Proof As $|\Omega _{\alpha ,1}|+|\Omega _{\alpha ,2}|<|\Omega |$ , by (3), we get that $\Omega _{\alpha ,1}\cup \Omega _{\alpha ,2}$ is strictly contained in $\Omega $ . Therefore, let $\beta \in \Omega \setminus (\Omega _{\alpha ,1}\cup \Omega _{\alpha ,2})$ .

Since $\beta \notin \Omega _{\alpha ,1}\cup \Omega _{\alpha ,2}$ and since the action of G on $\Omega $ is transitive, we have

(5) $$ \begin{align} |G_{\alpha}:G_{\alpha}\cap G_{\beta}|=|G_{\beta}:G_{\alpha}\cap G_{\beta}|>2. \end{align} $$

See Figure 1.

Figure 1:

Auxiliary picture for the proof of Lemma 2.1.

From this, we deduce

(6) $$ \begin{align}\Omega_{\alpha,1}\cap \Omega_{\beta,1}=\Omega_{\alpha,2}\cap \Omega_{\beta,1}=\Omega_{\alpha,1}\cap \Omega_{\beta,2}=\emptyset. \end{align} $$

Indeed, if, for instance, $\omega \in \Omega _{\alpha ,1}\cap \Omega _{\beta ,2}$ , then $|\omega ^{G_{\alpha }}|=1$ and $|\omega ^{G_{\beta }}|=2$ . Therefore, $|G_{\alpha }:G_{\alpha }\cap G_{\omega }|=1$ and $|G_{\beta }:G_{\beta }\cap G_{\omega }|=2$ . As $|G_{\alpha }:G_{\alpha }\cap G_{\omega }|=1$ , we get $G_{\alpha }=G_{\omega }$ . Now, as $|G_{\beta }:G_{\beta }\cap G_{\omega }|=2$ and $G_{\alpha }=G_{\omega }$ , we get $2=|G_{\beta }:G_{\beta }\cap G_{\omega }|=|G_{\beta }:G_{\beta }\cap G_{\alpha }|$ , which contradicts (5). Therefore, $\Omega _{\alpha ,1}\cap \Omega _{\beta ,2}=\emptyset $ . The proof for all other equalities in (6) is similar.

From (6), we obtain

(7) $$ \begin{align} (\Omega_{\alpha,1}\cup\Omega_{\alpha,2})\cap (\Omega_{\beta,1}\cup\Omega_{\beta,2})=\Omega_{\alpha,2}\cap\Omega_{\beta,2}. \end{align} $$

Recall that, by hypothesis, $|\Omega _{\alpha ,1}\cup \Omega _{\alpha ,2}|>|\Omega |/2$ . Using this together with (7), we get

(8) $$ \begin{align} |\Omega_{\alpha,2}\cap\Omega_{\beta,2}|&=|(\Omega_{\alpha,1}\cup\Omega_{\alpha,2})\cap (\Omega_{\beta,1}\cup\Omega_{\beta,2})|\\ \nonumber &=|\Omega_{\alpha,1}\cup\Omega_{\alpha,2}|+ |\Omega_{\beta,1}\cup\Omega_{\beta,2}|-|(\Omega_{\alpha,1}\cup\Omega_{\alpha,2})\cup (\Omega_{\beta,1}\cup\Omega_{\beta,2})|\\ \nonumber &\ge |\Omega_{\alpha,1}\cup\Omega_{\alpha,2}|+ |\Omega_{\beta,1}\cup\Omega_{\beta,2}|-|\Omega|\\ \nonumber &>\frac{|\Omega|}{2}+\frac{|\Omega|}{2}-|\Omega|=0. \end{align} $$

From (8), we deduce $\Omega _{\alpha ,2}\cap \Omega _{\beta ,2}\ne \emptyset $ . Let $\omega \in \Omega _{\alpha ,2}\cap \Omega _{\beta ,2}$ . In particular, $|\omega ^{G_{\alpha }}|=|\omega ^{G_{\beta }}|=2$ . This means that $|G_{\alpha }:G_{\alpha }\cap G_{\omega }|=|G_{\beta }:G_{\beta }\cap G_{\omega }|=2$ . Since $|G_{\alpha }|=|G_{\beta }|=|G_{\omega }|$ , we get that $G_{\alpha }\cap G_{\omega }$ and $G_{\beta }\cap G_{\omega }$ have both index $2$ in $G_{\omega }$ . Suppose $G_{\alpha }\cap G_{\omega }=G_{\beta }\cap G_{\omega }$ . Then

$$ \begin{align*}G_{\alpha}\cap G_{\omega}=G_{\beta}\cap G_{\omega}=G_{\alpha}\cap G_{\beta}\cap G_{\omega}\le G_{\alpha}\cap G_{\beta},\end{align*} $$

and hence

$$ \begin{align*}|G_{\alpha}:G_{\alpha}\cap G_{\beta}|\le |G_{\alpha}:G_{\alpha}\cap G_{\omega}|=2.\end{align*} $$

However, this contradicts (5). Therefore, $G_{\alpha }\cap G_{\omega }$ and $G_{\beta }\cap G_{\omega }$ are two distinct subgroups of $G_{\omega }$ having index $2$ . This yields

(9) $$ \begin{align}G_{\omega}=(G_{\alpha}\cap G_{\omega})(G_{\beta}\cap G_{\omega}), \end{align} $$

for each $\omega \in \Omega _{\alpha ,2}\cap \Omega _{\beta ,2}$ .

From (9) and from the fact that $|G_{\omega }:G_{\alpha }\cap G_{\omega }|=|G_{\omega }:G_{\beta }\cap G_{\omega }|=2$ , we see that $(G_{\alpha }\cap G_{\omega })\cap (G_{\beta }\cap G_{\omega })=G_{\alpha }\cap G_{\beta }\cap G_{\omega }$ has index $4$ in $G_{\omega }$ . Since $|G_{\omega }|=|G_{\alpha }|=|G_{\beta }|$ , we get that $G_{\alpha }\cap G_{\beta }\cap G_{\omega }$ has also index $4$ in $G_{\alpha }$ and in $G_{\beta }$ . Since $G_{\alpha }\cap G_{\beta }\cap G_{\omega }\le G_{\alpha }\cap G_{\beta }$ , we get that $|G_{\alpha }:G_{\alpha }\cap G_{\beta }|=|G_{\beta }:G_{\alpha }\cap G_{\beta }|$ divides $|G_{\alpha }:G_{\alpha }\cap G_{\beta }\cap G_{\omega }|=4$ . As $|G_{\alpha }:G_{\alpha }\cap G_{\beta }|=|G_{\beta }:G_{\alpha }\cap G_{\beta }|>2$ , we get $G_{\alpha }\cap G_{\beta }\cap G_{\omega }= G_{\alpha }\cap G_{\beta }$ and

$$ \begin{align*} |G_{\alpha}:G_{\alpha}\cap G_{\beta}|=|G_{\beta}:G_{\alpha}\cap G_{\beta}|=4. \end{align*} $$

We have summarized this paragraph in Figure 2. In other words, $\beta \in \Omega _{\alpha ,4}$ .

Figure 2:

Auxiliary picture for the proof of Lemma 2.1.

Since $\beta $ is an arbitrary element in $\Omega \setminus (\Omega _{\alpha ,1}\cup \Omega _{\alpha ,2})$ , we have proven part (a). Now, as $\Omega _{\alpha ,4}=\Omega \setminus (\Omega _{\alpha ,1}\cup \Omega _{\alpha ,2})$ , part (b) follows from (8) and part (c) follows from (9).

Proof Let $\beta \in \Omega _{\alpha ,4}$ . As $\Omega _{\beta ,1}\subseteq \Omega _{\alpha ,4}$ and as $\Omega _{\beta ,1}$ and $\Omega _{\alpha ,4}$ have the same cardinality, we deduce $\Omega _{\alpha ,4}=\Omega _{\beta ,1}$ . Analogously, $\Omega _{\beta ,4}=\Omega _{\alpha ,1}$ .

Let $g\in G$ with $\beta =\alpha ^g$ . Now, we have

$$ \begin{align*}(\Omega_{\alpha,4})^g=\Omega_{\alpha^g,4}=\Omega_{\beta,4}=\Omega_{\alpha,1}.\end{align*} $$

Analogously, $\Omega _{\alpha ,1}^g=\Omega _{\alpha ,4}$ . So,

$$ \begin{align*} \Omega_{\alpha,1}^g=\Omega_{\alpha,4}\mbox{ and }\Omega_{\alpha,4}^g=\Omega_{\alpha,1}. \end{align*} $$

Therefore, $(\Omega _{\alpha ,1}\cup \Omega _{\alpha ,4})^g=\Omega _{\alpha ,1}\cup \Omega _{\alpha ,4}$ and $g^2$ fixes setwise $\Omega _{\alpha ,1}$ and $\Omega _{\alpha ,4}$ .

Since $\Omega _{\alpha ,1}$ is a block of imprimitivity for G with setwise stabilizer $\mathbf {N}_G(G_{\alpha })$ , we deduce $g^2\in \mathbf {N}_G(G_{\alpha })$ . Set $T:=\langle \mathbf {N}_G(G_{\alpha }),g\rangle $ .

Since $G_{\alpha }$ fixes setwise $\Omega _{\alpha ,1}\cup \Omega _{\alpha ,4}$ , we deduce that $G_{\alpha }$ fixes setwise also ${\Omega _{\alpha ,4}=\Omega _{\beta ,1}}$ . Now, for every $x\in \mathbf {N}_G(G_{\alpha })$ , we have

$$ \begin{align*}\Omega_{\alpha,1}^{g^{-1}\alpha g}=(\Omega_{\alpha,1}^{g^{-1}})^{xg}=\Omega_{\beta,1}^{xg}=(\Omega_{\beta,1}^x)^g=\Omega_{\beta,1}^g=\Omega_{\alpha,1}.\end{align*} $$

Thus, $g^{-1}xg$ fixes setwise $\Omega _{\alpha ,1}$ and hence $g^{-1}xg\in \mathbf {N}_G(G_{\alpha })$ . This yields

$$ \begin{align*}\mathbf{N}_G(G_{\beta})=\mathbf{N}_G(G_{\alpha^g})=(\mathbf{N}_G(G_{\alpha}))^g=\mathbf{ N}_G(G_{\alpha}).\end{align*} $$

As g normalizes $\mathbf {N}_G(G_{\alpha })$ , we have $T=\mathbf {N}_G(G_{\alpha })\langle g\rangle $ and

$$ \begin{align*} \alpha^T=(\alpha^{\mathbf{N}_G(G_{\alpha})})^{\langle g\rangle}=\Omega_{\alpha,1}^{\langle g\rangle}=\Omega_{\alpha,1}\cup\Omega_{\alpha,4}. \end{align*} $$

Now, since T is an overgroup of $G_{\alpha }$ and since $\Omega _{\alpha ,1}\cup \Omega _{\alpha ,4}$ is the T-orbit containing $\alpha $ , we deduce that $\Omega _{\alpha ,1}\cup \Omega _{\alpha ,4}$ is a block of imprimitivity for G.

Proof Suppose that

• (*) there exist two distinct vertices of $\Gamma $ having valency at least $2$ .

By symmetry, without loss of generality, we suppose that these two vertices are in $\Lambda _X$ . Thus, suppose that $X_i,X_j\in \Lambda _X$ have valency at least $2$ in $\Gamma $ .

Let $Y_{i_1}$ and $Y_{i_2}$ be two neighbors of $X_i$ in $\Gamma $ . Then, by definition, $X_iY_{i_1}$ and $X_iY_{i_2}$ are both subgroups of G conjugate to X. Therefore, $X_iY_{i_1}$ and $X_iY_{i_2}$ are elementary abelian $2$ -groups and hence $X_i$ commutes with both $Y_{i_1}$ and $Y_{i_2}$ . Since $\langle Y_{i_1},Y_{i_2}\rangle =Y$ , we deduce that $X_i$ commutes with Y.

Arguing as in the paragraph above with $X_i$ replaced by $X_j$ , we deduce that $X_j$ commutes with Y. Therefore, $X=\langle X_i,X_j\rangle $ commutes with Y.

Now, it is elementary to see that every bipartite graph on six vertices, with parts having cardinality $3$ and having at least six edges has the property $(\ast )$ .

Proof Since $\Gamma $ is vertex-transitive of valency $2$ , $\Gamma $ is a disjoint union of s cycles of the same length $\ell $ . If $\ell \ge 7$ or if $\Gamma $ is disconnected, that is, $s\ge 2$ , it can be easily checked that $W=V$ .

Proof From Lemma 2.1, $\Omega =\Omega _{\alpha ,1}\cup \Omega _{\alpha ,2}\cup \Omega _{\alpha ,4}$ . Moreover, for each $\beta \in \Omega _{\alpha ,4}$ , we have shown that $G_{\alpha }$ contains a proper subgroup (namely, $G_{\alpha }\cap G_{\omega }$ , for each ${\omega \in \Omega _{\alpha ,2}\cap \Omega _{\beta ,2}}$ ) strictly containing $G_{\alpha }\cap G_{\beta }$ . This implies that the permutation group, P say, induced by $G_{\alpha }$ in its action on the suborbit $\beta ^{G_{\alpha }}$ is a $2$ -group. (Indeed, if $G_{\alpha }$ induces the alternating group $\mathrm {Alt}(4)$ or the symmetric group $\mathrm {Sym}(4)$ on $\beta ^{G_{\alpha }}$ , then $G_{\alpha }$ acts primitively on $\beta ^{G_{\alpha }}$ and hence $G_{\alpha }\cap G_{\beta }$ is maximal in $G_{\alpha }$ .) Clearly, this $2$ -group P must be either cyclic of order $4$ , or elementary abelian of order $4$ , or dihedral of order $8$ .

We have drawn in Figure 3, the lattice of subgroups of the cyclic group of order $4$ , the elementary abelian group of order $4$ and the dihedral group of order $8$ : the dark colored nodes indicate the lattice of subgroups between the whole group and the stabilizer of a point.

Figure 3:

Auxiliary picture for the proof of Lemma 2.5.

Figure 3 shows that, given $G_{\alpha }$ and $G_{\alpha }\cap G_{\beta }$ , we only have one choice for $G_{\alpha }\cap G_{\omega }$ when P is cyclic of order $4$ or dihedral of order $8$ , whereas, we have at most three choices for $G_{\alpha }\cap G_{\omega }$ when P is elementary abelian of order $4$ .

Given $\beta \in \Omega _{\alpha ,4}$ , let

$$ \begin{align*}\mathcal{S}_{\alpha,\beta}:=\{G_{\omega}\mid \omega\in \Omega_{\alpha,2}\cap \Omega_{\beta,2}\}. \end{align*} $$

Observe that in the set $\mathcal {S}_{\alpha ,\beta }$ , we are collecting point stabilizers and not elements of $\Omega $ and hence different elements $\omega _1,\omega _2$ of $\Omega $ can give rise to the same element of $\mathcal {S}_{\alpha ,\beta }$ when $G_{\omega _1}=G_{\omega _2}$ .

We claim that

(10) $$ \begin{align} |\mathcal{S}_{\alpha,\beta}|\le \begin{cases} 3,&\textrm{when the permutation group induced by } G_{\alpha} \textrm{ on } \beta^{G_{\alpha}} \textrm{ or by } G_{\beta} \textrm{ on } \alpha^{G_{\beta}}\\ &\textrm{ is not an elementary abelian } 2\textrm{-group of order } 4,\\ 9,&\textrm{otherwise}. \end{cases} \end{align} $$

This claim follows from the paragraphs above and from Figure 3. Indeed, from Lemma 2.1 part (c), for each $X\in \mathcal {S}_{\alpha ,\beta }$ , there exist a proper subgroup A of $G_{\alpha }$ and a proper subgroup B of $G_{\beta }$ with $G_{\alpha }\cap G_{\beta }<A$ , $G_{\alpha }\cap G_{\beta }<B$ and $X=AB$ . Observe that we have at most three choices for A and at most three choices for B and hence at most nine choices for X. Moreover, as long as the permutation group induced on the corresponding orbit is not elementary abelian, we actually have only one choice for either A or B yielding at most three choices for X.

For each $X\in \mathcal {S}_{\alpha ,\beta }$ , let $\mathcal {S}_X:=\{\omega \in \Omega _{\alpha ,2}\cap \Omega _{\beta ,2}\mid G_{\omega }=X\}$ . From Section 1.1 and from the notation therein, we have $|\mathcal {S}_X|=|\Omega _{\omega ,1}|=d$ . From this and from the definition of $\mathcal {S}_{\alpha ,\beta }$ , we obtain

(11) $$ \begin{align} |\Omega_{\alpha,2}\cap\Omega_{\beta,2}|=\left|\bigcup_{X\in\mathcal{S}_{\alpha,\beta}}\mathcal{S}_X\right|= \sum_{X\in\mathcal{S}_{\alpha,\beta}}|\mathcal{S}_X|= |\mathcal{S}_{\alpha,\beta}|d. \end{align} $$

From part (a) of Lemma 2.1, we have $\Omega =\Omega _{\alpha ,1}\cup \Omega _{\alpha ,2}\cup \Omega _{\alpha ,4}$ . From this, we immediately get $\Omega _{\beta ,2}\subseteq \Omega \setminus \Omega _{\alpha ,1}=\Omega _{\alpha ,2}\cup \Omega _{\alpha ,4}$ and hence $\Omega _{\alpha ,2}\cup \Omega _{\beta ,2}\subseteq \Omega _{\alpha ,2}\cup \Omega _{\alpha ,4}$ . Therefore,

(12) $$ \begin{align} |\Omega_{\alpha,2}\cap\Omega_{\beta,2}|&=|\Omega_{\alpha,2}|+|\Omega_{\beta,2}|-|\Omega_{\alpha,2}\cup\Omega_{\beta,2}|\\\nonumber &\ge |\Omega_{\alpha,2}|+|\Omega_{\beta,2}|-|\Omega_{\alpha,2}\cup\Omega_{\alpha,4}|\\\nonumber &= |\Omega_{\alpha,2}|+|\Omega_{\beta,2}|-|\Omega_{\alpha,2}|-|\Omega_{\alpha,4}|\\\nonumber &=|\Omega_{\alpha,2}|-|\Omega_{\alpha,4}|. \end{align} $$

Now, dividing both sides of (11) and (12) by $|\Omega _{\alpha ,1}|=d$ , by recalling (4) and by rearranging the terms, we obtain

(13) $$ \begin{align} x_2\le |\mathcal{S}_{\alpha,\beta}|+x_4. \end{align} $$

We now suppose that part (a) does not hold and we show that part (bi), (bii), (biii), and (biv) are satisfied. In particular, we work under the assumption that

$$ \begin{align*}|\Omega_{\alpha,1}|+|\Omega_{\alpha,2}|\ge \frac{5|\Omega|}{6}.\end{align*} $$

As $|\Omega |=d(x_1+x_2+x_4)$ , $|\Omega _{\alpha ,1}|+|\Omega _{\alpha ,2}|=d(x_1+x_2)$ and $x_1=1$ , the inequality $|\Omega _{\alpha ,1}|+|\Omega _{\alpha ,2}|\ge 5|\Omega |/6$ gives

$$ \begin{align*}5x_4\le 1+x_2.\end{align*} $$

Now, (13) yields $5x_4\le 1+x_2\le 1+|\mathcal {S}_{\alpha ,\beta }|+x_4$ , that is, $4x_4\le 1+|\mathcal {S}_{\alpha ,\beta }|$ . From (10), we deduce that $x_4\le 2$ . This already shows part (bi).

When $x_4=2$ , we deduce $|\mathcal {S}_{\alpha ,\beta }|\ge 7$ and hence (10) yields that the permutation groups induced by $G_{\alpha }$ on $\beta ^{G_{\alpha }}$ and by $G_{\beta }$ on $\alpha ^{G_{\beta }}$ are both elementary abelian $2$ -groups of order $4$ . Since this argument does not depend upon $\beta \in \Omega _{\alpha ,4}$ , we have shown that $G_{\alpha }$ acts as an elementary abelian group on each of its orbits of cardinality $4$ . Since all other orbits of $G_{\alpha }$ have cardinality $1$ or $2$ , we deduce that $G_{\alpha }$ acts as an elementary abelian $2$ -group on each of its orbits and hence $G_{\alpha }$ is an elementary abelian $2$ -group. This shows part (bii), under the additional assumption that $x_4=2$ . Moreover, as $|\mathcal {S}_{\alpha ,\beta }|\ge 7$ , Lemma 2.3 applied with $X:=G_{\alpha }$ and $Y:=G_{\beta }$ gives that $G_{\alpha }$ and $G_{\beta }$ commute with each other. This shows that part (biii) is satisfied. To prove part (biv), we use Lemma 2.4. Let $\Gamma $ be the graph having vertex set V, the set of conjugates of $G_{\alpha }$ in G, that is,

$$ \begin{align*}V:=\{G_{\omega}\mid\omega\in \Omega\}.\end{align*} $$

Then $|V|=1+x_2+x_4$ . We declare two vertices $G_{\omega _1}$ and $G_{\omega _2}$ of $\Gamma $ adjacent if $G_{\omega _1}\cap G_{\omega _2}$ has index $4$ in $G_{\omega _1}$ (and hence also in $G_{\omega _2}$ ). Clearly, the action of G by conjugation gives rise to a vertex-transitive action of G on $\Gamma $ . As $x_4=2$ , $\Gamma $ has valency $2$ . Let W be the collection of all vertices $G_{\omega }$ of $\Gamma $ with $G_{\alpha } \cap G_{\beta }\le G_{\omega }$ . Clearly, $G_{\alpha },G_{\beta }\in W$ and, from Lemma 2.1 part (c), for any two distinct vertices $G_{\delta _1}$ and $G_{\delta _2}$ of $\Gamma $ contained in W, we have that

$$ \begin{align*}\Omega_{\delta_1,2}\cap\Omega_{\delta_2,2}=V\setminus (\Gamma(G_{\delta_1})\cup\Gamma(G_{\delta_2}))\subseteq W.\end{align*} $$

From this, Lemma 2.4 gives that either $W=V$ or $|V|\le 6$ . The second alternative gives $x_2=|V|-1-x_4\le 3$ , which contradicts the fact that $5x_4\le 1+x_2$ . Therefore, $W=V$ and hence $G_{\alpha }\cap G_{\beta }\le G_{\omega }$ , for every $\omega \in \Omega $ . Thus $G_{\alpha }\cap G_{\beta }=1$ and hence ${G_{\alpha } G_{\beta }=G_{\alpha }\times G_{\beta }}$ is an elementary abelian $2$ -group of order $16$ . To prove that ${G_{\alpha }\times G_{\beta }\unlhd G}$ it suffices to apply again this argument to the collection W of all vertices $G_{\omega }$ of $\Gamma $ with $G_{\omega }\le G_{\alpha } \times G_{\beta }$ .

In particular, in the rest of the proof we work under the assumption $x_4=1$ .

When $x_4=1$ , we may refine some of the inequalities above. Indeed, when $x_4=1$ , we have $\Omega _{\alpha ,4}=\Omega _{\beta ,1}$ , because both sets have the same cardinality and $\Omega _{\beta ,1}\subseteq \Omega _{\alpha ,4}$ . From this it follows $\Omega _{\alpha ,2}=\Omega _{\beta ,2}$ . Therefore, from (11), we get

$$ \begin{align*}dx_2=|\Omega_{\alpha,2}|=|\Omega_{\alpha,2}\cap\Omega_{\beta,2}|=d|\mathcal{S}_{\alpha,\beta}|.\end{align*} $$

Now, the inequality $5=5x_4\le 1+x_2$ implies $|\mathcal {S}_{\alpha ,\beta }|=x_2\ge 4$ . Again, we may use (10) to deduce that the permutation groups induced by $G_{\alpha }$ on $\beta ^{G_{\alpha }}$ and by $G_{\beta }$ on $\alpha ^{G_{\beta }}$ are both elementary abelian $2$ -groups of order $4$ . This, as above, yields that $G_{\alpha }$ is an elementary abelian $2$ -group, that is, part (bii) holds.

From Lemma 2.1 part (c), $G_{\alpha }\cap G_{\beta }\le G_{\omega }$ , for every $\omega \in \Omega _{\alpha ,2}\cap \Omega _{\beta ,2}$ . In particular, $G_{\alpha }\cap G_{\beta }$ fixes pointwise $\Omega _{\alpha ,2}\cap \Omega _{\beta ,2}$ . As $\Omega _{\alpha ,2}\cap \Omega _{\beta ,2}=\Omega _{\alpha ,2}$ , we deduce that $G_{\alpha }\cap G_{\beta }$ fixes pointwise $\Omega _{\alpha ,2}$ . Since $G_{\alpha }\cap G_{\beta }$ fixes pointwise also $\Omega _{\alpha ,1}$ and $\Omega _{\beta ,1}=\Omega _{\alpha ,4}$ , we obtain that $G_{\alpha }\cap G_{\beta }$ fixes pointwise $\Omega _{\alpha ,1}\cup \Omega _{\alpha ,2}\cup \Omega _{\alpha ,4}=\Omega $ . Thus $G_{\alpha }\cap G_{\beta }=1$ and $|G_{\alpha }|=4$ . Observe also that when $x_4=1$ , the hypothesis of Lemma 2.2 is satisfied and hence $\mathbf {N}_G(G_{\alpha })=\mathbf {N}_G(G_{\beta })$ . Therefore, $G_{\beta }$ normalizes $G_{\alpha }$ . This gives that the commutator subgroup $[G_{\alpha },G_{\beta }]$ lies in $G_{\alpha }\cap G_{\beta }=1$ , that is, $G_{\alpha }$ commutes with $G_{\beta }$ . This shows that part (biii) is satisfied. Now, as $\Omega _{\alpha ,2}=\Omega _{\beta ,2}$ , Lemma 2.1 part (c) yields $G_{\omega }\le G_{\alpha }\times G_{\beta }$ , for every $\omega \in \Omega _{\alpha ,2}$ . Therefore, $G_{\alpha }\times G_{\beta }$ contains $G_{\omega }$ , for every $\omega \in \Omega $ . Thus,

$$ \begin{align*}G_{\alpha}\times G_{\beta}=\langle G_{\omega}\mid\omega\in \Omega\rangle\unlhd G,\end{align*} $$

and $G_{\alpha }\times G_{\beta }$ has order $16$ . Thus, part (biv) is satisfied.

Proof Let $\iota :R\to R$ be the permutation defined by $x^{\iota }=x^{-1}$ , for every $x\in R$ , and let

$$ \begin{align*} T:=\langle\iota,\tau\rangle. \end{align*} $$

Observe that $\iota \tau =\tau \iota $ and $\iota ^2=\tau ^2=1$ . Therefore, T is an elementary abelian $2$ -group of order at most $4$ .

Now, a subset S of R is inverse-closed and $\tau $ -invariant if and only if S is T-invariant. In particular, the number of inverse-closed subsets S of R with $S^{\tau }=S$ is $2^{\kappa }$ , where $\kappa $ is the number of orbits of T on R. To compute $\kappa $ , we use the orbit-counting lemma, which says that

(14) $$ \begin{align} \kappa=\frac{1}{|T|}\sum_{t\in T}|\mathrm{Fix}_R(t)|. \end{align} $$

Observe that

(15) $$ \begin{align} \mathrm{Fix}_R(1)&:=R,\\\nonumber \mathrm{Fix}_R(\iota)&:=\mathbf{I}(R),\\\nonumber \mathrm{Fix}_R(\tau)&:=U, \\\nonumber \mathrm{Fix}_R(\iota\tau)&:=\mathbf{I}(U)\cup\{x\in R\setminus U\mid x^2=r\}.\nonumber \end{align} $$

Observe that $\tau \ne 1$ because U is a proper subgroup of R and $r\ne 1$ . If $\iota =1$ , then R is an elementary abelian $2$ -group and $T=\langle \tau \rangle $ . Thus, (14) and (15) yield

$$ \begin{align*} \kappa&=\frac{1}{2}\left(|R|+|U|\right)\le\frac{|R|}{2}+\frac{|R|}{4}= \frac{3|R|}{4}\\ &=|R|-\frac{|R|}{4}=\mathbf{c}(R)-\frac{|R|}{4}. \end{align*} $$

Therefore, part (a) holds and the proof follows in this case. Suppose now $\iota =\tau $ . This means that U is an elementary abelian $2$ -subgroup of R and $x^{-1}=xr$ , for every ${x\in R\setminus U}$ . In other words, all elements in U square to $1$ and all elements in $R\setminus U$ square to r. Let $\bar {R}:=R/\langle r\rangle $ and let us use the “bar” notation for the subgroups and for the elements of $\bar {R}$ . Consider the function

$$ \begin{align*}( \cdot,\cdot):\bar{R}\times\bar{R}\to \langle r\rangle\end{align*} $$

defined by $( x\langle r\rangle , y\langle r\rangle )=x^{-1}y^{-1}xy$ , for every $x,y\in R$ . Similarly, consider the function

$$ \begin{align*}q:\bar{R}\to\langle r\rangle\end{align*} $$

defined by $q(x\langle r\rangle )=x^2$ . It is not hard to see that, regarding $\bar {R}$ as a vector space over the field with two elements, $(\cdot ,\cdot )$ is a bilinear form and q is a quadratic form polarizing to $(\cdot ,\cdot )$ , that is,

$$ \begin{align*}q(\bar{x}\bar{y})q(\bar{x})q(\bar{y})=(\bar{x},\bar{y}),\end{align*} $$

for every $\bar {x},\bar {y}\in \bar {R}$ . Using this terminology, we have that each element of $\bar {U}$ is totally singular and each element of $\bar {R}\setminus \bar {U}$ is nondegenerate. From the classification of the quadratic forms over finite fields, we have $|\bar {R}:\bar {U}|\in \{2,4\}$ . When $|\bar {R}:\bar {U}|=2$ , we deduce that R is an abelian group isomorphic to the direct product $C_4\times C_2^{\ell }$ , for some $\ell \ge 0$ . In particular, part (c) holds. When $|\bar {R}:\bar {U}|=4$ , we deduce that $R\cong Q_8\times C_2^{\ell }$ , for some $\ell \ge 0$ . In particular, R is generalized dicyclic and part (b) holds. For the rest of our argument, we may suppose that $\tau \ne \iota \ne 1$ .

Set $\mathcal {S}:=\{x\in R\setminus U\mid x^2=r\}$ . In the present situation, $T=\langle \iota ,\tau \rangle $ has order $4$ and hence, from (15), (14) becomes

(16) $$ \begin{align} \kappa&= \frac{1}{4} \left( |\mathrm{Fix}_R(1)|+ |\mathrm{Fix}_R(\iota)|+ |\mathrm{Fix}_R(\tau)|+ |\mathrm{Fix}_R(\tau\iota)| \right)\\\nonumber &=\frac{1}{4}\left( |R|+|\mathbf{I}(R)|+|U|+|\mathbf{I}(U)|+|\{x\in R\setminus U\mid x^2=r\}|\right)\\\nonumber &\le \frac{1}{4}\left( |R|+|\mathbf{I}(R)|+|U|+|\mathbf{I}(R)|+|\mathcal{S}|\right)\\\nonumber &=\frac{|R|+|\mathbf{I}(R)|}{2}-\left( \frac{|R|}{4}-\frac{|U|}{4}-\frac{|\mathcal{S}|}{4} \right)=\mathbf{c}(R)-\left( \frac{|R|}{4}-\frac{|U|}{4}-\frac{|\mathcal{S}|}{4} \right).\nonumber \end{align} $$

If $\mathcal {S}=\emptyset $ , then the proof follows immediately from (16), indeed, part (a) holds true. Therefore, for the rest of the proof, we suppose

$$ \begin{align*} \mathcal{S}\ne\emptyset. \end{align*} $$

To conclude, we divide the proof in various cases.

Suppose that $|R:U|=2$ . Let $x\in \mathcal {S}$ and observe that $R=U\cup Ux$ . Now, a computation yields

$$ \begin{align*} \mathcal{S}=\{ux\mid u\in U, u^x=u^{-1}\}. \end{align*} $$

When $\mathcal {S}=Ux$ , the action of x on U by conjugation is an automorphism of U inverting each element of U. Therefore, U is abelian and R is generalized dicyclic. Hence part (b) holds. When $\mathcal {S}\subsetneq Ux$ , the result of Liebeck and MacHale [Reference Liebeck and MacHale15] shows that the automorphism x can invert at most $3/4$ of the elements of U and hence $|\mathcal {S}|\le 3|U|/4=3|R|/8$ . Now, (16) gives $\kappa \le \mathbf {c}(R)-|R|/32$ ; hence, part (a) holds and the proof in this case follows. ${}_{\blacksquare }$

Therefore, for the rest of the proof, we may suppose

(17) $$ \begin{align} |R:U|\ge3. \end{align} $$

Suppose that $|\mathcal {S}|\le 3|R|/4-|U|/2$ . From (16) and (17), we deduce

$$ \begin{align*} \kappa&\le \mathbf{c}(R)-\left( \frac{|R|}{4}-\frac{|U|}{4}-\frac{3|R|}{16}+\frac{|U|}{8}\right)\\ &= \mathbf{c}(R)-\left( \frac{|R|}{16}-\frac{|U|}{8}\right)\\ &\le\mathbf{c}(R)-\left( \frac{|R|}{16}-\frac{|R|}{24}\right)=\mathbf{c}(R)- \frac{|R|}{48} \end{align*} $$

and the proof in this case follows. ${}_{\blacksquare }$

Therefore, for the rest of the proof, we suppose

$$ \begin{align*}|\mathcal{S}|> 3|R|/4-|U|/2.\end{align*} $$

To introduce the next case, we first need to make some general observations.

Let u be an arbitrary element of U. Then $u\mathcal {S}\subseteq R\setminus U$ and hence $\mathcal {S}\cup u\mathcal {S}\subseteq R\setminus U$ . Therefore,

(18) $$ \begin{align} |\mathcal{S}\cap u\mathcal{S}|&= |\mathcal{S}|+|u\mathcal{S}|-|\mathcal{S}\cup u\mathcal{S}|=2|\mathcal{S}|-|\mathcal{S}\cup u\mathcal{S}|\\ \nonumber &\ge 2|\mathcal{S}|-(|R|-|U|)>\frac{3|R|}{2}-|U|-(|R|-|U|)=\frac{|R|}{2}.\nonumber \end{align} $$

Now, let $ux\in \mathcal {S}\cap u\mathcal {S}$ . Then $x\in \mathcal {S}$ , and hence

$$ \begin{align*} r=(ux)^2=uxux=uu^xx^2=uu^xr. \end{align*} $$

Therefore, $u^x=u^{-1}$ . Now, repeating the argument above with $y\in \mathcal {S}\cap u\mathcal {S}$ , we deduce $u^y=u^{-1}$ and hence $xy^{-1}\in \mathbf {C}_R(u)$ . Since we have $|\mathcal {S}\cap u\mathcal {S}|$ choices for y, (18) implies $|\mathbf {C}_R(u)|>|R|/2$ and hence $R=\mathbf {C}_R(u)$ . Since u is an arbitrary element of U, we deduce that U is a central subgroup of R.

Since $u^x=u^{-1}$ , for every $u\in U$ and for every $ux\in \mathcal {S}\cap u\mathcal {S}$ , and since U is contained in the center of R, we deduce that U has exponent $2$ . Since U is a central subgroup of R of exponent $2$ , we now have an easier description for $\mathcal {S}$ , that is,

$$ \begin{align*} \mathcal{S}=\{x\in R\mid x^2=r\}. \end{align*} $$

Now that we know that U has exponent $2$ , we consider the quotient group ${\bar {R}:=R/\langle r\rangle }$ . Observe that each element of $\bar U$ is an involution.

Suppose that $\bar {R}$ is not an elementary abelian $2$ -group. The theorem of Miller [Reference Miller16] yields $|\mathbf {I}(\bar {R})|\le 3|\bar {R}|/4$ . In particular, the number of involutions in $\bar {R}\setminus \bar {U}$ is at most $3|\bar {R}|/4-|\bar {U}|$ . Since each element in $\bar {\mathcal {S}}$ is an involution and since $\bar {\mathcal {S}}\subseteq \bar {R}\setminus \bar {U}$ , we deduce $|\mathcal {S}|\le 3|R|/4-|U|$ . Using this inequality in (16), we get

$$ \begin{align*} \kappa\le \mathbf{c}(R)-\frac{|R|}{16}, \end{align*} $$

part (a) holds and the proof follows in this case. It remains to consider the case that $\bar {R}$ is an elementary abelian $2$ -group.

Suppose that $\bar {R}$ is an elementary abelian $2$ -group. Recall that the Frattini subgroup $\Phi (X)$ of a finite group X is the intersection of all the maximal subgroups of X. Recall also that, if X is a p-group for some prime p, then $\Phi (X)=X^p[X,X]$ , where $[X,X]$ is the commutator subgroup of X and $X^p:=\langle x^p\mid x\in X\rangle $ . When $p=2$ , $[X,X]\le X^2$ because $X/X^2$ is abelian. Therefore, $\Phi (X)=X^2$ .

Since the Frattini subgroup $\Phi (\bar {R})$ of $\bar {R}$ is the identity and since $r\in \Phi (R)$ , we deduce $\Phi (R)=\langle r\rangle $ . Now, if R is abelian, then from the structure theorem of finitely generated abelian groups, we deduce that R is isomorphic to

1. (i) $C_4\times C_2^{\ell }$ for some $\ell \ge 0$ .

If R is non-abelian, then $1\ne [R,R]\le \langle r\rangle $ and hence $[R,R]=\Phi (R)=\langle r\rangle $ . Now, from [Reference Berkovich4, Lemmas 4.2 and 4.3 and Remark 1, p. 74], we obtain that $R=E\times A$ , where E is an extraspecial $2$ -group and A is an elementary abelian $2$ -group. Now, from the structure theorem of extraspecial $2$ -groups [Reference Suzuki25, Theorem 4.18(ii)], we deduce that R is isomorphic to one of the following groups:

1. (ii) $\underbrace {D_8\circ D_8\circ \cdots \circ D_8}_{t\textrm { times}}\times C_2^{\ell }$ , for some $\ell \ge 0$ and $t\ge 1$ .

2. (iii) $Q_8\circ \underbrace {D_8\circ D_8\circ \cdots \circ D_8}_{(t-1)\textrm { times}}\times C_2^{\ell }$ , for some $\ell \ge 0$ and some $t\ge 1$ .

3. (iv) $C_4\circ \underbrace {D_8\circ D_8\circ \cdots \circ D_8}_{t\textrm { times}}\times C_2^{\ell }$ , for some $\ell \ge 0$ and some $t\ge 1$ .

Therefore, the case that $\bar {R}$ is elementary abelian splits naturally into four cases. To conclude the proof of this lemma, we look at each case in detail.

In Case (i), an explicit computation gives $|\mathcal {S}|=|R|/2$ . Hence, (16) gives

$$ \begin{align*} \kappa&\le\mathbf{c}(R)-\left(\frac{|R|}{4}-\frac{|U|}{4}-\frac{|R|}{8}\right)= \mathbf{c}(R)-\left(\frac{|R|}{8}-\frac{|U|}{4}\right)\\ &\le\mathbf{c}(R)-\left(\frac{|R|}{8}-\frac{|R|}{16}\right) =\mathbf{c}(R)-\frac{|R|}{16} \end{align*} $$

and part (a) holds.

In Case (ii), an explicit computation gives $|\mathcal {S}|=(2^t-1)|R|/2^{t+1}\le |R|/2$ . Therefore, we may argue as in the previous case and we obtain that part (a) holds.

In Case (iii), an explicit computation gives $|\mathcal {S}|=(2^t+1)|R|/2^{t+1}$ . When $t=1$ , ${R\cong Q_8\times C_2^{\ell }}$ is generalized dicyclic and hence part (b) hods. When $t\ge 2$ , we have ${|\mathcal {S}|\le 5|R|/8}$ and hence (16) gives

$$ \begin{align*} \kappa&\le\mathbf{c}(R)-\left(\frac{|R|}{4}-\frac{|U|}{4}-\frac{5|R|}{32}\right)= \mathbf{c}(R)-\left(\frac{3|R|}{32}-\frac{|U|}{4}\right)\\ &\le\mathbf{c}(R)-\left(\frac{3|R|}{32}-\frac{|R|}{16}\right) =\mathbf{c}(R)-\frac{|R|}{32}. \end{align*} $$

Thus, we obtain that part (a) holds.

In Case (iv), an explicit computation gives $|\mathcal {S}|=|R|/2$ . Therefore, we may argue as in the first case and we obtain that part (a) holds.