previous section, we showed that F is 3-chromatic. Then the next corollary is also obtained from the second result of the preceding proposition.
Corollary 17.
F^u,n is 3-colorable.
Next, we investigate the chromatic number of F^u,n. From Theorems 5 and 6 of [3], we can conclude that F^u,n contains triangles if and only if u2±u+1≡0modn. In general, a graph with triangles cannot be painted by 2 colors. If F^u,n contains triangles, the previous corollary implies that 3 is the least number of colors which can be assigned to vertices of F^u,n. Therefore, it is 3-chromatic.
Question. What about F^u,n containing no triangles?
We answer this question in Corollary 21. To prove this corollary, we need the following lemmas and theorem, the forest conditions for F^u,n.
Lemma 18.
If u≢±1modn, then there are not adjacent vertices v and w of F^u,n such that v<1/2<w.
Proof.
By the discussion before Proposition 14, we can work on the graph Fu,n instead. Assume that v and w are adjacent vertices of Fu,n such that v<1/2<w. Then, by using Lemma 3, nv and nw are adjacent in F. If n is even, Lemma 12 implies that ∞→n/2 is an edge of F crossing the edge incident to nv and nw. This is a contradiction because no edges of F cross in H2. We then suppose that n is odd. By Lemma 4, nv and nw are consecutive terms in some Farey sequence Fm. Since nv<n/2<nw, we have m=1. This implies that nv=n-1/2 and nw=n+1/2. Then v=(n-1)/2/n and w=(n+1)/2/n. If v→w is an edge of Fu,n, we have by Lemma 12 that (n+1)/2≡-u(n-1)/2modn. Thus, u≡1modn. The other case implies that u≡-1modn. This is a contradiction.
The following lemma is used as a part to prove the forest conditions for Gu,n in [1, Theorem 10]. The function in this lemma will arrive on the proof of our next theorem. For the sake of completeness, we include it here together with our own clarification.
Lemma 19.
Let u,n,k∈R and n≠0. Then the function φ:R∖{u+k/n}→R defined by (6)z⟼uz-u2+ku+1/nnz-u+kis increasing on the interval (-∞,u+k/n) and also increasing on (u+k/n,+∞). Further, φ(u+x/n)<u+1/n whenever 1<k-x.
Proof.
Considering the derivative of φ, dφ/dz=1/(nz-u-k)2>0 for every z∈R∖{u+k/n}. Then φ is increasing on the mentioned intervals. Next, suppose that 1<k-x. Since φ(u+x/n)=u+1/(k-x)/n, we have φ(u+x/n)<u+1/n.
Before the next theorem, we recall the definitions of paired and self-paired suborbital graphs as follows. Let G be a group acting transitively on a nonempty set X. Suppose that G(v,w) and G(w,v) are suborbital graphs for the group G equipped with the orbits G(v,w) and G(w,v) in X×X, respectively. We can see that G(w,v) is just the graph G(v,w) with arrows reversed. We say that the graphs are paired. If G(v,w)=G(w,v), we have G(v,w)=G(w,v). Then the graph consists of pairs of oppositely directed edges. In this case, the graph G(v,w) is called a self-paired suborbital graph. Refer to [3, Corollary 3]; the suborbital graph G^u,n of Γ^ is self-paired if and only if u2≡±1modn. This fact can be applied to F^u,n. Now, we are ready to prove the forest conditions for F^u,n.
Theorem 20.
F^u,n is a forest if and only if it contains no triangles, that is, u2±u+1≢0modn.
Proof.
For every n≤2, we can see that Fu,n=F-u,n, so F^u,n=Fu,n. Thus, this case is clear by Lemma 5. We then assume that n>2. Of course, the forward is trivial, so only the converse needs proof. Suppose that u2±u+1≢0modn. We will show that F^u,n does not contain any circuit. On the contrary, we assume that F^u,n contains a circuit C. Since Γ^0(n) acts transitively on edges of F^u,n, see [3, Theorem 4], we may suppose that C contains the edge ∞→u/n. Further, we can apply Proposition 14 to suppose that 0<u/n<1. By using Proposition 15 with the fact that no edges of F cross in H2, we can show that every vertex of F^u,n in the interval [0,1] is not adjacent to vertices outside the interval except ∞. Then the circuit C lies in the strip 0≤Re(z)≤1.
Case 1. F^u,n is self-paired, that is, u2≡±1modn.
Firstly, we consider the simple case, u2≡1modn. With this condition, [1, Corollary 3.3] implies that Fu,n and F-u,n are paired. They are the same graph but arrows reversed. Thus, F^u,n is a forest if and only if Fu,n is a forest. Therefore, Lemma 5 implies that F^u,n contains no circuits.
In the case u2≡-1modn, we can check easily by using Lemma 13 that u/n and n-u/n are the only two vertices of F^u,n in the interval [0,1] adjacent to ∞. Then the circuit C must contain the vertices u/n and n-u/n. This means that if we leave out the vertex ∞ from C, we obtain a path C-{∞} joining u/n and n-u/n where every vertex in the path is a vertex in the interval [0,1]. We see that u/n and n-u/n are on the different side of the line Re(z)=1/2. Since u≢±1modn, Lemma 18 implies that there are not adjacent vertices of the graph F^u,n belonging in the different sides of the line Re(z)=1/2. 1/2 is not a vertex of F^u,n because n>2. Then the path C-{∞} cannot occur. This is a contradiction. Hence F^u,n has no circuits.
Case 2. F^u,n is not self-paired, that is, u2≢±1modn.
In this case, we can see easily that u≢±1modn, so Lemma 18 can be applied. Further, there are only four vertices of F^u,n inducing four edges in the strip 0≤Re(z)≤1 incident to ∞. We can see that ∞→u/n and u′/n→∞, where 1≡-uu′modn, are two of these four edges belonging to Fu,n. Under the hyperbolic reflection v↦-v¯ and the translation v↦v+1, we obtain the other two edges ∞→n-u/n and n-u′/n→∞ belonging to the graph F-u,n. We separate this case into two subcases. That is, u/n and u′/n are on the same side of the line Re(z)=1/2, and the other case is that they are on the different sides. From Propositions 14 and 15, we know that F^n-u,n=F^-u,n=F^u,n. Then we may assume that u/n<u′/n; if not, we certainly obtain that n-u/n<n-u′/n, so we can consider F^n-u,n instead.
Before proving Case 2, we need to construct a semi-infinite path in F^u,n. Since gcd(u,n)=1, we have ux+ny=1 for some x,y∈Z. Then ux≡1modn, so u2-(ux)(u2+1)+1≡0modn. We can choose a positive integer k<n such that k≡-x(u2+1)modn. Hence u2+ku+1≡0modn. Since F^u,n is not self-paired and does not contain triangles, we have 1<k<n. Now, let(7)φ=-uu2+ku+1n-nu+k.We see that φ∈Γ^0(n) such that φ(∞)=u/n and φ(u+k/n)=∞. Then the edge φ-1(∞→u/n)=u+k/n→∞ belongs to F^u,n. One can show that u′=u+k.
We now let v1=u/n and define vj=φ(vj-1) for every j≥2. By Lemma 19, φ is a strictly increasing function on the interval (-∞,u+k/n) such that φ(u+x/n)<u+1/n for every x<1<k. Then we obtain a strictly increasing sequence vj of vertices of F^u,n in the interval [u/n,u+1/n). Since ∞→u/n is an edge in F^u,n, we obtain the semi-infinite path v1→v2→v3→⋯ contained in F^u,n. From now, if the direction of an edge is not clear, we will use the notation ⇌ to refer to either of the arrows → or ←. We are ready to provide the proof of Case 2.
In the case that u/n and u′/n are on the same side of the line Re(z)=1/2, we obtain that n-u/n and n-u′/n are on the other side. Thus, we obtain by Lemma 18 that the circuit C contains the vertex u′/n and does not contain n-u/n and n-u′/n. Recall that v1=u/n<u′/n=u+k/n. Since C is a circuit containing v1, there are finitely many vertices from the sequence {vj} belonging to the circuit C. Hence there is the greatest integer i such that vi is a vertex in C. Then there is an edge in C incident to vi and another vertex v of F^u,n such that v>vi. By Corollary 16, no edges of F^u,n cross in H2, so vj<v≤u+k/n for every j∈N. If v=u+k/n, we have φ(v)=∞. Then the edge vi⇌v crosses the edge φ(vi)⇌φ(v) in H2. If v<u+k/n, we apply Lemma 19. Since the function φ is strictly increasing on the interval (-∞,u+k/n), we still obtain that the edge vi⇌v crosses the edge φ(vi)⇌φ(v) in H2. This is a contradiction. Therefore, there is no such circuit C.
Next, we prove the remaining case; that is, u/n and u′/n are on the different sides of the line Re(z)=1/2. In this case, we have u/n, n-u′/n<1/2<u′/n, n-u/n. Since un-u′≡-uu′≡1modn, [3, Corollary 2] implies that G^u,n and G^n-u′,n are paired suborbital graphs. Thus, F^u,n and F^n-u′,n are also paired. Hence we may suppose that u/n<n-u′/n; if not, we can prove on the graph Fn-u′,n together with the compatible mapping φ instead. We now have u/n<n-u′/n<1/2<u′/n<n-u/n.
We know that the circuit C contains the edge ∞→u/n. Then Lemma 18 implies that it also contains the vertex n-u′/n. More precisely, it contains the edge n-u′/n→∞. Since the graph F^u,n does not contain triangles, the vertices u/n and n-u′/n are not adjacent. Then there is an edge u/n⇌v of C such that u/n<v<n-u′/n. Next, we consider the path n-u′/n→∞→u/n⇌v in the circuit C. Its image under φ-1 is the path φ-1(n-u′/n)→u′/n→∞⇌φ-1(v) in the circuit φ-1(C). We know that 1/2<u′/n and 1/2 is not a vertex of F^u,n. Then we obtain by Lemma 18 that the circuit φ-1(C) must belong to the right side of the line Re(z)=1/2. Since u′/n and φ-1(v) are adjacent to ∞, Corollary 16 implies that φ-1(n-u′/n) lies between u′/n and φ-1(v). We see that u′/n is the least vertex on the right side of the line Re(z)=1/2 adjacent to ∞. Hence u′/n<φ-1(n-u′/n)<φ-1(v). By Lemma 19, φ is increasing on the interval (u′/n,+∞). This induces a contradiction to the inequality v<n-u′/n, that is, n-u′/n=φφ-1(n-u′/n)<φφ-1(v)=v. Therefore, the circuit C does not exist.
From the proof in Cases 1 and 2, we have shown that if F^u,n does not contain triangles, it does not contain circuits. Consequently, F^u,n is a forest if and only if it contains no triangles.
By the similar reasons used in the case of modular, we obtain the following corollaries immediately. If u2±u+1≢0modn, the previous theorem implies that the graphs become forests. Thus, they are 2-chromatic. If u2±u+1≡0modn, the graphs contain triangles. Then their chromatic numbers are greater than 2. Finally, Corollary 17 guarantees that they are 3-chromatic.
Corollary 21.
Let χ be the chromatic number of F^u,n; then,
χ=2 if u2±u+1≢0modn,
χ=3 if u2±u+1≡0modn.
Corollary 22.
Let χ be the chromatic number of G^u,n; then,
χ=2 if u2±u+1≢0modn,
χ=3 if u2±u+1≡0modn.
Competing Interests
The authors declare that there are no competing interests regarding the publication of this paper.
Acknowledgments
This research was supported by Chiang Mai University and Thailand Research Fund.
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