Proof of Proposition 2.1

We compute the inner product of $1_E^G$ and $\chi \in \mathrm {Irr} (G)$ by Frobenius reciprocity:

$$\begin{align*}(1_E^G, \chi)_G = (1_E, \chi_E)_E = \frac{1}{|E|} \sum_{x \in E} \chi (x^{-1}). \end{align*}$$

Let $\mu _i$ and $ \psi $ be the characters as in Lemma 2.2. Since $E \subset N$ , we have

$$\begin{align*}(1_E^G, \mu_i )_G= \frac{2^{n-2}}{|E|}=1. \end{align*}$$

If $\chi = \psi $ , then we can write $\psi = \varphi ^G$ with $\varphi (\neq 1_N) \in \mathrm {Irr} (N)$ . It is clear that $\psi (1) = [G : N ] =2^n-1$ . For a nontrivial element $x \in E \subset N$ , we have

$$\begin{align*}\psi (x)= \sum_{h \in H} \varphi (hxh^{-1})= \sum_{g \in N -\{1\}} \varphi (g) =-1. \end{align*}$$

Here, the second equality holds since the action of H on N is transitive and faithful, and therefore the set $\{ hxh^{-1} \mid h \in H \}$ coincides with $N-\{1\}$ . Moreover, the third equality follows from the fact that $\varphi $ is nontrivial. We conclude

$$ \begin{align*} (1_E^G, \psi )_G &= \frac{1}{2^{n-2}} \left(\psi (1) + \sum_{x (\neq 1) \in E} \psi (x) \right)\\[6pt] & = \frac{1}{2^{n-2}} (2^n-1 + (-1)(2^{n-2}-1)) = 3. \end{align*} $$

Consequently, we obtain the decomposition of $1_E^G$ :

$$\begin{align*}1_E^G = 3 \psi + \sum_{i=0}^{2^n-2} \mu_i , \end{align*}$$

which is independent of the choice of E. This completes the proof of Proposition 2.1.▪

Proof It is well known that the number of t-dimensional subspaces in an s-dimensional vector space over $\mathbb {F}_2$ is given by the q-binomial coefficient with $q=2$ , which we denote by

$$\begin{align*}\begin{bmatrix} s \\ t \end{bmatrix} = \frac{(2^s-1) (2^{s-1}-1) \cdots (2^{s-t+1}-1)} {(2^t-1)(2^{t-1}-1)\cdots (2-1)}. \end{align*}$$

Using this formula, we can compute

$$ \begin{align*} |\mathscr{E}| & = \begin{bmatrix} n \\ n -2 \end{bmatrix} = \begin{bmatrix} n \\ 2 \end{bmatrix}= \frac{1}{3} (2^n-1)(2^{n-1}-1) \end{align*} $$

and

$$ \begin{align*} |\mathscr{E} \cap D| & = \begin{bmatrix} n-1 \\ n-2 \end{bmatrix} = \begin{bmatrix} n-1 \\ 1 \end{bmatrix} = 2^{n-1}-1. \end{align*} $$

Now, we identify N with the additive group of $\mathbb {F}_{2^n}$ . If g is a generator of $\mathbb {F}_{2^n}^{\times }$ and ${E \in \mathscr {E}}$ , then we can write $E=\{ 0, g^{i_1}, \ldots ,g^{i_{2^{n-2}-1}}\}$ with $\{ i_1, \ldots , i_{2^{n-2}-1}\} \subset \{ 1,2,\ldots , 2^n-1 \}$ . For notational convenience, we write it as $E= (i_1, \ldots , i_{2^{n-2}-1})$ . If we represent $\tau \in G$ by a product $ g^{\ell } \nu \ (g^{\ell } \in H, \nu \in N)$ , then it is easy to see that the conjugate $E^{\tau } $ is given by $E^{\tau } = E^{g^{\ell }} =(i_1 + \ell , \ldots , i_{2^{n-2}-1}+\ell )$ . We compute the normalizer $N_G (E)$ . We have $\tau = g^{\ell } \nu \in N_G (E)$ if and only if there exists a permutation $\gamma \in S_{2^{n-2}-1}$ such that

$$\begin{align*}i_j + \ell \equiv i_{\gamma (j)} \quad \pmod{2^n-1} \quad (j=1,\ldots , 2^{n-2}-1). \end{align*}$$

Summing up both the sides for j, we obtain

$$\begin{align*}(i_1 + \cdots + i_{2^{n-2}-1}) + (2^{n-2}-1)\ell \equiv (i_1 + \cdots + i_{2^{n-2}-1}) \quad \pmod{2^n-1}, \end{align*}$$

and this yields $(2^{n-2} -1 ) \ell \equiv 0 \pmod {2^n-1}$ . In this connection, we see

$$\begin{align*}\gcd (2^{n-2}-1 , 2^n -1)= \gcd (2^n-1, 3) = \begin{cases} 1, & \text{ if } n \text{ is odd}, \\ 3, & \text{ if } n \text{ is even}. \end{cases} \end{align*}$$

Therefore, if n is odd, then we conclude that $\ell =0 $ and $N_G (E) = N$ . Hence, the orbit length of every $E \in \mathscr {E}$ is $2^n-1$ , and the set $\mathscr {E}$ is divided into $\dfrac {1}{3} (2^{n-1}-1)$ conjugacy classes.

If n is even, then we obtain $\ell =0 $ or $\dfrac {2^n-1}{3}$ . In the latter case, the element $g^{\ell }$ in $N_G (E)$ is of order $3$ . Accordingly, the orbit length of E is either $2^n-1$ or $\dfrac {2^n-1}{3}$ . Let u (resp. v) be the number of orbits of length $2^n-1 \left ( \text {resp. } \dfrac {2^n-1}{3} \right )$ . It obviously yields

(2.1) $$ \begin{align} u (2^n-1) +v \dfrac{2^n-1}{3} = |\mathscr{E}|. \end{align} $$

We compute the total number of orbits $u+v$ by using the lemma of Burnside–Frobenius [Reference Aigner1, Lemma 6.2]. For $x \in G$ , if we define

$$\begin{align*}\mathrm{Fix} (x) = \{ E \in \mathscr{E} \mid E^x = E \}, \end{align*}$$

then we have

$$\begin{align*}u+v = \frac{1}{|G|} \sum_{x \in G} | \mathrm{Fix} (x) |. \end{align*}$$

As is seen in the above, we have $ \mathrm {Fix} (g^i \nu ) = \mathrm {Fix} (g^i) $ if we write $x =g^i \nu $ with $\nu \in N$ . Moreover, if the order of $g^i$ is neither $1$ nor $3$ , then $ \mathrm {Fix} (x) = \emptyset $ . Obviously, if the order of $g^i$ is equal to $1$ , then we have $i=0$ and $\mathrm {Fix} (1) = \mathscr {E}$ .

We now suppose that the order of $g^i$ is $3$ , and thus $i=(2^n-1)/3$ . Since the minimal polynomial of $g^i$ over $\mathbb {F}_2$ is $X^2+X+1$ of degree $2$ , the irreducible $\langle g^i \rangle $ -module B is of dimension $2$ over $\mathbb {F}_2$ . It is easy to see that B is of the form $\{ 0 , g^t , g^{t+i}, g^{t+2i}\}$ with some $ 0 \le t \le 2^n-1$ . Since one of $t , {t+i}, {t+2i}$ modulo $2^n-1$ lies in the first one-third interval, we may assume that $ 0 \le t < (2^n-1)/3$ . Hence, there are $\dfrac {2^n-1}{3}$ distinct irreducible $\langle g^i \rangle $ -modules inside N. To compute $|\mathrm {Fix} (g^i)|$ , we have to enumerate $(n-2)$ -dimensional $\langle g^i \rangle $ - modules inside N, but instead we only have to enumerate the complementary two-dimensional modules by Maschke’s theorem [Reference Isaacs5, Theorem 1.9]. Therefore, we conclude $|\mathrm {Fix} (g^i)| = \dfrac {2^n-1}{3}$ .

Therefore, it follows that

(2.2) $$ \begin{align} \qquad u+v = \frac{2^n}{2^n(2^n-1)} \sum_{i=0}^{2^n-2} |\mathrm{Fix} (g^i)| = \frac{1}{2^n-1} \left( |\mathscr{E}| + 2 \times \dfrac{2^n-1}{3} \right) = \frac{2^{n-1}+1}{3}. \end{align} $$

Solving equations (2.1) and (2.2), we obtain

$$\begin{align*}u = \frac{2}{3} (2^{n-2} -1) \ \text{ and } \ v=1. \end{align*}$$

We conclude that there are $\dfrac {2}{3} (2^{n-2} -1)$ conjugacy classes of length $2^n-1$ and one conjugacy class of length $\dfrac {2^n-1}{3}$ .

Let $\mathscr {O}$ be an orbit in $\mathscr {E}$ . Since G acts on the set of D’s transitively by Singer’s theorem [Reference Hall3, Theorem 11.3.1], the number $|\mathscr {O} \cap D| $ is independent of the choice of D.

We first consider the case where n is odd. Let $\mathscr {O}_i \ (i=1,\ldots ,(2^{n-1}-1)/3)$ be the conjugacy classes. Since

(2.3) $$ \begin{align} \sum_{i=1}^{(2^{n-1}-1)/3} | \mathscr{O}_i \cap D | = | \mathscr{E} \cap D| \end{align} $$

holds, it follows

$$\begin{align*}\dfrac{1}{3} (2^{n-1}-1) | \mathscr{O}_i \cap D | = 2^{n-1}-1. \end{align*}$$

Hence, we conclude that $| \mathscr {O}_i \cap D |=3$ , namely each D contains three conjugate fields.

Next, we consider the case where n is even. Let $\mathscr {O}_i \ ( i=1,\ldots ,{2}(2^{n-2}-1)/3 )$ be the conjugacy classes of length $2^n-1$ , and let $\mathscr {P}$ be the conjugacy class of length $(2^n-1)/3$ . If $E \in \mathscr {P}$ , then it is invariant by an element of order $3$ in $\mathbb {F}_{2^n}^{\times }$ . Therefore, such E is contained in three different D’s. Since there are $2^n-1$ nonconjugate D’s, we conclude that $|\mathscr {P} \cap D|=1$ . This also yields an equation like (2.3):

$$\begin{align*}\sum_{i=1}^{2(2^{n-2}-1)/3} | \mathscr{O}_i \cap D | = |\mathscr{E} \cap D | -1. \end{align*}$$

From this, it follows $|\mathscr {O}_i \cap D | =3$ for all i.

This completes the proof of Theorem 2.5, and thus Theorems 1.2 and 2.4 follow.▪

Proof If we assume that $(i,2^n-1)=1$ , then the order of $\chi _i $ is exactly $2^n-1$ and the value of $\chi _i$ is not contained in any proper subfields of $\mathbb {F}_{2^n}$ . Thus, we observe that $\varepsilon _i \mathbb {F}_2 [C_{2^n-1}]$ is an n-dimensional subspace over $\mathbb {F}_2$ .

Since $\varepsilon _i$ ’s are orthogonal idempotents, $V_i$ is apparently an $\mathbb {F}_2 [C_{2^n-1}]$ -module.

To show its irreducibility, suppose to the contrary that $V_i$ is not irreducible. There is a proper submodule W of $V_i$ . Since $V_i$ splits over $\mathbb {F}_{2^n}$ , the module W also splits over $\mathbb {F}_{2^n}$ . Therefore, the character of W is a proper subsum of $\varepsilon _i$ . However, such a subsum does not have its values in $\mathbb {F}_2$ ; therefore, W cannot be defined over $\mathbb {F}_2$ . This is a contradiction.▪

Proof By (1.1), it suffices to show that $ C_{2^n-1} \ltimes V_i$ is isomorphic to $\mathrm {AGL}_1 (\mathbb {F}_{2^n})$ .

By the isomorphism (3.2), we identify $V_i $ with $\mathbb {F}_2 [X] / (\phi _i (X))$ , where $\phi _i (X) $ is the minimal polynomial of $g^i = \chi _i (\sigma )$ and hence is of degree n. We define a map $\kappa $ from $ C_{2^n-1} \ltimes V_i$ to $\mathrm {AGL}_1 (\mathbb {F}_{2^n})$ by

$$\begin{align*}\kappa \,: \, \left( \sigma^j, U (x) \right) \mapsto \begin{bmatrix} g^{ij} & U (g^i) \\ 0 & 1 \end{bmatrix} \end{align*}$$

with $U(X) \in \mathbb {F}_2 [X]$ . By noting that $\sigma $ acts on $V_i$ by the multiplication of g, the map $\kappa $ sends

$$\begin{align*}\left( \sigma^j, U(x) \right) \left( \sigma^{\ell}, V(x) \right) = ( \sigma^{j+\ell}, U(x)+ x^j V(x) ) \end{align*}$$

to

$$\begin{align*}\begin{bmatrix} g^{i(j+\ell)} & \displaystyle U(g^i) + g^{ij} V(g^i) \\ 0 & 1 \end{bmatrix}. \end{align*}$$

On the other hand, we compute

$$\begin{align*}\begin{bmatrix} g^{ij} & U(g^i) \\ 0 & 1 \end{bmatrix} \begin{bmatrix} g^{i\ell} & V(g^i) \\ 0 & 1 \end{bmatrix} = \begin{bmatrix} g^{i(j + \ell ) } & \displaystyle U(g^i) + g^{ij} V(g^i) \\ 0 & 1 \end{bmatrix}. \end{align*}$$

Therefore, $\kappa $ is a homomorphism.

We see that $\left ( \sigma ^j, U(x) \right ) \in \ker \kappa $ if and only if $g^{ij} =1$ and $ U(g^i) =0 $ . The condition $g^{ij}=1$ is equivalent to $j \equiv 0 \pmod {2^n-1}$ since $(i,2^n-1)=1$ . The condition $U(g^i)=1$ is equivalent to the minimal polynomial $\phi _i (X)$ of $g^i$ divides $U(X)$ . Therefore, the kernel consists of the trivial element only. Since the orders of both the groups are the same, the map $\kappa $ is an isomorphism.▪

Proof We first note that $ L^{\times }/ (L^{\times })^2$ is an $\mathbb {F}_2$ -vector space on which $\operatorname {\mathrm {Gal}} (L/k)$ acts and hence is an $\mathbb {F}_2 [\operatorname {\mathrm {Gal}} (L/k)]$ -module. Let M be an irreducible $\mathbb {F}_2 [\operatorname {\mathrm {Gal}} (L/k)]$ -submodule of $L^{\times }/ (L^{\times })^2$ generated by $\theta $ . By Lemma 3.1, the module M is of dimension n over $\mathbb {F}_2$ . Let $(\theta =\theta _1, \ldots , \theta _n)$ be a basis of M. Let K be the field generated by $\sqrt {\theta _i} \ (i=1,\ldots ,n)$ , that is, $K = L \left ( \sqrt {\theta _1}, \ldots , \sqrt {\theta _n}\right )$ .

We shall first show that K is a Galois extension over k. Let $\widetilde {\sigma }$ be an extension of $\sigma \in \operatorname {\mathrm {Gal}} (L/k)$ to K. We compute

$$\begin{align*}\left( \widetilde{\sigma} (\sqrt{\theta_i}) \right)^2 = \widetilde{\sigma} (\theta_i) = \sigma (\theta_i). \end{align*}$$

Recalling that M is a multiplicative $\operatorname {\mathrm {Gal}} (L/k)$ -module, we have $\sqrt {\theta '} \in K$ for every element $\theta ' $ of M. Moreover, in additive notation, there exists $A=[a_{ij}] \in \mathrm {GL}_n (\mathbb {F}_2) $ satisfying

(3.3) $$ \begin{align} \sigma (\theta_1, \ldots , \theta_n ) = (\theta_1, \ldots , \theta_n) A. \end{align} $$

In particular, we obtain $\widetilde {\sigma } (\sqrt {\theta _i}) = \pm \sqrt {\sigma (\theta _i)} \in K$ . This shows that $K/ k $ is a Galois extension.

We have an exact sequence

induced from the restriction map. The Galois group $\operatorname {\mathrm {Gal}} (L/k )$ acts on $\operatorname {\mathrm {Gal}} (K/L)$ : for $\gamma \in \operatorname {\mathrm {Gal}} (K/L)$ and $\sigma \in \operatorname {\mathrm {Gal}} (L/k)$ , we choose an extension $\widetilde {\sigma }$ in $\operatorname {\mathrm {Gal}} (K/k )$ and we define $\sigma \cdot \gamma = \widetilde {\sigma } \gamma \widetilde {\sigma }^{-1}$ . This action is well defined because $\operatorname {\mathrm {Gal}} (K/L)$ is abelian.

For $\sigma \in \operatorname {\mathrm {Gal}} (L/k)$ , we define $s(\sigma ) \in \operatorname {\mathrm {Gal}} (K/k)$ by

$$\begin{align*}s (\sigma ) (\sqrt{\theta_1}, \ldots , \sqrt{\theta_n}) = (\sqrt{\theta_1}, \ldots , \sqrt{\theta_n}) A \end{align*}$$

with A defined in (3.3). It is easy to verify that this map s gives a splitting homomorphism and the above exact sequence splits.

By Kummer theory, there exists a bilinear nondegenerate pairing defined as

(3.4) $$ \begin{align} \langle \cdot , \cdot \rangle \ : \ \operatorname{\mathrm{Gal}} (K/L) \times M \longrightarrow \mu_2 \longrightarrow \mathbb{F}_2, \quad (\gamma, \theta ) \mapsto \frac{\gamma (\sqrt{\theta})}{\sqrt{\theta}}, \end{align} $$

where the map $\mu _2 \longrightarrow \mathbb {F}_2$ is an isomorphism whose inverse map is $\mathbb {F}_2 \ni x \mapsto (-1)^x$ . This yields an isomorphism

(3.5) $$ \begin{align} \operatorname{\mathrm{Gal}} (K/L) \cong \mathrm{Hom} (M, \mathbb{F}_2), \quad \gamma \mapsto \langle \gamma , \theta \rangle. \end{align} $$

Both the sides of (3.5) are $\operatorname {\mathrm {Gal}} (L/k )$ -modules. The action on the right-hand side is given by $\sigma ( \theta \mapsto \langle \gamma , \theta \rangle ) = ( \theta \mapsto \langle \gamma , \sigma \theta \rangle ) $ .

We shall show that $\operatorname {\mathrm {Gal}} (K/L)$ is an irreducible $\mathbb {F}_2 [\operatorname {\mathrm {Gal}} (L/k )]$ -module isomorphic to $\varepsilon _j \mathbb {F}_2 [\operatorname {\mathrm {Gal}} (L/k )]$ for some integer j prime to $2^n-1$ . Then, from Lemma 3.2, $\operatorname {\mathrm {Gal}} (K/k) \cong F_{2^n}$ follows. To do this end, we compute the action of $\sigma \in \operatorname {\mathrm {Gal}} (L/k)$ on $\operatorname {\mathrm {Gal}} (K/L)$ in terms of (3.3). In the above, we have shown that $\widetilde {\sigma }(\sqrt {\theta _i}) = \pm \sqrt {\sigma \theta _i}$ , and thus we can define $e_i \in \mathbb {F}_2$ by

$$\begin{align*}\widetilde{\sigma } (\sqrt{\theta_i}) = (-1)^{e_i} \sqrt{\sigma \theta_i}. \end{align*}$$

Using (3.3), we can compute further

$$\begin{align*}\widetilde{\sigma } (\sqrt{\theta_i}) = (-1)^{e_i} \prod_{j=1}^n \sqrt{\theta_j}^{a_{ji}}. \end{align*}$$

By writing $A^{-1} = [b_{ij}]$ , we have

$$\begin{align*}\widetilde{\sigma }^{-1} \sqrt{\theta_i} = (-1)^{f_i} \sqrt{\sigma^{-1} \theta_i} = (-1)^{f_i} \prod_{j=1}^n \sqrt{\theta_j}^{b_{ji}} \end{align*}$$

with some $f_i \in \mathbb {F}_2$ . The relation of $e_i$ ’s and $f_i$ ’s is derived by computing $\widetilde {\sigma } \, \widetilde {\sigma }^{-1} \left ( \sqrt {\theta _i} \right ) = \sqrt {\theta _i}$ . In fact, the left-hand side is equal to

$$\begin{align*}(-1)^{f_i} \widetilde{\sigma} \left( \prod_{j=1}^n \sqrt{\theta_j}^{b_{ji}} \right) = (-1)^{f_i} \prod_{j=1}^n (-1)^{e_j b_{ji}} \left( \prod_{k=1}^n \sqrt{\theta_j}^{a_{kj}} \right)^{b_{ji}} = (-1)^{f_i+ \sum_{j=1}^n e_j b_{ji} } \sqrt{\theta_i}. \end{align*}$$

Hence, we obtain

(3.6) $$ \begin{align} f_i+ \sum_{j=1}^n e_j b_{ji} =0 \text{ for all } i=1, \ldots , n. \end{align} $$

Now, let $(g_1, \ldots , g_n)$ be the dual basis of $\operatorname {\mathrm {Gal}} (K/L)$ with respect to the paring $\langle \cdot , \cdot \rangle $ . We compute the action $\sigma \cdot g_i$ on $\sqrt {\theta _j}:$

$$ \begin{align*} (\sigma \cdot g_i) \left( \sqrt{\theta_j} \right) &= \widetilde{\sigma} g_i \widetilde{\sigma}^{-1} \left( \sqrt{\theta_j} \right) = \widetilde{\sigma} g_i \left( (-1)^{f_j} \prod_{k=1}^n \sqrt{\theta_k}^{b_{kj}}\right) \\[6pt] &= (-1)^{f_j} \widetilde{\sigma} \left( (-1)^{b_{ij}} \prod_{k=1}^n \sqrt{\theta_k}^{b_{kj}}\right) = (-1)^{f_j + b_{ij}} \prod_{k=1}^n \left( \widetilde{\sigma} \sqrt{\theta_k}\right)^{b_{kj}} \\[6pt] &= (-1)^{f_j + b_{ij} + \sum_{k=1}^n e_k b_{kj}} \sqrt{\theta_j}. \end{align*} $$

Combining with (3.6), we have

$$\begin{align*}(\sigma \cdot g_i) \left( \sqrt{\theta_j} \right) = (-1)^{b_{ij}} \sqrt{\theta_j}. \end{align*}$$

This means that $\sigma $ acts on $\operatorname {\mathrm {Gal}} (K/L)$ by $A^{-1}$ . Therefore, $\operatorname {\mathrm {Gal}} (K/L)$ is isomorphic to an irreducible module $\varepsilon _{-i} \mathbb {F}_2 [\operatorname {\mathrm {Gal}} (L/k )]$ . Since $(-i, 2^n-1) =1$ , we conclude ${\operatorname {\mathrm {Gal}} (K/k) \cong F_{2^n}}$ .

This completes the proof of Theorem 3.3.▪

Proof This follows from the Kummer duality (3.4).▪

Proof We consider an irreducible module $M= (\theta , \sigma \theta , \sigma ^2 \theta , \sigma ^3 \theta )$ , which is isomorphic to $\mathbb {F}_2 [X] / \phi _1 (X) =\mathbb {F}_2 [X] /(X^4+X+1)$ . Hence, the action of $\sigma $ is given by the companion matrix A of $\phi _1 (X)$ :

$$\begin{align*}\sigma (\theta, \sigma (\theta), \sigma^2 (\theta ) , \sigma^3 (\theta)) = (\theta, \sigma (\theta), \sigma^2 (\theta ) , \sigma^3 (\theta)) \begin{bmatrix} 0 & 0 & 0 & 1 \\ 1 &0 &0 & 1 \\ 0 & 1 & 0 & 0 \\ 0 & 0 & 1 & 0 \end{bmatrix}. \end{align*}$$

Let $\boldsymbol {v}_i =A^i \boldsymbol {e}_1$ for $i=0,\ldots , 14$ . If we denote the element in $\widetilde {\mathbb {F}_2^{4}}$ corresponding to $\boldsymbol {v}_i$ by $\tilde {\boldsymbol {v}}_i$ , then the equivalence classes by Definition 4.1 are easily computed, and we have

$$\begin{align*}\tilde{\boldsymbol{v}}_1 = \tilde{\boldsymbol{v}}_4, \ \tilde{\boldsymbol{v}}_{2} = \tilde{\boldsymbol{v}}_8, \ \tilde{\boldsymbol{v}}_3 = \tilde{\boldsymbol{v}}_{14}, \ \tilde{\boldsymbol{v}}_5 = \tilde{\boldsymbol{v}}_{10}, \ \tilde{\boldsymbol{v}}_6 = \tilde{\boldsymbol{v}}_{13}, \ \tilde{\boldsymbol{v}}_9 = \tilde{\boldsymbol{v}}_{7}, \ \tilde{\boldsymbol{v}}_{11} = \tilde{\boldsymbol{v}}_{12}. \end{align*}$$

We further connect them by the equivalence relation in Definition 4.2:

$$\begin{align*}\tilde{\boldsymbol{v}}_i \sim \tilde{\boldsymbol{v}}_{15-i} \quad (i=1,\ldots , 7). \end{align*}$$

By combining these, it follows that the conjugacy classes of the quadratic extensions of $L (\sqrt {\theta })$ in K are

$$ \begin{align*} & \{ Q (\tilde{\boldsymbol{v}}_1), Q (\tilde{\boldsymbol{v}}_3), Q (\tilde{\boldsymbol{v}}_{11}) \}, \\[3pt] & \{ Q (\tilde{\boldsymbol{v}}_2), Q (\tilde{\boldsymbol{v}}_6), Q (\tilde{\boldsymbol{v}}_{9}) \}, \\[3pt] & \{ Q (\tilde{\boldsymbol{v}}_5) \}. \end{align*} $$

Therefore, we can choose $Q (\tilde {\boldsymbol {v}}_1)$ , $Q (\tilde {\boldsymbol {v}}_2)$ , $Q (\tilde {\boldsymbol {v}}_5)$ as representatives of the conjugacy classes. These fields are nothing but ones in the statement of the proposition.▪