Proof. For $1 \leq i \leq n$ set $K_i = (G_1)_{x,r_1,{r_1}/{2}}(G_2)_{x,r_2,{r_2}/{2}} \ldots (G_i)_{x,r_i,{r_i}/{2}}$ and $K_0=\{1\}$. We first prove by induction on $i$ that $\bigotimes _{j=1}^{i} V_{\omega _j}$ is an irreducible representation of $K_i$ via the action described in § 2.5. For $i=0$, we take $\bigotimes _{j=1}^{i} V_{\omega _i}$ to be the trivial one-dimensional representation and the statement holds. Now assume the induction hypothesis that $\bigotimes _{j=1}^{i-1} V_{\omega _{j}}$ is an irreducible representation of $K_{i-1}$. Suppose $V' \subset \big (\bigotimes _{j=1}^{i-1} V_{\omega _{j}}\big ) \otimes V_{\omega _i}$ is a non-trivial subspace that is $K_i$-stable. Since $K_{i-1}$ acts on $V_{\omega _i}$ via a character (times identity), the subspace $V'$ has to be of the form $\big (\bigotimes _{j=1}^{i-1} V_{\omega _{j}}\big ) \otimes V''$ for a $K_i$-stable non-trivial subspace $V''$ of $V_{\omega _i}$. However, since Heisenberg representations are irreducible, $V_{\omega _i}$ is irreducible as a representation of $(G_i)_{x,r_i,\frac {r_i}{2}} \subset K_i$, and therefore $V''=V_{\omega _i}$. Thus $\bigotimes _{j=1}^{i} V_{\omega _j}$ is an irreducible representation of $K_i$, and by induction the representation $\kappa$ is an irreducible representation of $K_n$.

Since $K_n$ acts trivially on $\rho$, every irreducible $\tilde K$-subrepresentation of $\tilde \rho =\rho \otimes \kappa$ has to be of the form $\rho ' \otimes \kappa$ for an irreducible subrepresentation $\rho '$ of $\rho$. As $\rho$ is irreducible when restricted to $(G_{n+1})_{[x]} \subset \tilde K$, we deduce that $\tilde \rho$ is an irreducible representation of $\tilde K$.

Proof. This is (part of) [Reference YuYu01, Theorem 9.4].

Proof Proof of Theorem 3.1

Recall that $\tilde \rho$ is irreducible by Lemma 3.3. Thus, in order to show that $\operatorname {c-ind}_{\tilde K}^{G(F)} \tilde \rho$ is irreducible, hence supercuspidal, we have to show that if $g \in G(F)$ such that

(1)\begin{equation} \operatorname{Hom}_{\tilde K \cap {{}^{g}\tilde K}}\big( ^{g}\tilde \rho|_{\tilde K \cap {{}^{g}\tilde K}}, \tilde \rho|_{\tilde K \cap {{}^{g}\tilde K}}\big) \neq \{0 \} , \end{equation}

then $g \in \tilde K$, where $^{g}\tilde K$ denotes $g\tilde K g^{-1}$ and $^{g}\tilde \rho (x)=\tilde \rho (g^{-1}xg)$.

Fix such a $g \in G(F)$ satisfying $\operatorname {Hom}_{\tilde K \cap {{}^{g}\tilde K}}\big ( ^{g}\tilde \rho, \tilde \rho \big ) \neq \{0 \}$, and define

\[ \tilde K_i = (G_1)_{x,{r_1}/{2}}(G_2)_{x,{r_2}/{2}} \ldots (G_i)_{x,{r_i}/{2}} \quad \text{and}\quad \tilde K_0 = \{ 1 \} . \]

We first prove by induction that $g \in \tilde K_n G_{n+1}(F)\tilde K_n$ using Lemma 3.4 (which is (part of) [Reference YuYu01, Theorem 9.4]). This is essentially [Reference YuYu01, Corollary 4.5], but we include a short proof for the convenience of the reader. Let $1 \leq i \leq n$ and assume the induction hypothesis that $g \in \tilde K_{i-1}G_{i}(F)\tilde K_{i-1}$, which is obviously satisfied for $i=1$. We need to show that $g \in \tilde K_{i}G_{i+1}(F)\tilde K_{i}$. Since $\tilde K_{i-1} \subset \tilde K_i \subset \tilde K$, we may assume without loss of generality that $g \in G_i(F)$. Recall that by construction $\rho |_{(G_i)_{x,r_i,({r_i}/{2})+}}= \operatorname {Id}$ and $\kappa |_{(G_i)_{x,r_i,({r_i}/{2})+}}=\prod _{j=1}^{n} \hat {\phi }_j \cdot \operatorname {Id}$. Thus by restriction of the action in (1) to $(G_i)_{x,r_i,({r_i}/{2})+} \cap {{}^{g}(G_i)_{x,r_i,({r_i}/{2})+}}$ we conclude that $g$ intertwines $(\prod _{j=1}^{n} \hat {\phi }_j)|_{(G_i)_{x,r_i,({r_i}/{2})+}}$. By the definition of $\hat {\phi }_j$ in § 2.5, we have that $\hat {\phi }_j|_{(G_i)_{x,r_i, ({r_i}/{2})+}}$ is trivial for $j>i$. Moreover, if $j < i$, then for $y\in (G_i)_{x,r_i,({r_i}/{2})+} \cap {{}^{g}(G_i)_{x,r_i,({r_i}/{2})+}}$ we have

(2)\begin{equation} {{}^{g}\hat{\phi}_j}(y)= \hat{\phi}_j(g^{{-}1}yg)=\phi_j(g^{{-}1}yg)=\phi_j(g^{{-}1})\phi_j(y)\phi_j(g)=\phi_j(y)=\hat{\phi}_j(y) . \end{equation}

Therefore we obtain that $g$ also intertwines $\hat {\phi }_i|_{(G_i)_{x,r_i,({r_i}/{2})+}}$. By Lemma 3.4 (which is (part of) [Reference YuYu01, Theorem 9.4]) we conclude that $g\in (G_i)_{x,{r_i}/{2}}G_{i+1}(F)(G_i)_{x,{r_i}/{2}}$, and hence $g \in \tilde K_i G_{i+1}(F)\tilde K_i$. This finishes the induction step and therefore we have shown that $g \in \tilde K_nG_{n+1}(F)\tilde K_n$.

In order to prove that $g \in \tilde K$, we may therefore assume without loss of generality that $g \in G_{n+1}(F)$, and it suffices to prove that then $g \in (G_{n+1})_{[x]}$. Let us assume the contrary, that $g \in G_{n+1}(F)-(G_{n+1})_{[x]}$, or, equivalently, that the images of $g.x$ and $x$ in $\mathscr {B}(G_{n+1}^\textrm {{der}}, k)$ are distinct. Let $f$ be an element of $\operatorname {Hom}_{\tilde K \cap {{}^{g}\tilde K}}\big (^{g}\tilde \rho, {\tilde \rho }\big ) - \{0\}$. We denote its image in the space $V_{\tilde \rho }$ of the representation of $\tilde \rho$ by $V_f$. We write $H_{n+1}$ for the derived subgroup $G_{n+1}^{\text {der}}$ of $G_{n+1}$ and denote by $(H_{n+1})_{x,r}$ the Moy–Prasad filtration subgroup of depth $r \in \mathbb {R}_{\geq 0}$ at the image of $x$ in $\mathscr {B}(H_{n+1},F)$. Then $^{g}(H_{n+1})_{x,0}=(H_{n+1})_{g.x,0}$, and we have

(3)\begin{equation} f \in \operatorname{Hom}_{\tilde K \cap {{}^{g}\tilde K}}\big(^{g}\tilde \rho, {\tilde \rho}\big) - \{0\} \subset \operatorname{Hom}_{(H_{n+1})_{x,0} \cap {(H_{n+1})_{g.x,0}}}\big(^{g}\tilde \rho, {\tilde \rho}\big) - \{0\} . \end{equation}

By construction $\tilde \rho |_{(H_{n+1})_{x,0+}}=\hat {\phi }|_{(H_{n+1})_{x,0+}} \cdot \operatorname {Id} = \phi |_{(H_{n+1})_{x,0+}} \cdot \operatorname {Id}$, where

\[ \hat{\phi} := \prod_{i=1}^{n} \hat{\phi}_i|_{(G_{n+1})_{[x]}G_{x,({r_1}/{2})+}}\quad \text{and}\quad \phi:=\prod_{i=1}^{n} \phi_i|_{G_{n+1}(F)}. \]

In addition, for all $y \in (H_{n+1})_{g.x,0+}$ we have $^{g}\tilde \rho (y)=\hat \phi (g^{-1}yg)=\prod _{i=1}^{n} \phi _i(g^{-1}yg)=\prod _{i=1}^{n} \phi _i(y)=\phi (y)$, because $g \in G_{n+1}(F)$. Hence, by (3), the action of

\[ U:=((H_{n+1})_{x,0} \cap {(H_{n+1})_{g.x,0+}})(H_{n+1})_{x,0+} \]

on the image $V_f$ of $f$ via ${\tilde \rho }$ is given by $\phi \cdot \operatorname {Id}$.

Recall that the image of $x$ in $\mathscr {B}(H_{n+1}, k)$ is a vertex by condition (ii) of the input in § 2.1. Hence the group $(((H_{n+1})_{x,0} \cap {(H_{n+1})_{g.x,0+}})(H_{n+1})_{x,0+})/(H_{n+1})_{x,0+}$ is the ($\mathbb {F}_q$-points of) a unipotent radical of a (proper) parabolic subgroup of $(H_{n+1})_{x,0}/(H_{n+1})_{x,0+}$. We denote this subgroup by $\bar {U}$.

In the remainder of the proof we exhibit a subspace $V_\kappa ' \subset V_\kappa$ such that $V_f \subset V_\rho \otimes V_\kappa '$ and prove that the action of ${U}$ on $V_\kappa '$ via $\kappa$ is given by $\phi \cdot \operatorname {Id}$. Hence, since ${U}$ also acts via $\phi \cdot \operatorname {Id}$ on $V_f \subset V_\rho \otimes V_\kappa '$, we deduce that $(\rho |_{\bar {U}}, V_\rho )$ contains the trivial representation, which contradicts that $\rho |_{(G_{n+1})_{x,0}}$ is cuspidal (see condition (iii) of the input in § 2.1).

Let $T$ be a maximal torus of $G$ that splits over a tamely ramified extension $E$ of $F$ such that $x$ and $g.x$ are contained in $\mathscr {A}(T,E)$. (Such a torus exists by Remark 2.2.) Let $\lambda \in X_*(T) \otimes _\mathbb {Z}\mathbb {R}=\operatorname {Hom}_{\bar F}(\mathbb {G}_m,T_{\bar F}) \otimes _\mathbb {Z} \mathbb {R}$ such that $g.x = x + \lambda$, and observe that $\bar {U}$ is the image of

(4)\begin{equation} U_{n+1}:=H_{n+1}(F) \cap \big\langle U_\alpha(E)_{x,0} \, | \, \alpha \in \Phi(G_{n+1}, T), \lambda(\alpha) >0 \big\rangle \end{equation}

in $(H_{n+1})_{x,0}/(H_{n+1})_{x,0+}$. We define, for $1 \leq i \leq n$,

\[ U_i:= G(F) \cap \big\langle U_\alpha(E)_{x,{r_i}/{2}} \, | \, \alpha \in \Phi(G_i, T)-\Phi(G_{i+1}, T), \lambda(\alpha) >0 \big\rangle . \]

Note that ${{}^{g}(G_i)_{x,r_i,({r_i}/{2})+}}=(G_i)_{g.x,r_i,({r_i}/{2})+}$ and $U_i \subset (G_i)_{x,r_i,{r_i}/{2}} \cap (G_i)_{g.x,r_i,({r_i}/{2})+} \subset \tilde K \cap {{}^{g}\tilde K}$. More precisely, $U_i \subset (G_i)_{g.x,r_i+,({r_i}/{2})+}$, hence ${{}^{{g}^{-1}}U_i} \subset (G_i)_{x,r_i+,({r_i}/{2})+}$ and $\hat {\phi }_j|_{{{}^{{g}^{-1}}U_i}}$ is trivial for $j \geq i$. Thus, by (2), we obtain that $^{g}\tilde \rho |_{U_i} = \prod _{j=1}^{i-1} \hat \phi _j \cdot \operatorname {Id}$. Hence $U_i$ acts on $V_f$ via the character $\prod _{j=1}^{i-1} {\hat \phi _j}|_{U_i}=\prod _{1 \leq j \leq n \atop j \neq i} {\hat \phi _j}|_{U_i}$. Since $U_i$ acts trivially via $\rho$ on the space $V_\rho$ underlying the representation of $\rho$ and $U_i$ acts via $\prod _{1 \leq j \leq n \atop j \neq i} {\hat \phi _j}|_{U_i}$ on $\bigotimes _{1 \leq j \leq n \atop j \neq i} V_{\omega _j}$, we obtain

\[ V_f \subset V_\rho \otimes \bigotimes_{j=1}^{i-1} V_{\omega_j} \otimes V_{\omega_i}^{U_i} \otimes \bigotimes_{j=i+1}^{n} V_{\omega_j} \subset V_\rho \otimes \bigotimes_{i=1}^{n} V_{\omega_i} = V_\rho \otimes V_\kappa \]

for $1 \leq i \leq n$. Hence we deduce that $V_f \subset V_\rho \otimes \bigotimes _{i=1}^{n} V_{\omega _i}^{U_i}$. We will see that $\bigotimes _{i=1}^{n} V_{\omega _i}^{U_i}$ is the subspace $V_\kappa ' \subset V_\kappa$ that we are looking for.

In order to study the subspace $V_{\omega _i}^{U_i}$ for $1 \leq i \leq n$, we recall that we write $V_i=(G_i)_{x,r_i,{r_i}/{2}}/(G_i)_{x,r_i,({r_i}/{2})+}$ and equip $V_i$ with the pairing $\big \langle \cdot, \cdot \big \rangle _i$ defined by $\big \langle a,b\big \rangle _i=\hat {\phi }_i(aba^{-1}b^{-1})$ (using the above fixed identification of the $p$th roots of unity in $\mathbb {C}^{*}$ with $\mathbb {F}_p$). We define the space $V_i^{+}$ to be the image of $U_i= G(F) \cap \big \langle U_\alpha (E)_{x,{r_i}/{2}} \, | \, \alpha \in \Phi (G_i, T)-\Phi (G_{i+1}, T), \lambda (\alpha )>0 \big \rangle$ in $V_i$, the space $V_i^{0}$ to be the image of $G(F) \cap \big \langle U_\alpha (E)_{x,{r_i}/{2}} \, | \, \alpha \in \Phi (G_i, T)-\Phi (G_{i+1}, T), \lambda (\alpha )=0 \big \rangle$ in $V_i$, and $V_i^{-}$ to be the image of $G(F) \cap \big \langle U_\alpha (E)_{x,{r_i}/{2}} \, | \, \alpha \in \Phi (G_i, T)-\Phi (G_{i+1}, T), \lambda (\alpha )<0 \big \rangle$ in $V_i$. Then $V_i=V_i^{+} \oplus V_i^{0} \oplus V_i^{-}$ and the $\mathbb {F}_p$-vector subspaces $V_i^{+}$ and $V_i^{-}$ are both totally isotropic. Since $\phi _i$ is $G_i$-generic of depth $r_i$ relative to $x$ the orthogonal complement of $V_i^{+}$ is $V_i^{+} \oplus V_i^{0}$, the orthogonal complement of $V_i^{-}$ is $V_i^{0} \oplus V_i^{-}$, and $V_i^{0}$ is a non-degenerate subspace of $V_i$. We denote by $P_i \subset \operatorname {Sp}(V_i)$ the (maximal) parabolic subgroup of $\operatorname {Sp}(V_i)$ that preserves the subspace $V_i^{+}$ and that therefore also preserves $V_i^{+} \oplus V_i^{0}$. We obtain a surjection $\operatorname {pr}_{i,0}: P_i \twoheadrightarrow \operatorname {Sp}(V_i^{0})$ by composing restriction to $V_i^{0}$ with projection from $V_i^{+} \oplus V_i^{0}$ to $V_i^{0}$ with kernel $V_i^{+}$. Note that the image $\bar {U}_{\operatorname {Sp}(V_i)}$ of $\bar {U}$ in $\operatorname {Sp}(V_i)$ is contained in $P_i$ and that $\operatorname {pr}_{i,0}(\bar {U}_{\operatorname {Sp}(V_i)})=\operatorname {Id}_{V_i^{0}}$.

Recall that $V_i^{\sharp }$ is the Heisenberg group with underlying set $V_i \times \mathbb {F}_p$ that is attached to the symplectic $\mathbb {F}_p$-vector space $V_i$ with pairing $\big \langle \cdot, \cdot \big \rangle _i$, and note that the subset $V_i^{0} \times \mathbb {F}_p \subset V_i \times \mathbb {F}_p$ forms a subgroup, which is the Heisenberg group $(V_i^{0})^{\sharp }$ attached to the symplectic vector space $V_i^{0}$ with the (restriction of the) pairing $\big \langle \cdot, \cdot \big \rangle _i$. We denote by $V_{\omega _i}^{0}$ a Weil–Heisenberg representation of $\operatorname {Sp}(V_i^{0}) \ltimes (V_i^{0})^{\sharp }$ corresponding to the same central character as the central character of $V_i^{\sharp }$ acting on $V_{\omega _i}$ (which in turn corresponds to the character $\hat {\phi }_i|_{(G_i)_{x,r_i,({r_i}/{2})+}}$ via the special isomorphism $j_i$). By [Reference GérardinGér77, Theorem 2.4(b)] the restriction of the Weil–Heisenberg representation $V_{\omega _i}$ from $\operatorname {Sp}(V_i) \ltimes V_i^{\sharp }$ to $P_i \ltimes V_i^{\sharp }$ is given by

\[ \operatorname{Ind}_{P_i \ltimes ( V_i^{+} \times (V_i^{0})^{\sharp})}^{P_i \ltimes V_i^{\sharp}} V_{\omega_i}^{0} \otimes (\mathbb{C}_{\chi^{V_i^{+}}} \ltimes 1), \]

where the group $P_i \ltimes ( V_i^{+} \times (V_i^{0})^{\sharp })$ acts on $V_{\omega _i}^{0}$ by composing the projection

\[ \operatorname{pr}_{i,0} \ltimes (\operatorname{pr}_{{+}0,0} ): P_i \ltimes ( V_i^{+} \times (V_i^{0})^{\sharp}) \rightarrow \operatorname{Sp}(V_i^{0}) \ltimes (V_i^{0})^{\sharp} \]

(where $\operatorname {pr}_{+0,0}: ( V_i^{+} \times (V_i^{0})^{\sharp }) \twoheadrightarrow (V_i^{0})^{\sharp }$ denotes the projection with kernel $V_i^{+}$) with the Weil–Heisenberg representation of $\operatorname {Sp}(V_i^{0}) \ltimes (V_i^{0})^{\sharp }$, and $\mathbb {C}_{\chi ^{V_i^{+}}}$ is a one-dimensional space on which the action of $P_i$ is given by a quadratic characterFootnote ² $\chi ^{V_i^{+}}$ that factors through the projection $\operatorname {pr}_{i,+}: P_i \rightarrow \operatorname {GL}(V_i^{+})$ obtained by restricting elements in $P_i$ to $V_i^{+}$.

Let $\bar U_{i}$ be the image of $U_i$ in the Heisenberg group $(G_i)_{x,r_i,{r_i}/{2}}/\big ((G_i)_{x,r_i,({r_i}/{2})+} \cap \ker (\hat {\phi }_i)\big )$. Then by Yu's construction of the special isomorphism $j_i:(G_i)_{x,r_i,{r_i}/{2}}/\big ((G_i)_{x,r_i,({r_i}/{2})+} \cap \ker (\hat {\phi }_i)\big ) \rightarrow V_i^{\sharp }$ in [Reference YuYu01, Proposition 11.4], we have $j_i(\bar U_{i})=V_i^{+} \times 0 \subset V_i \times \mathbb {F}_p$. Since the orthogonal complement of $V_i^{-}$ is $V_i^{0} \oplus V_i^{-}$, and hence for every element $v_- \in V_i^{-}$ there exists $v_+ \in V_i^{+}$ such that $\big \langle v_-,v_+\big \rangle _i \neq 0$, we have

(5)\begin{equation} \Big(\operatorname{Ind}_{P_i \ltimes ( V_i^{+} \times (V_i^{0})^{\sharp})}^{P_i \ltimes V_i^{\sharp}} V_{\omega_i}^{0} \otimes (\mathbb{C}_{\chi^{V_i^{+}}} \ltimes 1)\Big)^{1 \ltimes (V_i^{+} \times 0)} \simeq V_{\omega_i}^{0} \otimes (\mathbb{C}_{\chi^{V_i^{+}}} \ltimes 1) \end{equation}

as a representation of $P_i$.

Note that the image of $\bar {U}_{\operatorname {Sp}(V_i)}$ in $\operatorname {GL}(V_i^{+})$ under the projection $\operatorname {pr}_{i,+}:P_i \rightarrow \operatorname {GL}(V_i^{+})$ is unipotent since $\bar {U}$ is unipotent. Hence $\operatorname {pr}_{i,+}(\bar {U}_{\operatorname {Sp}(V_i)})$ is contained in the commutator subgroup of $\operatorname {GL}(V_i^{+})$, and $\chi ^{V_i^{+}}|_{\operatorname {pr}_{i,+}(\bar {U}_{\operatorname {Sp}(V_i)})}$ is trivial. Moreover, we observed above that $\operatorname {pr}_{i,0}(\bar {U}_{\operatorname {Sp}(V_i)})=\operatorname {Id}_{V_i^{0}}$. Thus $\bar {U}_{\operatorname {Sp}(V_i)}$ acts trivially on $V_{\omega _i}^{0} \otimes (\mathbb {C}_{\chi ^{V_i^{+}}} \ltimes 1)$.

Recall that the action of ${U}$ on $(V_{\omega _i})^{U_i}$ is given by the product of $\phi _i|_{U}$ with the above Weil representation construction; see § 2.5. Hence ${U}$ acts on $(V_{\omega _i})^{U_i}$ via the character $\phi _i|_{U}$. Since we proved above that ${U}$ acts via $\phi =\prod _{i=1}^{n} \phi _i$ on $V_f \subset V_\rho \otimes \bigotimes _{i=1}^{n} (V_{\omega _i})^{U_i}$, we deduce that there exists a non-trivial subspace $V_{\rho,f}$ of $V_\rho$ on which ${U}$ acts trivially. Hence $\rho |_{\bar {U}}$ contains the trivial representation, which contradicts that $\rho |_{(G_{n+1})_{x,0}}$ is cuspidal.

Proof. First note that $X$ is $G'$-invariant by construction. Let $\sqrt {2\varpi }$ in $F^{\mathrm {sep}}$ such that $\sqrt {2\varpi }^{2}=2 \varpi$. We consider the maximal torus

\[ T'= \begin{pmatrix} \frac{\varpi}{\sqrt{2\varpi}} & 0_{1 \times 8} & \frac{-\varpi }{\sqrt{2\varpi}}\\ 0_{8 \times 1} & 1_{8\times 8} & 0_{8 \times 1} \\ \frac{1}{\sqrt{2\varpi}} & 0_{1 \times 8} & \frac{1}{\sqrt{2\varpi}} \\ \end{pmatrix} T \begin{pmatrix} \frac{1}{{\sqrt{2\varpi}}} & 0_{1 \times 8} & \frac{\varpi}{\sqrt{2\varpi}} \\ 0_{8 \times 1} & 1_{8\times 8} & 0_{8 \times 1} \\ \frac{-1}{{\sqrt{2\varpi}}} & 0_{1 \times 8} & \frac{\varpi}{\sqrt{2\varpi}} \\ \end{pmatrix} \]

of $G'$. Then the set $\{H_{\alpha }=d\check \alpha (1) \, | \, \alpha \in \Phi (G, T') \setminus \Phi (G',T')\}$, where $\check \alpha$ denotes the dual root of $\alpha$, is given by

\[{\pm} \begin{pmatrix} 0 & 0_{1 \times 8} & \varpi \\ 0_{8 \times 1} & 0_{8\times 8} & 0_{8 \times 1} \\ \varpi^{{-}1} & 0_{1 \times 8} & 0 \\ \end{pmatrix} \]

and sums of the former with a diagonal matrix of the form

\begin{gather*} \pm \operatorname{diag}(0,1,0,0,0,0,0, 0,-1,0), \quad \pm \operatorname{diag}(0,0,1,0,0,0,0,-1,0,0), \\ \pm \operatorname{diag}(0,0,0,1,0,0,-1,0,0,0), \quad \pm \operatorname{diag}(0,0,0,0,1,-1,0,0,0,0) . \end{gather*}

Hence $\operatorname {val}(X(H_\alpha ))=\operatorname {val}(\pm 2\varpi ^{-1})=-\frac {1}{2}$ for all $\alpha \in \Phi (G, T') \setminus \Phi (G',T')$, where $\operatorname {val}$ denotes the valuation of $F$ with image $\mathbb {Z}\cup \{\infty \}$. Moreover, $X$ is contained in $(\mathfrak {g}')^{*}_{y,-{1}/{2}}$ for any point $y \in \mathscr {B}(G', F)$ and its restriction to the Lie algebra of the identity component $Z(G')^{\circ }$ of the center of $G'$ is contained in $\operatorname {Lie}^{*}(Z(G')^{\circ })_{-{1}/{2}}$. Since $p>10$, that is, $p$ does not divide the order of the Weyl group of $\operatorname {Sp}_{10}$, we conclude that $X$ is $G$-generic of depth $\frac {1}{2}$.

Let $E$ be a finite, tamely ramified extension of $F$ that contains $\sqrt {2\varpi }$. Then $x$ is a vertex in $\mathscr {B}(G,E)$ and it is an easy calculation to check that

\[ G_{x,0}(E)=\begin{pmatrix} \frac{\varpi}{\sqrt{2\varpi}} & 0_{1 \times 8} & \frac{-\varpi }{\sqrt{2\varpi}}\\ 0_{8 \times 1} & 1_{8\times 8} & 0_{8 \times 1} \\ \frac{1}{\sqrt{2\varpi}} & 0_{1 \times 8} & \frac{1}{\sqrt{2\varpi}} \\ \end{pmatrix} G_{y,0}(E) \begin{pmatrix} \frac{1}{{\sqrt{2\varpi}}} & 0_{1 \times 8} & \frac{\varpi}{\sqrt{2\varpi}} \\ 0_{8 \times 1} & 1_{8\times 8} & 0_{8 \times 1} \\ \frac{-1}{{\sqrt{2\varpi}}} & 0_{1 \times 8} & \frac{\varpi}{\sqrt{2\varpi}} \\ \end{pmatrix} \]

for the point $y=(0,0,0,\frac {1}{4},\frac {1}{4}) \in \mathscr {A}(T,F) \subset \mathscr {A}(T,E)$. Hence

\[ x=\begin{pmatrix} \frac{\varpi}{\sqrt{2\varpi}} & 0_{1 \times 8} & \frac{-\varpi }{\sqrt{2\varpi}}\\ 0_{8 \times 1} & 1_{8\times 8} & 0_{8 \times 1} \\ \frac{1}{\sqrt{2\varpi}} & 0_{1 \times 8} & \frac{1}{\sqrt{2\varpi}} \\ \end{pmatrix}.y, \]

which implies $x \in \mathscr {A}(T', E) \subset \mathscr {B}(G', E)$, and therefore $x \in \mathscr {B}(G', E) \cap \mathscr {B}(G, F) =\mathscr {B}(G',F)$.

Proof. Using the standard coordinates we define the groups

\[ {H_{23}}:= \begin{pmatrix} 1 & 0 & 0 & 0 & 0 \\ 0 & \operatorname{GL}_2(\mathcal{O}) & 0 & 0 & 0 \\ 0 & 0 & 1_{4 \times 4} & 0 & 0 \\ 0 & 0 & 0 & \operatorname{GL}_2(\mathcal{O}) & 0 \\ 0 & 0 & 0 & 0 & 1 \\ \end{pmatrix} \cap \operatorname{Sp}_{10}(F) \subset G'_{x,0}, \]

\[ {H_{45}}:= \begin{pmatrix} 1_{3\times 3} & 0 & 0 & 0 \\ 0 & \operatorname{GL}_2(\mathcal{O}) & 0 & 0 \\ 0 & 0 & \operatorname{GL}_2(\mathcal{O}) & 0 \\ 0 & 0 & 0 & 1_{3\times 3} \\ \end{pmatrix} \cap \operatorname{Sp}_{10}(F) \subset G'_{x,0}. \]

Note that ${H_{23}} \simeq \operatorname {GL}_2(\mathcal {O}) \simeq {H_{45}}$, and $g{H_{23}}g^{-1}={H_{45}}$ and $g{H_{45}}g^{-1}={H_{23}}$, hence ${H_{23}} \in K \cap {{}^{g}K}$. Moreover, the image of ${H_{23}}$ and the image of ${H_{45}}$ in $G'_{x,0}/G'_{x,0+}$ are both isomorphic to $\operatorname {GL}_2(\mathbb {F}_p)$.

We will show that $\dim \operatorname {Hom}_{{H_{23}}}({{}^{g}\tilde {\phi }}, \tilde {\phi })=0$, which implies that $\dim \operatorname {Hom}_{({K\cap {{}^{g}K}}) \ltimes ({J \cap {{}^{g}J}})}({{}^{g}\tilde {\phi }}, \tilde {\phi }) = 0$.

We write $V=J/J_+$, where we recall that

\[ J=(G',G)(F)_{x,({1}/{2},{1}/{4})} \quad\text{and}\quad J_+{=}(G',G)(F)_{x,({1}/{2},({1}/{4})+)}. \]

Let $\mathfrak {g}(\mathcal {O})$ be the $\mathcal {O}$-points of the Lie algebra of the reductive parahoric group scheme over $\mathcal {O}$ corresponding to the base point $(0,0,0,0,0)$, that is, the Lie algebra of $\operatorname {Sp}_{10}$ defined over $\mathcal {O}$ in the standard basis. We denote by $\mathfrak {g}(\mathcal {O})_{t_1t_2^{-1}}$ the submodule of $\mathfrak {g}(\mathcal {O})$ corresponding to the root $\operatorname {diag}(t_1, t_2, t_3, t_4, t_5, t_5^{-1}, t_4^{-1}, t_3^{-1}, t_2^{-1}, t_1^{-1}) \mapsto t_1t_2^{-1}$, and analogously for all other indices. Then the four-dimensional $\mathbb {F}_p$-vector space $V$ is spanned by the images of

\[ \mathfrak{g}(\mathcal{O})_{t_1^{{-}1}t_2} , \quad \mathfrak{g}(\mathcal{O})_{t_1^{{-}1}t_3} , \quad \mathfrak{g}(\mathcal{O})_{t_1^{{-}1}t_2^{{-}1}} , \quad \mathfrak{g}(\mathcal{O})_{t_1^{{-}1}t_3^{{-}1}} . \]

Each of these images is a one-dimensional $\mathbb {F}_p$-vector subspace of $V$, which we denote by $V_{t_2}$, $V_{t_3}$, $V_{t_2^{-1}}$ and $V_{t_3^{-1}}$, respectively. The pairing on $V=J/J_+$ defined by $\big \langle a,b\big \rangle =\hat {\phi }(aba^{-1}b^{-1})$ for $a, b \in J$,turns $V$ into a symplectic $\mathbb {F}_p$-vector space, and $V^{+}:=V_{t_2} \oplus V_{t_3}$ and $V^{-}:=V_{t_2^{-1}} \oplus V_{t_3^{-1}}$ are both maximal isotropic subspaces. Recall that $\tilde {\phi }$ is defined to be the pullback to $K\ltimes J$ of the Weil–Heisenberg representation of $\operatorname {Sp}(V) \ltimes (J/N)$ via the symplectic action defined in [Reference YuYu01, Proposition 11.4]. Hence the actions of ${H_{23}}$ and ${H_{45}}$ on $\tilde {\phi }$ factor through $\operatorname {Sp}(V)$, and therefore ${H_{45}}$ acts trivially on $\tilde {\phi }$. Thus $^{g}\tilde {\phi }|_{{H_{23}}}={{}^{g}\tilde {\phi }}|_{g{H_{45}}g^{-1}}$ is trivial, and in order to prove that $\dim \operatorname {Hom}_{{H_{23}}}({{}^{g}\tilde {\phi }}, \tilde {\phi })=0$ it suffices to show that the representation $\tilde {\phi }|_{{H_{23}}}$ has no non-zero ${H_{23}}$-fixed vector.

We denote by $P$ the parabolic subgroup of $\operatorname {Sp}(V)$ that preserves $V^{+}$. Then the image of ${H_{23}}$ in $\operatorname {Sp}(V)$ is the Levi subgroup $M\simeq \operatorname {GL}(V^{+})\simeq \operatorname {GL}(V^{-})$ of $P$ that stabilizes $V^{+}$ and $V^{-}$. Recall that we denote by $V^{\sharp }$ the group with underlying set $V \times \mathbb {F}_p$ and with group law $(v,a).(v',a')=(v+v', a+a'+\frac {1}{2}\big \langle v,v'\big \rangle )$. By [Reference GérardinGér77, Theorem 2.4(b)] the restriction of the Weil–Heisenberg representation from $\operatorname {Sp}(V) \ltimes V^{\sharp }$ to $P \ltimes V^{\sharp }$ is given by

\[ \pi:= \operatorname{Ind}_{P \ltimes (V^{+} \times \mathbb{F}_p)}^{P \ltimes V^{\sharp}} \chi^{V^{+}} \ltimes \phi, \]

where $\chi ^{V^{+}}$ is the characterFootnote ³ of $P$ given by $P \ni p \mapsto \det (p|_{V^{+}})^{({p-1})/{2}} \in \{ \pm 1\} \subset \mathbb {C}^{*}$ and by an abuse of notation we denote by $\phi$ the (restriction to $V^{+} \times \mathbb {F}_p$ of the) character $\phi \circ j^{-1}$, where $j:J/N \xrightarrow {\simeq } V^{\sharp }$ denotes the special isomorphism from [Reference YuYu01, Proposition 11.4].

Let $f: P \ltimes V^{\sharp } \rightarrow \mathbb {C}$ be an element of the representation space of $\pi$ and suppose that $f$ is non-zero and $M$-invariant. Hence there exists $v \in V^{-}$ such that $f(1 \ltimes v) \neq 0$. Let $v' \in V^{-}$ so that $v$ and $v'$ form a basis of $V^{-}$ and let $m=\big (\begin {smallmatrix} 1 & 0 \\ 0 & a \end {smallmatrix}\big ) \in \operatorname {GL}(V^{-})$ using the basis $(v, v')$ where $a \in \mathbb {F}_p$ such that $a^{({p-1})/{2}}=-1$. Identifying $\operatorname {GL}(V^{-})$ with $M$ (via the action of $M$ on $V^{-}$), we obtain that

\begin{align*} f(1\ltimes v) &= m.f(1 \ltimes v)=f((1 \ltimes v)(m \ltimes 1))=f((m \ltimes 1)(1 \ltimes m^{{-}1}.v)) \\ &=\chi^{V^{+}}(m)f(1 \ltimes m^{{-}1}.v) = \det(m|_{V^{+}})^{({p-1})/{2}}f(1 \ltimes v)=\det(m|_{V^{-}})^{({p-1})/{2}}f(1 \ltimes v)\\ &={-}f(1 \ltimes v). \end{align*}

This contradicts that $f(1 \ltimes v) \neq 0$, hence the representation $\pi$ does not contain any non-zero element fixed under the action of $M$. Therefore $\tilde {\phi }$ does not contain any non-zero element fixed under the action of ${H_{23}}$. Thus $\dim \operatorname {Hom}_{{H_{23}}}({{}^{g}\tilde {\phi }}, \tilde {\phi })=0$.

Proof. This follows from the fact that $KJ \cap {{}^{g}(KJ)}=(K \cap {{}^{g}K})(J \cap {{}^{g}J})$ [Reference YuYu01, Lemma 13.7] as discussed in [Reference YuYu01] in the lines immediately following Theorem 14.2.