1 Introduction
1.1 Background
A basic but important question in the representation theory of p-adic groups is to study the category of complex smooth representations
$\operatorname {Rep}(G)$
, where G is a reductive group over a non-archimedean locally compact field F of residual characteristic p. In [Reference Bernstein and Deligne7], Bernstein developed a block decomposition
$$ \begin{align*}\operatorname{Rep}(G)=\prod_{\mathfrak{s}}\operatorname{Rep}_{\mathfrak{s}}(G),\end{align*} $$
where each
$\mathfrak {s}$
in the product consists of (the G-conjugacy class of) a Levi subgroup M of G and an orbit
$\mathcal {O}$
of a cuspidal representation
$\pi _{0}$
of M twisted by unramified characters of M, and
$\operatorname {Rep}_{\mathfrak {s}}(G)$
is the subcategory of
$\operatorname {Rep}(G)$
consisting of smooth representations having the inertial cuspidal support
$\mathfrak {s}$
.
The so-called ‘type theory’, justifying the title of this paper, dates back to the seminal work of Bushnell-Kutzko [Reference Bushnell and Kutzko22], which depicts a general strategy to describe
$\operatorname {Rep}_{\mathfrak {s}}(G)$
for an inertial equivalence class
$\mathfrak {s}=(M,\mathcal {O})$
. A type of
$\operatorname {Rep}_{\mathfrak {s}}(G)$
, in their sense, consists of an open compact subgroup J of G and an irreducible representation
$\lambda $
of J, such that the restriction of any representation
$\pi \in \operatorname {Rep}_{\mathfrak {s}}(G)$
to J contains
$\lambda $
(cf. §3.3 for a precise definition). Once a type
$(J,\lambda )$
of
$\operatorname {Rep}_{\mathfrak {s}}(G)$
exists, an equivalence of categories could be defined
$$ \begin{align*}\boldsymbol{\mathrm{M}}_{\lambda}:\operatorname{Rep}_{\mathfrak{s}}(G)\rightarrow\operatorname{Mod}(\mathcal{H}(G,\lambda)),\quad\pi\mapsto\operatorname{Hom}_{G}(\operatorname{ind}_{J}^{G}\lambda,\pi),\end{align*} $$
where
$\operatorname {ind}_{J}^{G}\lambda $
denotes the compact induction of
$\lambda $
as a representation of G, and
$\operatorname {Mod}(\mathcal {H}(G,\lambda ))$
denotes the category of nondegenerate modules of the Hecke algebra
$\mathcal {H}(G,\lambda )$
. More precisely, they proposed a general strategy, which is divided into two following questions:
-
(1) Construct a type
$(J_{M},\lambda _{M})$
of
$\operatorname {Rep}_{\mathfrak {s}_{M}}(M)$
, where
$\mathfrak {s}_{M}$
denotes the corresponding inertial equivalence class of M consisting of the same data of
$\mathfrak {s}$
. -
(2) Construct a type
$(J,\lambda )$
of
$\operatorname {Rep}_{\mathfrak {s}}(G)$
based on
$(J_{M},\lambda _{M})$
. Usually,
$(J,\lambda )$
could be chosen as a so-called ‘covering pair’ of
$(J_{M},\lambda _{M})$
.
We remark that the question (1), albeit innocent-looking, relates to the extremely difficult folklore conjecture that every cuspidal representation of M could be constructed from the compact induction of an irreducible representation of an open compact modulo center subgroup. Once being constructed in a certain way, the uniqueness of
$(J_{M},\lambda _{M})$
up to M-conjugacy is also quite intriguing and worth pursuing (for instance, see [Reference Bushnell and Kutzko19]). Finally, the subsequent question is obviously
-
(3) Describe
$\mathcal {H}(G,\lambda )$
and
$\operatorname {Mod}(\mathcal {H}(G,\lambda ))$
.
The rough expectation is that each
$\mathcal {H}(G,\lambda )$
should not be far from a certain affine Hecke algebra. We leave §3 for the missing details in this paragraph.
We are trying to give a historical summary, which, due to the ignorance of the author, could be quite partial and by no means complete. Beside some sporadic results for low rank groups G, perhaps the first foundational result is due to Howe [Reference Howe41], where he gave the full answer to the question (1) in the case
$G=\operatorname {GL}_{r}(F)$
and p greater that r. Under the same condition, questions (2) and (3) were also subsequently answered; see [Reference Howe and Moy40], [Reference Waldspurger75]. After that, two main streamlines occurred: the first one dealt with special groups G and all the blocks
$\operatorname {Rep}_{\mathfrak {s}}(G)$
, while the second one dealt with rather general groups and blocks
$\operatorname {Rep}_{\mathfrak {s}}(G)$
with certain restrictions.
We describe the first streamline. A milestone is the work of Bushnell-Kutzko [Reference Bushnell and Kutzko19], [Reference Bushnell and Kutzko22], [Reference Bushnell and Kutzko23], where they completely answered the three questions above for
$G=\operatorname {GL}_{r}(F)$
. They gave an explicit construction for a cuspidal representation of any Levi subgroup of G, influenced by and generalizing the work of Howe [Reference Howe41] and Carayol [Reference Carayol24]. In particular, the corresponding Hecke algebra
$\mathcal {H}(G,\lambda )$
is indeed an affine Hecke algebra of type A, which provides another aspect of the classification result of Bernstein and Zelevinsky [Reference Bernstein and Zelevinsky6], [Reference Zelevinsky79] for irreducible representations of
$\operatorname {GL}_{r}(F)$
. After that, various results were built up for other groups, including
-
• When G is an inner form of
$\operatorname {GL}_{r}(F)$
, the three questions above were resolved in a sequence of articles [Reference Sécherre63], [Reference Sécherre64], [Reference Sécherre65], [Reference Sécherre and Stevens66], [Reference V. Sécherre and Stevens67] of Sécherre and Stevens, influenced by the earlier work of Broussous, Grabitz, Silberger and Zink [Reference Broussous12], [Reference Broussous and Grabitz13], [Reference Grabitz34], [Reference Grabitz, Silberger and Zink35], etc. -
• For
$G=\operatorname {SL}_{r}(F)$
, the three questions were resolved by Bushnell-Kutzko [Reference Bushnell and Kutzko20], [Reference Bushnell and Kutzko21] and Goldberg-Roche [Reference Goldberg and Roche32], [Reference Goldberg and Roche33]. For an inner form G of
$\operatorname {SL}_{r}(F)$
, although questions (1) and (2) remain to be resolved, Aubert-Baum-Plyman-Solleveld [Reference Aubert, Baum, Plymen and Solleveld3] somehow answered question (3) for the Hecke algebra related to a product of several blocks
$\operatorname {Rep}_{\mathfrak {s}}(G)$
. -
• Assume
$p\neq 2$
. For a classical group G, or more precisely, the fixed-point subgroup G of
$\operatorname {GL}(V)$
defined by an involution related to a sesquilinear form of the r-dimensional vector space V over F, the first question was resolved by Stevens [Reference Stevens70], [Reference Stevens71], [Reference Stevens72], [Reference Stevens73]. Notably, the uniqueness of
$(J_{M},\lambda _{M})$
up to M-conjugacy was shown in [Reference Kurinczuk, Skodlerack and Stevens50] recently. The second question was resolved by Miyauchi-Stevens [Reference Miyauchi and Stevens53]. They also partially explored the third question when M is a maximal Levi subgroup of G, but the general case is still pending.
All these works essentially rely on the original work of Bushnell-Kutzko for
$G=\operatorname {GL}_{r}(F)$
.
We describe the second streamline. Let G be a general reductive group over F. First of all, we sum up the following results for certain rather easily described blocks:
-
• Borel [Reference Borel11] and Casselman [Reference Casselman25] studied the smooth representations having Iwahori fixed vectors, and related them to the modules of the Iwahori Hecke algebra. Indeed, the study of this case dates back to the earlier work of Iwahori-Matsumoto [Reference Iwahori and Matsumoto43]. Then at least when G is split, in which case the above representations are exactly in the unramified principal block, the above three questions were fully answered.
-
• If G is split, Roche [Reference Roche61] resolved the three questions for general principal blocks under some mild condition on the residual characteristic p.
-
• If the corresponding block
$\operatorname {Rep}_{\mathfrak {s}}(G)$
is of depth 0, saying that the corresponding cuspidal representation
$\pi _{0}$
of M is of depth
$0$
, Moy-Prasad [Reference Moy and Prasad56], [Reference Morris57] as well as Morris [Reference Morris55] resolved the first two questions. The third question was resolved by Morris [Reference Morris54] based on the previous work of Howlett-Lehrer [Reference Howlett and Lehrer42].
Now we assume that G is split over a tamely ramified extension of F. Motivated and influenced by the work of Howe [Reference Howe41], Moy-Prasad [Reference Morris55], Adler [Reference Adler1] and others, Yu [Reference Yu78] gave an explicit construction of the so-called ‘tame supercuspidal representations’Footnote
1
via compact induction, which in particular resolved the first question for blocks with respect to a tame supercuspidal representation
$\pi _{0}$
. Then Kim-Yu [Reference Kim and Yu49] resolved the second question for such blocks based on Yu’s construction of tame supercuspidal representations, and Hakim-Murnaghan [Reference Hakim and Murnaghan37] fully explored the ‘uniqueness’ of Yu’s construction.
Unlike the special cases mentioned above, Yu’s construction is general enough to recover ‘almost all’ the supercuspidal representations. Indeed, when F is of characteristic 0 and p is large enough, Kim [Reference Kim and Yu49] proved that Yu’s construction exhausts all the supercuspidal representations. Recently, Fintzen [Reference Fintzen27] showed that for any F with p not dividing the order of the Weyl group of G, which in particular recovers Kim’s assumption, Yu’s construction is exhaustive. It is also worth mentioning that Kaletha [Reference Kaletha45] constructed the so-called ‘regular supercuspidal representations’ as a subclass of tame supercuspidal representations, having simpler constructing datum and easier described Langlands parameter.
Finally, to study question (3) for those blocks with
$\pi _{0}$
tame supercuspidal, Yu proposed a conjecture to transfer the original Hecke algebra
$\mathcal {H}(G,\lambda )$
to another Hecke algebra related to a depth-0 block of a twisted Levi subgroup of G (cf. [Reference Yu78, Conjecture 0.2] and [Reference Adler and Mishra2, Conjecture 1.1]). This conjecture was recently proved by Adler-Mishra [Reference Adler and Mishra2] for regular supercuspidal blocks and Ohara [Reference Ohara59] in general.
Let us also briefly mention that the type theory is not the only possible way to study the category
$\operatorname {Rep}_{\mathfrak {s}}(G)$
. Indeed, Bernstein himself constructed a progenerator
$\Pi _{M}$
of the block
$\operatorname {Rep}_{\mathfrak {s}_{M}}(M)$
, as well as its parabolic induction
$\Pi _{G}=i_{P}^{G}(\Pi _{M})$
as a progenerator of the block
$\operatorname {Rep}_{\mathfrak {s}}(G)$
, such that the map
$$ \begin{align*}\operatorname{Rep}_{\mathfrak{s}}(G)\rightarrow\operatorname{Mod}(\mathcal{H}(\Pi_{G})),\quad\pi\mapsto\operatorname{Hom}_{G}(\Pi_{G},\pi)\end{align*} $$
is an equivalence of categories, where
$\mathcal {H}(\Pi _{G})=\operatorname {End}_{G}(\Pi _{G})$
denotes the corresponding endomorphism algebra (cf. [Reference Renard60, Chapitre VI]). Using harmonic analysis over p-adic groups, Heiermann [Reference Heiermann38] constructed the generators of
$\mathcal {H}(\Pi _{G})$
and calculated the corresponding relations when G is a classical group, which was generalized by Solleveld [Reference Solleveld69] to general reductive groups based on some conjectural assumptions. It is shown that
$\mathcal {H}(\Pi _{G})$
is the semi-direct product of an affine Hecke algebra and a twisted finite group algebra, which parallels the question (3) we mentioned above in the type theory.
Now we introduce our main player: the finite central cover of a p-adic reductive group. Fix a positive integer n. Assume that
$F^{\times }$
contains the subgroup of n-th roots of unity
$\mu _{n}$
of cardinality n. Let
$\widetilde {G}$
be an n-fold cover of G, which is a central extension of G by
$\mu _{n}$
as
$\ell $
-groups – that is,
To proceed a general discussion, usually we need to restrict to some special n-fold covers. For instance, those covers constructed by Brylinski-Deligne [Reference Brylinski and Deligne14] are general enough to include most interesting covers and concrete enough to make various specific calculations. So from now on, we also assume
$\widetilde {G}$
to be a so-called n-fold metaplectic cover. In this article, by ‘n-fold metaplectic cover’ we mean an n-fold cover of G arising from Brylinski-Deligne’s construction (see Section 4). Also, in the discussion below, we assume
$\widetilde {G}$
to be tame, saying that n is relatively prime to p.
Like the previous case, the Bernstein decomposition is still valid (cf. [Reference Kaplan and Szpruch47])
$$ \begin{align*}\operatorname{Rep}(\widetilde{G})=\prod_{\mathfrak{s}}\operatorname{Rep}_{\mathfrak{s}}(\widetilde{G}),\end{align*} $$
where the inertial equivalence class
$\mathfrak {s}=(\widetilde {M},\mathcal {O})$
consists of (the G-conjugacy class of) a Levi subgroup
$\widetilde {M}$
of
$\widetilde {G}$
and an orbit
$\mathcal {O}$
of a cuspidal representation
$\widetilde {\pi }_{0}$
of
$\widetilde {M}$
twisted by unramified characters of M.Footnote
2
Still, one wonders if the three questions above could be dealt with for the category
$\operatorname {Rep}_{\mathfrak {s}}(\widetilde {G})$
, and in particular, a type
$(\widetilde {J},\widetilde {\lambda })$
of
$\operatorname {Rep}_{\mathfrak {s}}(\widetilde {G})$
is expected to be constructed. Here, essentially we only need to consider genuine representations, saying that the action of
$\mu _{n}$
on
$\widetilde {\pi }_{0}$
is given by a fixed character
$\epsilon $
of order n.
Unlike the linear case, only few cases for covers were explored, including the following:
-
• When G is split, Savin [Reference Savin62] resolved the three questions above for the genuine unramified principal block of
$\widetilde {G}$
, or in other words, the block of genuine representations having Iwahori fixed vectors. This in particular generalizes the results of Borel and Casselman. Also, the corresponding genuine Iwahori Hecke algebra is isomorphic to the Iwahori Hecke algebra of a linear reductive group, which leads to the so-called ‘Shimura correspondence’ for representations. -
• When the corresponding block
$\operatorname {Rep}_{\mathfrak {s}}(\widetilde {G})$
is of depth 0, Howard-Weissman [Reference Howard and Weissman39] generalized the argument of Moy-Prasad to resolve questions (1) and (2). -
• When
$\widetilde {G}$
is a cover of a torus, the three questions become somehow transparent. They were studied by Weissman [Reference Weissman77]. -
• When
$\widetilde {G}$
is a tame Kazhdan-Patterson cover of
$G=\operatorname {GL}_r(F)$
, Suzuki [Reference Suzuki74] constructed maximal simple types of
$\widetilde {G}$
and sketched a solution to the question (1) based on the work of Bushnell-Kutzko [Reference Bushnell and Kutzko19]. -
• For sporadic cases, partial results for question (1) were obtained, including Blondel [Reference Blondel8], [Reference Blondel9] for
$G=\operatorname {GL}_{r}(F)$
and Ngo [Reference Ngo58] for
$G=\mathrm {SO}_{r}(F)$
and
$\widetilde {G}=\mathrm {Spin}_{r}(F)$
.
So one is curious to explore the three questions above for general covers
$\widetilde {G}$
and general blocks
$\operatorname {Rep}_{\mathfrak {s}}(\widetilde {G})$
.
1.2 Main results and proofs
The main goal of the paper is to partially answer the three questions for a tame n-fold metaplectic cover
$\widetilde {G}$
of
$G=G_{r}:=\operatorname {GL}_{r}(F)$
. So, let
$\mathfrak {s}=(\widetilde {M},\mathcal {O})$
be an inertial equivalence class of
$\widetilde {G}$
with
$\widetilde {\pi }_{0}\in \mathcal {O}$
being a genuine cuspidal representation of
$\widetilde {M}$
. Let
$\mathfrak {s}_{M}=(\widetilde {M},\mathcal {O})$
be the corresponding inertial equivalence class of
$\widetilde {M}$
.
We first give the answer to the first question, which could be summed up as the following theorem.
Theorem 1.1 (cf. Theorem 6.15, Theorem 6.18, Theorem 8.11).
We may construct a maximal simple type (cf. Definition 8.6)
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
of
$\widetilde {M}$
, where
$J_{M}$
is an open compact subgroup of M and
$\widetilde {\lambda }_{M}$
is a genuine irreducible representation of
$\widetilde {J}_{M}$
, such that
$\widetilde {\pi }_{0}$
contains
$\widetilde {\lambda }_{M}$
. Moreover,
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
is an
$\mathfrak {s}_{M}$
-type. Such
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
is unique up to M-conjugacy.
Write
$M=G_{r_{1}}\times \dots \times G_{r_{k}}$
with
$r_{1}+\dots +r_{k}=r$
. For each i, we regard
$G_{r_{i}}$
as a subgroup of M and
$\widetilde {G_{r_{i}}}$
as a subgroup of
$\widetilde {M}$
via the pull-back. Then there exists a maximal simple type
$(\widetilde {J}_{i},\widetilde {\lambda }_{i})$
of
$\widetilde {G_{r_{i}}}$
such that
$\widetilde {\lambda }$
equals the tensor product
$\widetilde {\lambda }_{1}\boxtimes \dots \boxtimes \widetilde {\lambda }_{k}$
(See §4.2 for the meaning of the tensor product). So essentially, we only need to explain the construction of a maximal simple type of
$\widetilde {G}$
. Then Theorem 1.1 could be easily reduced to the case where
$M=G$
.
More generally, we explain the construction of a simple type
$(\widetilde {J},\widetilde {\lambda })$
of
$\widetilde {G}$
. Our construction is largely based on the theory of Bushnell-Kutzko for simple strata, simple characters, etc. To proceed, we assume that the readers are familiar with the corresponding concepts and leave Section 5 for more details.
Let V be an r-dimensional vector space over F. Up to choosing a basis of V, we identify G with
$\operatorname {Aut}_{F}(V)$
and
$A=\operatorname {M}_{r}(F)$
with
$\operatorname {End}_{F}(V)$
. Let
$[\mathfrak {a},u,0,\beta ]$
be a strict simple stratum in A. Here,
$E=F[\beta ]$
is a subfield of A of degree d over F, and
$\mathfrak {a}$
, as a hereditary order in A, is normalized by
$E^{\times }$
. Let B be the centralizer of E in A. Then
$\mathfrak {b}=\mathfrak {a}\cap B$
is a hereditary order in B.
We consider the related subgroups
$H^{1}=H^{1}(\beta ,\mathfrak {a})$
,
$J^{1}=J^{1}(\beta ,\mathfrak {a})$
and
$J=J(\beta ,\mathfrak {a})$
of G, where the first two groups are pro-p open compact and the third one is open compact, such that
$$ \begin{align*}J/J^{1}\cong U(\mathfrak{b})/U^{1}(\mathfrak{b})\cong\mathcal{M}=\operatorname{GL}_{m_{1}}(\boldsymbol{l})\times\dots\times\operatorname{GL}_{m_{t}}(\boldsymbol{l}),\end{align*} $$
where
$m=r/d=m_{1}+\dots +m_{t}$
, and
$\boldsymbol {l}$
denotes the residue field of E, and
$\mathcal {M}$
is a Levi subgroup of
$\operatorname {GL}_{m}(\boldsymbol {l})$
. We may find a maximal open compact subgroup K of G that contains J, and since
$\widetilde {G}$
is tame, we may find a splitting (i.e., a section and a group homomorphism)
$\boldsymbol {s}:K\rightarrow \widetilde {G}$
.
We consider a simple character
$\theta $
of
$H^{1}$
, the Heisenberg representation
$\eta $
of
$\theta $
of
$J^{1}$
, and a
$\beta $
-extension
$\kappa $
of J that extends
$\eta $
. We let
$\widetilde {\kappa }$
be the pull-back of
$\kappa $
as a non-genuine irreducible representation of
$\widetilde {J}$
. On the other hand, we let
$\varrho $
be a cuspidal representation of
$\mathcal {M}$
. After inflating to
$\boldsymbol {s}(J)$
and then extending to
$\widetilde {J}$
by
$\epsilon $
, we get a genuine irreducible representation
$\widetilde {\rho }$
of
$\widetilde {J}$
. We let
$\widetilde {\lambda }=\widetilde {\kappa }\otimes \widetilde {\rho }$
. Then
$(\widetilde {J},\widetilde {\lambda })$
is a homogeneous type of
$\widetilde {G}$
.
Remark 1.2. As already been mentioned by Suzuki [Reference Suzuki74] for maximal simple types,
$\widetilde {\lambda }$
is indeed the ‘genuine pull-back’ of a homogeneous type
$\lambda $
of G. More precisely, let
$\rho $
be the inflation of
$\varrho $
to J and let
$\lambda =\kappa \otimes \rho $
be a related homogeneous type of G. Then
$\widetilde {\lambda }$
is obtained from extending the representation
$\lambda \circ \boldsymbol {p}$
of
$\boldsymbol {s}(J)$
to
$\widetilde {J}$
by
$\epsilon $
.
Moreover,
$(\widetilde {J},\widetilde {\lambda })$
is a twisted simple type of
$\widetilde {G}$
if (cf. Section 6 for more details)
-
•
$m_{1}=\dots =m_{t}=m_{0}$
for a positive integer
$m_{0}$
; -
• There exists a cuspidal representation
$\varrho _{0}$
of
$\operatorname {GL}_{m_{0}}(\boldsymbol {l})$
, such that
$\varrho $
is isomorphic to
$(\varrho _{0}\boxtimes \dots \boxtimes \varrho _{0})\chi _{g_{0}}$
as a representation of
$\mathcal {M}=\operatorname {GL}_{m_{0}}(\boldsymbol {l})\times \dots \times \operatorname {GL}_{m_{0}}(\boldsymbol {l})$
, where
$g_{0}$
is a diagonal element in
$U(\mathfrak {b})$
and
$\chi _{g_{0}}:=\epsilon ([g_{0},\cdot ]_{\sim })$
is a character of
$\mathcal {M}$
.
In the above definition, if moreover,
$g_{0}=1$
and
$\chi _{g_{0}}$
is the identity character, then we call the related pair
$(\widetilde {J},\widetilde {\lambda })$
a simple type of
$\widetilde {G}$
. Finally, a simple type
$(\widetilde {J},\widetilde {\lambda })$
is maximal if
$t=1$
and
$m_{0}=m$
, or in other words,
$\mathfrak {b}$
is a maximal hereditary order in B. We remark that the intertwining set
$I_{G}(\widetilde {\lambda })$
of a simple type
$(\widetilde {J},\widetilde {\lambda })$
could be calculated explicitly; this further enables us to study the related Hecke algebra
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
.
Now we may explain the proof of Theorem 1.1 for
$M=G$
. Let
$(\widetilde {J},\widetilde {\lambda })$
be a maximal simple type of
$\widetilde {G}$
. First, we show that it is a type of a cuspidal inertial equivalence class of
$\widetilde {G}$
. Indeed, we consider
$\boldsymbol {J}=E^{\times }J$
, which is an open compact modulo center subgroup of G. Moreover, the normalizer
$N_{G}(\widetilde {\lambda })$
and intertwining set
$I_{G}(\widetilde {\lambda })$
turn out to be equal, which is an open subgroup of
$\boldsymbol {J}$
of finite index and denoted by
$J_{\lambda }$
. Thus, we may take an extension of
$\widetilde {\lambda }$
to an irreducible representation
$\widetilde {\lambda '}$
of
$\widetilde {J_{\lambda }}$
, and then take the compact induction
$\widetilde {\boldsymbol {\lambda }}=\operatorname {ind}_{\widetilde {J_{\lambda }}}^{\widetilde {\boldsymbol {J}}}\widetilde {\lambda '}$
as a genuine irreducible representation of
$\widetilde {\boldsymbol {J}}$
, called an extended maximal simple type of
$\widetilde {G}$
. Since the normalizer of
$\widetilde {\boldsymbol {\lambda }}$
in G is
$\widetilde {\boldsymbol {J}}$
, the compact induction
$\widetilde {\pi }_{0}=\operatorname {ind}_{\widetilde {\boldsymbol {J}}}^{\widetilde {G}}\widetilde {\boldsymbol {\lambda }}$
is a genuine irreducible cuspidal representation of
$\widetilde {G}$
. This shows that
$(\widetilde {J},\widetilde {\lambda })$
is a type of the inertial equivalence class related to
$\widetilde {\pi }_{0}$
.
On the other hand, given a cuspidal representation
$\widetilde {\pi }_{0}$
of
$\widetilde {G}$
, we want to find a maximal simple type
$(\widetilde {J},\widetilde {\lambda })$
contained in
$\widetilde {\pi }_{0}$
. This could be done in two steps: first, we find a simple character
$\theta $
contained in
$\widetilde {\pi }_{0}$
, and then we find a corresponding maximal simple type
$\widetilde {\lambda }$
contained in
$\widetilde {\pi }_{0}$
. The first step is essentially a repetition of a similar argument of [Reference Bushnell and Kutzko19, Chapter 8] or [Reference Sécherre and Stevens66, §3 and 4], due to the following obvious fact: if H is an open compact pro-p-subgroup of G, then there exists a unique splitting
$\boldsymbol {s}:H\rightarrow \widetilde {G}$
; thus, for a representation
$\xi $
of H, the group
$\,_{s}H:=\boldsymbol {s}(H)$
as well as the representation
$\,_{s}\xi :=\xi \circ \boldsymbol {p}$
of
$\,_{s}H$
are well-defined. Since the argument in the first step concerns only pro-p-subgroups and their representations, the corresponding argument could be simply transplanted. The second step reduces to studying depth 0 representations, which essentially follows from a similar argument in [Reference Sécherre and Stevens66, §5]. So Theorem 1.1 is explained.
Now we answer the second and third questions for an inertial equivalence class related to a simple type
$(\widetilde {J},\widetilde {\lambda })$
of
$\widetilde {G}$
. Keep the notation as before and let
$r_{0}=dm_{0}$
. From the construction, we may find a decomposition
$V=\bigoplus _{i=1}^{t}V^{i}$
of vector spaces over both F and E, where
$V^{i}$
is a vector space of dimension
$r_{0}$
over F and
$m_{0}$
over E. Moreover, we assume that this decomposition is compatible with the hereditary orders
$\mathfrak {a}$
and
$\mathfrak {b}$
, saying that the lattice chains in defining
$\mathfrak {a}$
and
$\mathfrak {b}$
are decomposable with respect to this decomposition. We also notice that in this case,
$\mathfrak {b}$
is a hereditary order in
$\operatorname {M}_{m}(\mathfrak {o}_{E})$
related to the composition
$(m_{0},\dots ,m_{0})$
of m. Consider the Levi subgroup
$M=\operatorname {Aut}_{F}(V^{1})\times \dots \times \operatorname {Aut}_{F}(V^{t})$
of G and a related parabolic subgroup
$P=MU$
. Let
$U^{-}$
be the opposite of U as a unipotent subgroup of G. Then we are able to construct
-
• an open compact subgroup
$J_{P}=(H^{1}\cap U^{-})(J\cap P)$
of G and an irreducible representation
$\widetilde {\lambda }_{P}$
of
$\widetilde {J_{P}}$
, such that
$\widetilde {\lambda }=\operatorname {ind}_{\widetilde {J_{P}}}^{\widetilde {J}}\widetilde {\lambda }_{P}$
. -
• an open compact subgroup
$J_{M}=J_{P}\cap M=J\cap M$
of M and an irreducible representation
$\widetilde {\lambda }_{M}$
of
$\widetilde {J_{M}}$
as the restriction of
$\widetilde {\lambda }_{P}$
.
Then the answer to the second question is as follows:
Theorem 1.3 (cf. Theorem 6.15, Theorem 6.16).
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
is a maximal simple type of
$\widetilde {M}$
, which is a type of a cuspidal inertial equivalence class
$\mathfrak {s}_{M}=(\widetilde {M},\mathcal {O})$
.
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
is a covering pair of
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
, so both
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
and
$(\widetilde {J},\widetilde {\lambda })$
are
$\mathfrak {s}$
-types with
$\mathfrak {s}=(\widetilde {M},\mathcal {O})$
an inertial equivalence class of
$\widetilde {G}$
.
The crux of the proof requires the calculation of the Hecke algebra
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })\cong \mathcal {H}(\widetilde {G},\widetilde {\lambda }_{P})$
, which is closely related to the third question. Let
$q_{E}$
be the cardinality of the residue field
$\boldsymbol {l}$
of E and let
$\boldsymbol {q}_{0}=q_{E}^{m_{0}}$
. We define a certain positive integer
$s_{0}$
dividing n (cf. §6.3) and the affine Hecke algebra
$\widetilde {\mathcal {H}}(t,s_{0},\boldsymbol {q}_{0})$
of type A (cf. §7.1).
Theorem 1.4 (cf. Theorem 7.5).
Up to a scalar, there exists a canonical embedding of algebras
$$ \begin{align*}\Psi:\widetilde{\mathcal{H}}(t,s_{0},\boldsymbol{q}_{0})\hookrightarrow\mathcal{H}(\widetilde{G},\widetilde{\lambda})\end{align*} $$
which preserves the support in the sense made precise in loc. cit.
The proof is based on finding explicit generators of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
, similar to a parallel argument of Sécherre [Reference Sécherre65, Théorème 4.6]. It is expected that
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
is an affine Hecke algebra in general (cf. Conjecture 7.16). Anyway, we give a rather satisfactory answer to questions (2) and (3) for simple types, which in particular includes all the cuspidal inertial equivalence classes.
We also expect to construct types related to any inertial equivalence classes of
$\widetilde {G}$
and calculate the corresponding Hecke algebra if possible. They are related to the so-called semi-simple types in [Reference Bushnell and Kutzko23] and [Reference V. Sécherre and Stevens67]. Hopefully, this could be done in a sequel of this article.
Finally, we focus on the case where
$\widetilde {G}$
is either a Kazhdan-Patterson cover or the Savin’s cover (cf. §4.2). These two types of covers are special, in the sense that there exists a certain ‘metaplectic tensor product’ functor from representations of covers of smaller
$\operatorname {GL}(F)$
’s to representations of a Levi subgroup
$\widetilde {M}$
of
$\widetilde {G}$
. Also, both of them admit a classification result of irreducible representations in the sense of Zelevinsky [Reference Zelevinsky79]. We list main results that we achieve for such covers.
-
• (cf. Corollary 7.12 and Corollary 7.13) The embedding
$\Psi $
in Theorem 1.4 is an isomorphism, which can also be chosen as an isometry. -
• (cf. Proposition 9.7) Assume
$G=G_{2r_{0}}$
, and let P be a parabolic subgroup of G of a Levi factor
$M=G_{r_{0}}\times G_{r_{0}}$
. Let
$\widetilde {\pi }$
be a unitary cuspidal representation of
$\widetilde {M}$
invariant under the action of the Weyl group
$W(G,M)$
. Let
$\nu (\cdot )=\left |\operatorname {det}(\cdot )\right |{}_{F}$
, which is an unramified character of
$G_{r_{0}}$
. Then the positive real number
$s\in \mathbb {R}$
such that the parabolic induction
$i_{\widetilde {P}}^{\widetilde {G}}(\widetilde {\pi }\cdot (\nu ^{-s}\boxtimes \nu ^{s}))$
is reducible can be explicitly calculated. -
• (cf. Proposition 9.10) The corresponding equivalence of categories
which is the composition of the functor
$$ \begin{align*}\widetilde{\mathcal{T}}_{G}:\operatorname{Rep}_{\mathfrak{s}}(\widetilde{G})\rightarrow\operatorname{Mod}(\widetilde{\mathcal{H}}(t,s_{0},\boldsymbol{q}_{0})),\end{align*} $$
$\boldsymbol {\mathrm {M}}_{\widetilde {\lambda }}:\operatorname {Rep}_{\mathfrak {s}}(\widetilde {G})\rightarrow \operatorname {Mod}(\mathcal {H}(\widetilde {G},\widetilde {\lambda }))$
and the functor
$\Psi ^{*}:\operatorname {Mod}(\mathcal {H}(\widetilde {G},\widetilde {\lambda }))\rightarrow \operatorname {Mod}(\widetilde {\mathcal {H}}(t,s_{0},\boldsymbol {q}_{0}))$
induced from the pull-back of
$\Psi $
, can be fully determined.
-
• (cf. Proposition 9.12) The set of
$\widetilde {G}$
-conjugacy classes of weak equivalence classes of simple types
$(\widetilde {J},\widetilde {\lambda })$
are in bijection with the set of discrete inertial equivalence classes of
$\widetilde {G}$
.
1.3 Structure of the article
We outline the structure of this article.
Section 2–5 are preliminaries. We fix general notation in Section 2, sketch general results of type theory in Section 3, introduce metaplectic covers in Section 4 with an emphasis on the case
$G=\operatorname {GL}_{r}(F)$
, and recall the theory of strata and simple characters of Bushnell-Kutzko in Section 5.
In Section 6, we introduce the key definition of homogeneous types and (twisted) simple types. We also resolve the crucial problem of calculating the intertwining set and normalizer of a simple type
$(\widetilde {J},\widetilde {\lambda })$
in G. Theorem 1.1 and Theorem 1.3, except the exhaustion of
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
, are stated, while some of them are proved in §6.4.
In Section 7, the main focus is to calculate the Hecke algebra
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
of a simple type
$(\widetilde {J},\widetilde {\lambda })$
. As we explained before, we are able to find an embedding
$\Psi $
from an affine Hecke algebra
$\widetilde {\mathcal {H}}(t,s_{0},\boldsymbol {q}_{0})$
of type A to
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
, which in particular is an isomorphism if
$\widetilde {G}$
is either a Kazhdan-Patterson cover or Savin’s cover. As a result, Theorem 1.4 is stated and proved, and so is the rest of the claims in §6.4 for at least
$M=G$
.
In Section 8, we state the exhaustion of
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
in Theorem 1.1, whose proof is accomplished in Section 10.
Finally in Section 9, our main focus is the two classes of special covers of
$G=\operatorname {GL}_{r}(F)$
we mentioned above. We prove all the statements we claimed.
2 Preliminaries
In this article, we fix a non-archimedean locally compact field F, whose residual field
$\boldsymbol {k}$
is of cardinality q. We write
$\mathfrak {o}_{F}$
for the ring of integers of F and
$\mathfrak {p}_{F}$
for the maximal ideal of
$\mathfrak {o}_{F}$
. We write
$v_{F}:F^{\times }\rightarrow \mathbb {Z}$
for the canonical discrete valuation with respect to F.
We fix a positive integer n that divides
$q-1$
. It implies that the subgroup of n-th roots of unity of
$F^{\times }$
, denoted by
$\mu _{n}(F)$
and usually abbreviated by
$\mu _{n}$
, consists of n elements. Let
$\left |\cdot \right |{}_{F}$
denote the discrete valuation of F.
We denote by
$(\cdot ,\cdot )_{n}:F^{\times }\times F^{\times }\rightarrow \mu _{n}$
the n-th Hilbert symbol, which is a bimultiplicative, anti-symmetric pairing, that descends to a nondegenerate bimultiplicative pairing
$F^{\times }/F^{\times n}\times F^{\times }/F^{\times n}\rightarrow \mu _{n}$
, where
$F^{\times n}=\{x^{n}\mid x\in F^{\times }\}$
. Since
$\operatorname {gcd}(q,n)=1$
, such a pairing is trivial on
$\mathfrak {o}_{F}^{\times }\times \mathfrak {o}_{F}^{\times }$
. We refer to [Reference Weil76, XIII.§5] for all the required properties in this article. In general, for a finite extension
$E/F$
, we denote by
$(\cdot ,\cdot )_{n,E}:E^{\times }\times E^{\times }\rightarrow \mu _{n}$
the corresponding n-th Hilbert symbol. It is known that
$(x,y)_{n,E}=(x,\operatorname {N}_{E/F}(y))_{n,F}$
, where
$x\in F^{\times }$
,
$y\in E^{\times }$
and
$\operatorname {N}_{E/F}:E^{\times }\rightarrow F^{\times }$
denotes the norm map.
By
$\ell $
-groups in this article, we mean locally compact totally disconnected topological groups as in [Reference Bernstein and Zelevinsky5]. By representations of an
$\ell $
-group in this article, we mean complex smooth representations. In particular, a character is a one-dimensional smooth representation.
We fix an additive character
$\psi _{F}:F\rightarrow \mathbb {C}^{\times }$
of conductor
$\mathfrak {p}_{F}$
(i.e., it is trivial on
$\mathfrak {p}_{F}$
and is not trivial on
$\mathfrak {o}_{F}$
).
Let G be an
$\ell $
-group. We write
$Z(G)$
for the center of G and
$[\cdot ,\cdot ]:G\times G\rightarrow G$
for the commutator map given by
$[g_{1},g_{2}]=g_{1}g_{2}g_{1}^{-1}g_{2}^{-1},\ g_{1},g_{2}\in G$
.
We denote by
$\operatorname {det}:\operatorname {M}_{r}(F)\rightarrow F$
and
$\operatorname {tr}:\operatorname {M}_{r}(F)\rightarrow F$
the determinant map and the trace map, respectively. In general, for a finite extension
$E/F$
, we write
$\operatorname {det}_{E}:\operatorname {M}_{r}(E)\rightarrow E$
and
$\operatorname {tr}_{E}:\operatorname {M}_{r}(E)\rightarrow E$
correspondingly.
Let
$\nu =\left |\cdot \right |{}_{F}$
which is an unramified character of
$F^{\times }$
. By composing with the determinant map
$\operatorname {det}_{F}$
, we identify
$\nu $
with a character of
$\operatorname {GL}_{r}(F)$
for any r.
Let
$H\subset H'$
be two closed subgroups of G. We write
$\operatorname {Ind}_{H}^{H'}:\operatorname {Rep}(H)\rightarrow \operatorname {Rep}(H')$
,
$\operatorname {ind}_{H}^{H'}:\operatorname {Rep}(H)\rightarrow \operatorname {Rep}(H')$
and
$\lvert _{H}:\operatorname {Rep}(H')\rightarrow \operatorname {Rep}(H)$
for the induction, compact induction and restriction functors, respectively, where
$\operatorname {Rep}(\cdot )$
denotes the category of smooth representations. For a representation
$\pi $
of
$H'$
, we often write
$\pi $
instead of
$\pi |_{H}$
for short if the domain of definition of
$\pi $
(i.e., H) is clear from the context. By convention, we say that a representation
$\pi $
of
$H'$
contains an irreducible representation
$\pi '$
of H if
$\operatorname {Hom}_{H}(\pi ',\pi \lvert _{H})\neq 0$
. Assume H to be an open normal subgroup of
$H'$
, let
$\overline {H}=H'/H$
and let
$\overline {\rho }$
be a representation of
$\overline {H}$
. Then we denote by
$\operatorname {Inf}_{\overline {H}}^{H'}\overline {\rho }$
the inflation of
$\overline {\rho }$
as a representation of
$H'$
that extends trivially on H.
Let
$(\rho ,W)$
be a representation of H. We write
$(\rho ^{\vee },W^{\vee })$
for the contragredient of
$(\rho ,W)$
. For
$g,x\in G$
, we denote by
$x^{g}=g^{-1}xg$
,
$H^{g}=g^{-1}Hg$
, and
$\rho ^{g}(\cdot )=\rho (g\cdot g^{-1})$
as a representation of
$H^{g}$
. We say that
$g\in G$
intertwines
$\rho $
if the intertwining space
$$ \begin{align*}\operatorname{Hom}_{H^{g}\cap H}(\rho^{g},\rho)\end{align*} $$
is nonzero, and we denote by
$I_{G}(\rho )$
the intertwining set of
$\rho $
consisting of
$g\in G$
satisfying the above condition. In general, for two closed subgroups
$H_{1}$
,
$H_{2}$
of G and
$\rho _{1}$
,
$\rho _{2}$
their representations, respectively, we say that
$g\in G$
intertwines
$\rho _{1}$
and
$\rho _{2}$
if the intertwining space
$$ \begin{align*}\operatorname{Hom}_{H_{1}^{g}\cap H_{2}}(\rho_{1}^{g},\rho_{2})\end{align*} $$
is nonzero. We say that g normalizes H (resp.
$\rho $
) if
$H^{g}=H$
(resp.
$\rho ^{g}\cong \rho $
), and we write
$N_{G}(H)$
(resp.
$N_{G}(\rho )$
) for the corresponding normalizer.
For
$x\in \mathbb {R}$
, we denote by
$\lfloor x\rfloor $
(resp.
$\lceil x\rceil $
) the largest integer smaller than or equal to (resp. the smallest integer greater than or equal to) x.
Let
$\mathfrak {S}_{k}$
be the group of permutations of k elements.
Let
$\operatorname {gcd}(k_{1},\dots ,k_{m})$
denote the greatest common divisor of
$k_{1},\dots ,k_{m}$
.
3 Hecke algebra, cuspidal representations, types and covering pairs
In this section, we follow [Reference Bushnell and Kutzko19] and [Reference Bushnell and Kutzko22] to recall some known results for Hecke algebra, cuspidal representations, types and covering pairs.
3.1 Hecke algebra
Our reference here is [Reference Bushnell and Kutzko19, §4] and [Reference Bushnell and Kutzko22, §2]. Let G be an
$\ell $
-group, let J be an open compact subgroup of G, and let
$(\rho ,W)$
be an irreducible representation of J, which is necessarily finite dimensional. We fix a Haar measure
$dx$
of G.
Let
$\mathcal {H}(G)$
denote the Hecke algebra of G consisting of complex smooth compactly supported functions on G, equipped with the convolution for the product structure. It is well-known that we have an equivalence of categories
$$ \begin{align*}\operatorname{Rep}(G)\rightarrow\operatorname{Mod}(\mathcal{H}(G)),\end{align*} $$
where
$\operatorname {Mod}(\mathcal {H}(G))$
denotes the category of nondegenerate
$\mathcal {H}(G)$
-modules, and for
$(\pi ,V)\in \operatorname {Rep}(G)$
, the corresponding
$\mathcal {H}(G)$
-module structure is given by
$$ \begin{align*}v\mapsto \pi(f)v:=\int_{G}f(x)\pi(x)vdx\end{align*} $$
for
$f\in \mathcal {H}(G)$
and
$v\in V$
.
We denote by
$\mathcal {H}(G,\rho )$
the space of compactly supported functions
$\phi :G\rightarrow \operatorname {End}_{\mathbb {C}}(W^{\vee })$
, such that
$$ \begin{align*}\phi(g_{1}gg_{2})=\rho^{\vee}(g_{1})\phi(g)\rho^{\vee}(g_{2}),\quad g_{1},g_{2}\in J,\ g\in G.\end{align*} $$
The convolution operation
$$ \begin{align*}\phi_{1}\ast \phi_{2}(g)=\int_{G}\phi_{1}(x)\phi_{2}(x^{-1}g)dx,\quad \phi_{1},\phi_{2}\in\mathcal{H}(G,\rho)\end{align*} $$
gives
$\mathcal {H}(G,\rho )$
the structure of an associative
$\mathbb {C}$
-algebra with unit. We will use the abbreviation
$$ \begin{align*}\phi^{k}=\underbrace{\phi\ast\dots\ast\phi}_{k\text{-copies}}.\end{align*} $$
By [Reference Bushnell and Kutzko19, Proposition 4.1.1], for
$g\in G$
, there exists a function
$\phi \in \mathcal {H}(G,\rho )$
whose support is
$JgJ$
if and only if g intertwines
$\rho $
.
We fix a complex structure on the finite dimensional complex vector space
$W^{\vee }$
. So
$(\rho ^{\vee },W^{\vee })$
is realized as a unitary representation. We define
$$ \begin{align*}h_{G}(\phi_{1},\phi_{2})=\int_{x\in G}\operatorname{tr}_{W^{\vee}}(\phi_{1}(x)\overline{\phi_{2}(x)})dx=\operatorname{tr}_{W^{\vee}}(\phi_{1}\ast\overline{\phi_{2}}(1)),\quad \phi_{1},\phi_{2}\in\mathcal{H}(G,\rho)\end{align*} $$
as a positive definite hermitian form on
$\mathcal {H}(G,\rho )$
. Here, the ‘bar’ for
$\overline {\phi _{2}(x)}$
denotes the complex conjugate on
$\operatorname {End}_{\mathbb {C}}(W^{\vee })$
induced by that on
$W^{\vee }$
and the ‘bar’ for
$\overline {\phi _{2}}$
is given by
$\overline {\phi _{2}}(x)=\overline {\phi _{2}(x^{-1})}$
for
$x\in G$
, and
$\operatorname {tr}_{W^{\vee }}:\operatorname {End}(W^{\vee })\rightarrow \mathbb {C}$
denotes the trace map. Of course,
$h_{G}$
depends on the choice of the Haar measure
$dx$
on G.
For
$a\in \operatorname {End}_{\mathbb {C}}(W)$
, we write
$a^{\vee }\in \operatorname {End}_{\mathbb {C}}(W^{\vee })$
for the transpose of a with respect to the canonical pairing between W and
$W^{\vee }$
. Then we get an isomorphism of algebras
$$ \begin{align*}\mathcal{H}(G,\rho)\rightarrow\mathcal{H}(G,\rho^{\vee})^{{op}},\quad \phi\mapsto \hat{\phi}:=[g\mapsto \phi(g^{-1})^{\vee}].\end{align*} $$
The map
$$ \begin{align*}(\phi,f)\mapsto\phi\ast f:=[g\mapsto\int_{G}\phi(x)f(x^{-1}g)],\quad \phi\in\mathcal{H}(G,\rho^{\vee}),\ f\in\operatorname{ind}_{J}^{G}\rho\end{align*} $$
induces an isomorphism of algebras
$\mathcal {H}(G,\rho ^{\vee })\cong \operatorname {End}_{G}(\operatorname {ind}_{J}^{G}\rho ).$
Also, it provides
$\operatorname {ind}_{J}^{G}\rho $
with a left
$\mathcal {H}(G,\rho ^{\vee })$
-module structure and thus a right
$\mathcal {H}(G,\rho )$
-module structure.
Let
$(\pi ,V)\in \operatorname {Rep}(G)$
. Let
$$ \begin{align*}V_{\rho}:=\operatorname{Hom}_{J}(W,V)=\operatorname{Hom}_{G}(\operatorname{ind}_{J}^{G}W,V)\end{align*} $$
be the space of
$\rho $
-invariants of
$(\pi ,V)$
. It is endowed with a left
$\mathcal {H}(G,\rho )$
-module structure via the right
$\mathcal {H}(G,\rho )$
-action on
$\operatorname {ind}_{J}^{G}\rho $
explained as above. More precisely, the action is given by
$$ \begin{align} \phi\cdot f=[w\mapsto\int_{G}\pi(g)f(\hat{\phi}(g^{-1})w)dg],\quad \phi\in\mathcal{H}(G,\rho),\ f\in V_{\rho},\ w\in W. \end{align} $$
This provides us with a functor
$$ \begin{align} \boldsymbol{\mathrm{M}}_{\rho}:\operatorname{Rep}(G)\rightarrow\operatorname{Mod}(\mathcal{H}(G,\rho)),\quad (\pi,V)\mapsto V_{\rho}. \end{align} $$
Here,
$\operatorname {Mod}(\mathcal {H}(G,\rho ))$
denotes the equivalence classes of nondegenerate
$\mathcal {H}(G,\rho )$
-modules.
3.2 Cuspidal representations
In the rest of this section, let G be a p-adic reductive group or, more generally, an n-fold cover of a p-adic reductive group (cf. [Reference Renard60], [Reference Kaplan and Szpruch47]).
Let
$P=MN$
be a parabolic subgroup of G, with M being a Levi factor and N being the unipotent radical of P.
We define, as in [Reference Bernstein and Zelevinsky6, §1.8], the normalized parabolic induction functor and normalized Jacquet functor
$$ \begin{align*}i_{P}^{G}:\operatorname{Rep}(M)\rightarrow\operatorname{Rep}(G),\quad r_{N}:\operatorname{Rep}(G)\rightarrow\operatorname{Rep}(M).\end{align*} $$
We recall the following equivalent definitions for a cuspidal representation of G.
Definition 3.1 [Reference Bernstein and Zelevinsky6], [Reference Kaplan and Szpruch47].
An irreducible representation
$\pi $
of G is called cuspidal if the following equivalent statements are satisfied:
-
(1)
$\pi $
does not occur as a subrepresentation of a parabolic induction
$i_{P}^{G}(\rho )$
for any proper parabolic subgroup
$P=MN$
of G and any irreducible representation
$\rho $
of M. -
(2) The Jacquet module
$r_{N}(\pi )$
is zero for any proper parabolic subgroup P of G with the unipotent radical N. -
(3) Every matrix coefficient of
$\pi $
is compact modulo the center.
One typical method of obtaining cuspidal representations is the usage of compact induction, which is summarized as the following lemma:
Lemma 3.2 ([Reference Bushnell and Henniart18, Theorem 11.4]).
Let
$\boldsymbol {J}$
be an open subgroup of G, containing a compact modulo center of G. Let
$\boldsymbol {\lambda }$
be an irreducible representation of
$\boldsymbol {J}$
. Assume that the intertwining set
$I_{G}(\boldsymbol {\lambda })$
equals
$\boldsymbol {J}$
. Then the compact induction
$\operatorname {ind}_{\boldsymbol {J}}^{G}\boldsymbol {\lambda }$
is an irreducible cuspidal representation of G, and moreover, any irreducible representation
$\pi $
of G containing
$\boldsymbol {\lambda }$
is cuspidal.
3.3 Bernstein blocks and types
A cuspidal pair
$(M,\rho )$
of G consists of a Levi subgroup M of G and a cuspidal representation
$\rho $
of M. It is known that for an irreducible representation
$\pi $
of G, there exists a cuspidal pair
$(M,\rho )$
, unique up to G-conjugacy, and a parabolic subgroup P of G having a Levi factor M, such that
$\pi $
is a subrepresentation of the parabolic induction
$i_{P}^{G}(\rho )$
, where P is a parabolic subgroup of M. Such a pair is called the cuspidal support of
$\pi $
.
Moreover, let
$\mathcal {O}$
be the orbit of
$\rho $
twisted by unramified characters of M. Then
$\mathfrak {s}=(M,\mathcal {O})$
, up to G-conjugacy, is called an inertial equivalence class of G. The inertial support of
$\pi $
is the inertial equivalence class of its cuspidal support.
Write
$\operatorname {Rep}_{\mathfrak {s}}(G)$
for the subcategory of
$\operatorname {Rep}(G)$
consisting of representations whose irreducible subquotients have inertial support
$\mathfrak {s}$
. Then, each
$\operatorname {Rep}_{\mathfrak {s}}(G)$
is a block of
$\operatorname {Rep}(G)$
, and we have the block decomposition (cf. [Reference Renard60, Chapitre IV, §7.2], [Reference Kaplan and Szpruch47])
$$ \begin{align*}\operatorname{Rep}(G)\cong\prod_{\mathfrak{s}}\operatorname{Rep}_{\mathfrak{s}}(G),\end{align*} $$
where
$\mathfrak {s}$
ranges over all the inertial equivalence classes of G.
Let J be an open compact subgroup of G and let
$\lambda $
be an irreducible representation of J. As in [Reference Bushnell and Kutzko22, §3], we may define a special idempotent
$e_{\lambda }$
in
$\mathcal {H}(G)$
and the subcategory
$\operatorname {Rep}_{\lambda }(G)=\{V\mid \mathcal {H}(G)e_{\lambda } V=V\}$
of
$\operatorname {Rep}(G)$
. Then, we call
$(J,\lambda )$
an
$\mathfrak {s}$
-type if for any irreducible representation
$\pi $
of G, we have that
$\pi |_{J}$
contains
$\lambda $
if and only if
$\pi $
has inertial equivalence class
$\mathfrak {s}$
.
In this case, we have
$\operatorname {Rep}_{\lambda }(G)=\operatorname {Rep}_{\mathfrak {s}}(G)$
and an equivalence of categories
$$ \begin{align*}\boldsymbol{\mathrm{M}}_{\lambda}:\operatorname{Rep}_{\mathfrak{s}}(G)\rightarrow\operatorname{Mod}(\mathcal{H}(G,\lambda)),\quad (\pi,V)\mapsto V_{\lambda}.\end{align*} $$
Such
$\boldsymbol {\mathrm {M}}_{\lambda }$
is equivariant up to the multiplicative action by unramified characters of G on both
$\operatorname {Rep}_{\mathfrak {s}}(G)$
and
$\operatorname {Mod}(\mathcal {H}(G,\lambda ))$
.
3.4 Covering pairs
Let
$P=MN$
be a parabolic subgroup of G, with M being a Levi factor and N being the unipotent radical of P. Let
$P^{-}$
and
$N^{-}$
be the opposite of P and N, respectively, with respect to M. A pair
$(J,\lambda )$
, consisting of an open subgroup J of G and an irreducible
$\lambda $
of J is called decomposed with respect to
$(M,P)$
if
-
•
$J=(J\cap N^{-})\cdot (J\cap M)\cdot (J\cap N)$
. -
• The groups
$J\cap N^{-}$
and
$J\cap N$
are contained in the kernel of
$\lambda $
.
An element
$\zeta \in M$
is called strongly
$(P,J)$
-positive if
-
•
$\zeta (J\cap N)\zeta ^{-1}\subset (J\cap N)$
,
$\zeta ^{-1}(J\cap N^{-})\zeta \subset (J\cap N^{-}).$
-
• For any compact open subgroups
$H_{1}$
,
$H_{2}$
of N, there exists an integer
$i\geq 0$
such that
$\zeta ^{i}H_{1}\zeta ^{-i}\subset H_{2}$
. -
• For any compact open subgroups
$H_{1}$
,
$H_{2}$
of
$N^{-}$
, there exists an integer
$i\geq 0$
such that
$\zeta ^{-i}H_{1}\zeta ^{i}\subset H_{2}$
.
Consider another pair
$(J_{M},\lambda _{M})$
, where
$J_{M}$
is an open compact subgroup of M and
$\lambda _{M}$
is an irreducible representation of
$J_{M}$
. The pair
$(J,\lambda )$
is a (G-)covering pair of
$(J_{M},\lambda _{M})$
if
-
(1) The pair
$(J,\lambda )$
is decomposed with respect to
$(M,P)$
for every parabolic subgroup P of G with a Levi factor M. -
(2)
$J\cap M=J_{M}$
and
$\lambda |_{J_{M}}=\lambda _{M}$
. -
(3) For every parabolic subgroup P of G with a Levi factor M, there exist a strongly
$(P,J)$
-positive element
$z\in Z(M)$
and an invertible element
$\phi _{z}$
in
$\mathcal {H}(G,\lambda )$
supported on
$JzJ$
.
Sometimes, the following condition is more convenient to verify, which implies the condition (3) above (cf. [Reference Bushnell and Kutzko22, Condition 8.2]):
-
(4) Every
$\phi \in \mathcal {H}(G,\lambda )$
is supported on
$JMJ$
.
We remark that in [Reference Bushnell and Kutzko22], Bushnell and Kutzko use the word ‘cover’ for such a pair
$(J,\lambda )$
, which unfortunately conflicts with ‘metaplectic covers’, the central objects of this article. So we use ‘covering pair’ instead, translated from the corresponding French words (cf. [Reference Blondel10]).
The following theorem illustrates the connection between types and covering pairs.
Theorem 3.3 ([Reference Bushnell and Kutzko22, Theorem 8.3]).
Let L be a Levi subgroup of M and let
$\rho $
be a cuspidal representation of L. Let
$\mathfrak {s}_{G}$
(resp.
$\mathfrak {s}_{M}$
) be the inertial equivalence class of G (resp. M) that contains
$(L,\rho )$
. If
$(J_{M},\lambda _{M})$
is a
$\mathfrak {s}_{M}$
-type and
$(J,\lambda )$
is an covering pair of
$(J_{M},\lambda _{M})$
, then
$(J,\lambda )$
is an
$\mathfrak {s}_{G}$
-type.
Fix a parabolic subgroup
$P=MN$
of G. Let
$(J,\lambda )$
be a covering pair of
$(J_{M},\lambda _{M})$
. In [Reference Bushnell and Kutzko22, §7], an embedding of algebras
$t_{P}:\mathcal {H}(M,\lambda _{M})\rightarrow \mathcal {H}(G,\lambda )$
is defined and uniquely characterized by the following properties:
-
• For any strongly
$(P,J)$
-positive element
$\zeta \in M$
, define
$\varphi _{\zeta }\in \mathcal {H}(M,\lambda _{M})$
(resp.
$\phi _{\zeta }\in \mathcal {H}(G,\lambda )$
) such that
$\operatorname {Supp}(\varphi _{\zeta })=J_{M}\zeta J_{M}$
and
$\varphi _{\zeta }(\zeta )=\mathrm {id}_{\lambda _{M}^{\vee }}$
(resp.
$\operatorname {Supp}(\phi _{\zeta })= J\zeta J$
and
$\phi _{\zeta }(\zeta )=\mathrm {id}_{\lambda ^{\vee }}).$
Then
$t_{P}(\varphi _{\zeta })=\delta _{N}^{1/2}(\zeta )\cdot \phi _{\zeta }$
, where
$\delta _{N}:M\rightarrow \mathbb {C}^{\times }$
denotes the modulus character with respect to N. -
• Let
$\mu _{G}$
(resp.
$\mu _{M}$
) be the Haar measure on G (resp. M), such that
$\mu _{G}(J)=\mu _{M}(J_{M})=1$
. Using these two Haar measures and fixing a complex structure on the representation space of
$\lambda ^{\vee }$
and
$\lambda _{M}^{\vee }$
, we define the corresponding hermitian forms
$h_{G}$
on
$\mathcal {H}(G,\lambda )$
and
$h_{M}$
on
$\mathcal {H}(M,\lambda _{M})$
. Then we have (3.3)In other words,
$$ \begin{align} h_{M}(\varphi,\varphi)=h_{G}(t_{P}(\varphi),t_{P}(\varphi)),\quad\text{for any}\ \varphi\in\mathcal{H}(M,\lambda_{M}). \end{align} $$
$t_{P}$
is an isometry between
$\mathcal {H}(M,\lambda _{M})$
and
$t_{P}(\mathcal {H}(G,\lambda ))$
.
-
• If
$\mathcal {H}(G,\lambda )_M:=\{\phi \in \mathcal {H}(G,\lambda )\mid \operatorname {Supp}(\phi )\subset JMJ \}$
is a subalgebra of
$\mathcal {H}(G,\lambda )$
, then we have
$t_P(\mathcal {H}(M,\lambda _M))=\mathcal {H}(G,\lambda )_M$
and the map
$t_P$
preserves support of functions (cf. [Reference Bushnell and Kutzko22, Theorem 7.2.(ii)]), in the sense that
$$ \begin{align*}\operatorname{Supp}(t_{P}(\varphi))=J\cdot\operatorname{Supp}(\varphi)\cdot J,\quad \varphi\in\mathcal{H}(M,\lambda_{M}).\end{align*} $$
We remark that the second property follows from [Reference Roche61, §5]. In loc. cit. the condition (4) for a covering pair is imposed, which simply guarantees that
$t_{P}$
is an isomorphism and is not essential for our statement here. Moreover, although in loc. cit. the representation
$\lambda $
is assumed to be one-dimensional, as already pointed out by the author, the proof is general enough to be adapted to an irreducible finite dimensional representation
$\lambda $
of J.
The above homomorphism
$t_{P}$
induces a map
$$ \begin{align*}t_{P}^{*}:\operatorname{Mod}(\mathcal{H}(G,\lambda))\rightarrow\operatorname{Mod}(\mathcal{H}(M,\lambda_{M}))\end{align*} $$
as the pull-back map of
$t_{P}$
. Such
$t_{P}^{*}$
should be regarded as the normalized Jacquet functor on the Hecke algebra side. Also, the above
$t_{P}^{*}$
has a right adjoint
$$ \begin{align*}(t_{P})_{*}:\operatorname{Mod}(\mathcal{H}(M,\lambda_{M}))\rightarrow \operatorname{Mod}(\mathcal{H}(G,\lambda)).\end{align*} $$
Indeed, for
$V\in \operatorname {Mod}(\mathcal {H}(M,\lambda _{M}))$
, we have
$$ \begin{align*}(t_{P})_{*}(V)=\operatorname{Hom}_{\mathcal{H}(M,\lambda_{M})}(\mathcal{H}(G,\lambda),V).\end{align*} $$
Correspondingly, such
$(t_{P})_{*}$
should be regarded as the normalized parabolic induction functor on the Hecke algebra side. More precisely, we have the following theorem:
Theorem 3.4 ([Reference Bushnell and Kutzko22, Theorem 7.9, Corollary 8.4]).
Under the setting of Theorem 3.3, we have commutative diagrams:
Remark 3.5. The character
$\delta _{N}^{1/2}$
introduced above guarantees that
$t_{P}^{*}$
(resp.
$(t_{P})_{*}$
) is compatible with the normalized Jacquet module functor
$r_{N}$
(resp. parabolic induction functor
$i_{P}^{G}$
). Note that there is a
$\delta _{N}^{1/2}$
-shift between our definition of
$t_{P}$
and that of [Reference Bushnell and Kutzko22], since in ibid. they consider non-normalized parabolic induction and Jacquet module functor.
4 Metaplectic covers of
$\operatorname {GL}_{r}(F)$
4.1 General theory for a finite central cover
We refer to [Reference Gan, Gao and Weissman29] for the basic facts that we are going to state below, which also serves as an excellent historical survey.
Let G be an
$\ell $
-group. By an n-fold cover of G, we mean a central extension of G by
$\mu _{n}$
as
$\ell $
-groups:
We note that the set of equivalence classes of such central extensions is in bijection with the set of (locally constant) 2-cohomology classes
$H^{2}(G,\mu _{n})$
. More precisely, given an n-fold cover
$\widetilde {G}$
of G, we fix a continuous map
$\boldsymbol {s}:G\rightarrow \widetilde {G}$
such that
$\boldsymbol {p}\circ \boldsymbol {s}=\operatorname {id}$
. Then the corresponding cohomology class is related to the 2-cocycle
$\sigma :G\times G\rightarrow \mu _{n}$
satisfying
$$ \begin{align} \boldsymbol{s}(g_{1})\boldsymbol{s}(g_{2})\sigma(g_{1},g_{2})=\boldsymbol{s}(g_{1}g_{2}),\quad g_{1},g_{2}\in G. \end{align} $$
For two covers
$\widetilde {G}_{1}$
and
$\widetilde {G}_{2}$
realized by 2-cocycles
$\sigma _{1}$
and
$\sigma _{2}$
, respectively, the Baer sum of
$\widetilde {G}_{1}$
and
$\widetilde {G}_{2}$
is realized by the 2-cocycle
$\sigma _{1}\cdot \sigma _{2}$
.
By convention, for a closed subgroup H of G, we write
$\widetilde {H}$
for the preimage
$\boldsymbol {p}^{-1}(H)$
. We identify
$\mu _{n}$
with a central subgroup of
$\widetilde {G}$
.
A splitting of H is a continuous group homomorphism
$\boldsymbol {s}_{H}:H\rightarrow \widetilde {G}$
satisfying
$\boldsymbol {p}\circ \boldsymbol {s}_{H}=\operatorname {id}$
. In general, such a splitting may not exist or may not be unique. If H is a pro-p-group and
$\operatorname {gcd}(n,p)=1$
, then the cohomology group
$H^{2}(H,\mu _{n})$
is trivial, implying that there exists a unique splitting
$\boldsymbol {s}_{H}$
of H. Thus, we identify H with a subgroup
$\boldsymbol {s}_{H}(H)$
of
$\widetilde {H}$
, which we denote by
$\,_{s}H$
. For a representation
$\rho $
of H, we similarly write
$\,_{s}\rho $
for the corresponding representation of
$\,_{s}H$
. In general, even if the splittings of H are not unique, we may still define
$\,_{s}H$
and
$\,_{s}\rho $
as above once we fix a splitting
$\boldsymbol {s}_{H}$
. We refer to [Reference Ngo58] for a similar setting.
The commutator
$[\cdot ,\cdot ]:\widetilde {G}\times \widetilde {G}\rightarrow \widetilde {G}$
factors through
$G\times G$
, and we denote by
$[\cdot ,\cdot ]_{\sim }:G\times G\rightarrow \widetilde {G}$
the resulting map. In particular, if
$g_{1},g_{2}\in G$
commute, then
$$ \begin{align} [g_{1},g_{2}]_{\sim}=\sigma(g_{1},g_{2})\sigma(g_{2},g_{1})^{-1}\in\mu_{n}. \end{align} $$
Similarly, the
$\widetilde {G}$
-conjugation on
$\widetilde {G}$
factors through G, so we may consider the G-conjugation on
$\widetilde {G}$
. It is clear that
$[g_{1}^{g},g_{2}^{g}]_{\sim }=[g_{1},g_{2}]_{\sim }$
for any
$g,g_{1},g_{2}\in G$
. Also, for
$H,H_{1},H_{2}$
closed subgroups of G, we define the coset
$g\widetilde {H}:=\boldsymbol {s}(g)\widetilde {H}$
and the double coset
$\widetilde {H_{1}}g\widetilde {H_{2}}:=\widetilde {H_{1}}\boldsymbol {s}(g)\widetilde {H_{2}}$
, which does not depend on the choice of the section
$\boldsymbol {s}$
.
For
$\widetilde {\rho }\in \operatorname {Rep}(\widetilde {H})$
, we say that
$g\in G$
intertwines
$\widetilde {\rho }$
if
$\boldsymbol {s}(g)$
intertwines
$\widetilde {\rho }$
, which does not depend on the choice of
$\boldsymbol {s}$
. We denote by
$I_{G}(\widetilde {\rho })$
the intertwining set of
$\widetilde {\rho }$
as a subset of G. Similarly, it makes sense to define the normalizer
$N_{G}(\widetilde {\rho })$
.
Fix a character
$\epsilon :\mu _{n}\rightarrow \mathbb {C}^{\times }$
. A representation
$\widetilde {\pi }$
of
$\widetilde {G}$
is called (
$\epsilon $
-)genuine if
$\mu _{n}$
acts by
$\epsilon $
on
$\widetilde {\pi }$
. We remark that essentially we only need to consider the case where
$\epsilon $
is primitive; otherwise, any
$\epsilon $
-genuine representation
$\widetilde {\pi }$
of
$\widetilde {G}$
corresponds to an
$\epsilon '$
-genuine representation of an
$n'$
-fold cover of G with
$n'$
dividing n, where
$\epsilon '$
is a primitive character of
$\mu _{n'}$
. So from now on, we also assume the character
$\epsilon $
to be primitive.
For a representation
$\rho $
and a splitting
$\boldsymbol {s}$
of H, we write
$\epsilon \cdot \,_{s}\rho $
for the extension of
$\,_{s}\rho $
as an
$\epsilon $
-genuine representation of
$\widetilde {H}$
.
For a representation
$\chi $
of H and a genuine representation
$\widetilde {\rho }$
of
$\widetilde {H}$
, the tensor product
$\widetilde {\rho }\otimes \chi :=\widetilde {\rho }\otimes (\chi \circ \boldsymbol {p})$
is well-defined as another genuine representation of
$\widetilde {H}$
. When
$\chi $
is a character, we write
$\widetilde {\rho }\chi $
or
$\widetilde {\rho }\cdot \chi $
instead.
4.2 Metaplectic covers of
$\operatorname {GL}_{r}(F)$
We consider metaplectic covers of
$\operatorname {GL}_{r}(F)$
, which, in the context of this article, are n-fold covers arising from Brylinski-Deligne covers (cf. [Reference Brylinski and Deligne14]). Roughly speaking, Brylinski and Deligne constructed a family of central extensions of a reductive group G over F by the second K-group:
Recall that the abelian group
$K_{2}(F)$
could be given by generators of the form
$\{x,y\}$
with
$x,y\in F^{\times }$
, subject only to the following relations (cf. [Reference Matsumoto51], [Reference Milnor52, Theorem 11.1]):
-
•
$\{x_{1}x_{2},y\}=\{x_{1},y\}\{x_{2},y\},\ \{y,x_{1}x_{2}\}=\{y,x_{1}\}\{y,x_{2}\}, \quad \text {for any}\ x_{1},x_{2},y\in F^{\times }.$
-
•
$\{x,1-x\}=1,\quad \text {for any}\ x\neq 0,1.$
Pushing out the map (cf. [Reference Gan, Gao and Weissman29, p3])
$$ \begin{align*}K_{2}(F)\rightarrow \mu_{n},\quad \{x,y\}\mapsto (x,y)_{n},\end{align*} $$
they got a family of n-fold covers
$\widetilde {G}$
of G.
Remark 4.1. As far as I understand, before the work of Brylinski-Deligne, the terminology ‘metaplectic covers’ means finite central covers of simple simply connected groups studied by Moore, Steinberg, Matsumoto, etc., and their push-outs, pull-backs, Baer sums as finite central covers of general reductive groups. See [Reference Gan, Gao and Weissman29] for more details.
We refer to Proposition 4.2 for the properties that are special for a metapletic cover instead of a general cover of
$\operatorname {GL}_{r}(F)$
.
We follow [Reference F. Gao and Weissman30] to characterize all the metaplectic covers of
$G=\operatorname {GL}_{r}(F)$
. Let T be the diagonal torus of G, let
$Y=\operatorname {Hom}(\mathbb {G}_{m},T)$
be the cocharacter lattice, and let
$W=W(G,T)$
be the corresponding Weyl group. Then the set of
$K_{2}(F)$
-extensions
$\hat {G}$
of G are in bijection with the set of W-invariant quadratic forms
$$ \begin{align*}Q:Y\rightarrow \mathbb{Z}.\end{align*} $$
This bijection is additive, saying that for two Brylinski-Deligne covers
$\hat {G}_{1}$
and
$\hat {G}_{2}$
of G with related quadratic forms being
$Q_{1}$
and
$Q_{2}$
, respectively, the quadratic form related to the Baer sum of
$\hat {G}_{1}$
and
$\hat {G}_{2}$
is
$Q_{1}+Q_{2}$
.
One way to pin down the above bijection is as follows: Let
$B_{Q}$
be the associated bilinear form given by
$$ \begin{align*}B_{Q}(y_{1},y_{2})=Q(y_{1}+y_{2})-Q(y_{1})-Q(y_{2}),\quad y_{1},y_{2}\in Y.\end{align*} $$
Then for
$y_{1},y_{2}\in Y$
and
$a,b\in F^{\times }$
, we have (cf. [Reference Brylinski and Deligne14, Corollary 3.14])
$$ \begin{align*}[y_{1}(a),y_{2}(b)]_{\sim}=\{a,b\}^{B_{Q}(y_{1},y_{2})},\end{align*} $$
where
$[\cdot ,\cdot ]_{\sim }:T\times T\rightarrow K_{2}(F)$
is the resulting commutator with respect to
$\hat {G}$
.
Moreover, we let
$e_{1},\dots ,e_{r}$
be the canonical basis of Y. Then such quadratic forms are in bijection with pairs of integers
$(\boldsymbol {a},\boldsymbol {b})$
given by
$\boldsymbol {a}=Q(e_{1})$
and
$\boldsymbol {b}=B_{Q}(e_{1},e_{2})$
. Likewise, this bijection is additive.
We consider two special Brylinski-Deligne covers of G. First, we consider the
$K_{2}(F)$
-extension
$\hat {G}_{1}$
related to the 2-cocycle
$$ \begin{align*}G\times G\rightarrow K_{2}(F),\quad (g_{1},g_{2})\mapsto\{\operatorname{det}(g_{1}),\operatorname{det}(g_{2})\}.\end{align*} $$
In this case, the corresponding pair of integers is
$(\boldsymbol {a},\boldsymbol {b})=(1,2)$
. We let
$\widetilde {G}_{1}$
be the corresponding n-fold metaplectic cover of G. Then it is related to the 2-cocycle
$$ \begin{align} \sigma_{\operatorname{det}}:G\times G\rightarrow\mu_{n},\quad (g_{1},g_{2})\mapsto(\operatorname{det}(g_{1}),\operatorname{det}(g_{2}))_{n}. \end{align} $$
We further consider the canonical
$K_{2}(F)$
-extension of
$\operatorname {SL}_{r+1}(F)$
considered by Matsumoto with respect to the Steinberg symbol
$\{\cdot ,\cdot \}^{-1}:F^{\times }\times F^{\times }\rightarrow K_{2}(F)$
(cf. [Reference Matsumoto51], [Reference Milnor52, §12]). Via the pull-back of the embedding
$$ \begin{align*}\operatorname{GL}_{r}(F)\rightarrow\operatorname{SL}_{r+1}(F),\quad g\mapsto(\operatorname{det}(g)^{-1},g),\end{align*} $$
we get a
$K_{2}(F)$
-extension of G, which we denote by
$\hat {G}_{2}$
. In this case, the corresponding pair of integers is
$(\boldsymbol {a},\boldsymbol {b})=(1,1)$
. We let
$\widetilde {G}_{2}$
be the corresponding n-fold metaplectic cover of
$G=\operatorname {GL}_{r}(F)$
. In [Reference Kazhdan and Patterson48, §0.I], [Reference Banks, Levy and Sepanski4], a special 2-cocycle
$\sigma _{\mathrm {KP}}:G\times G\rightarrow \mu _{n}$
related to the cover
$\widetilde {G}_{2}$
is constructed for each r. It is trivial when
$r=1$
and satisfies the following block-compatibility:
$$ \begin{align} \begin{aligned} \sigma_{\mathrm{KP}}(\operatorname{diag}(g_1,\dots,g_k),\operatorname{diag}(g_1',\dots,g_k'))= \bigg[\prod_{i=1}^k\sigma_{\mathrm{KP}}(g_i,g_i')\bigg]\cdot\bigg[\prod_{1\leq i<j\leq k}(\det(g_i),\det(g_j'))_n\bigg], \end{aligned} \end{align} $$
where
$g_{i},g_{i}'\in \operatorname {GL}_{r_{i}}(F)$
for each
$i=1,\dots ,k$
and
$r=r_{1}+\cdots +r_{k}$
.
Since
$(1,2)$
and
$(1,1)$
generate
$\mathbb {Z}\times \mathbb {Z}$
, the integral combination of
$\hat {G}_{1}$
and
$\hat {G}_{2}$
with respect to the Baer sum ranges over all the equivalence classes of Brylinski-Deligne covers of G, and the integral combination of
$\widetilde {G}_{1}$
and
$\widetilde {G}_{2}$
ranges over all the n-fold metaplectic covers of G. In other words, when
$(\boldsymbol {c},\boldsymbol {d})$
ranges over
$\mathbb {Z}/n\mathbb {Z}\times \mathbb {Z}/n\mathbb {Z}$
, the corresponding 2-cocycle
$\sigma _{\operatorname {det}}^{\boldsymbol {c}}\cdot \sigma _{\mathrm {KP}}^{\boldsymbol {d}}$
represents all the n-fold metaplectic covers of G.
We fix a pair of integers
$(\boldsymbol {c},\boldsymbol {d})$
, and we let
$\sigma =\sigma _{\operatorname {det}}^{\boldsymbol {c}}\cdot \sigma _{\mathrm {KP}}^{\boldsymbol {d}}$
be the related 2-cocycle for
$r\geq 1$
. We let
$\widetilde {G}$
be the related n-fold metaplectic cover of G. We list various properties of
$\sigma $
.
Proposition 4.2.
-
(1)
$\sigma (x,y)=(x,y)_{n}^{\boldsymbol {c}}$
for
$r=1$
and
$x,y\in F^{\times }$
. -
(2) For
$r=r_{1}+\dots +r_{k}$
and
$g_{i},g_{i}'\in \operatorname {GL}_{r_{i}}(F)$
, we have (4.7)
$$ \begin{align} \begin{aligned} &\sigma(\operatorname{diag}(g_1,\dots,g_k),\operatorname{diag}(g_1',\dots,g_k'))\\=& \bigg[\prod_{i=1}^k\sigma(g_i,g_i')\bigg]\cdot\bigg[\prod_{1\leq i<j\leq k}(\det(g_i),\det(g_j'))_n\bigg]^{\boldsymbol{c}+\boldsymbol{d}}\cdot\bigg[\prod_{1\leq j<i\leq k}(\det(g_i),\det(g_j'))_n\bigg]^{\boldsymbol{c}}. \end{aligned} \end{align} $$
-
(3) Keep the notation of (2) and assume
$g=\operatorname {diag}(g_{1},\dots ,g_{k})$
and
$g'=\operatorname {diag}(g_{1}',\dots ,g_{k}')$
commute. Then (4.8)
$$ \begin{align} [g,g']_{\sim}=\prod_{i=1}^{k}[g_{i},g_{i}']_{\sim}\cdot\prod_{i\neq j}(\operatorname{det}(g_{i}),\operatorname{det}(g_{j}))_{n}^{2\boldsymbol{c}+\boldsymbol{d}}. \end{align} $$
-
(4) For
$g\in G$
and
$z=\lambda I_{r}\in Z(G)$
, we have (4.9)
$$ \begin{align} [z,g]_{\sim}=(\lambda,\operatorname{det}(g))_{n}^{(2\boldsymbol{c}+\boldsymbol{d})r-\boldsymbol{d}}. \end{align} $$
-
(5) Let
$r=r_{1}+\dots +r_{k}$
and let
$E_{i}/F$
be a field extension of degree
$d_{i}$
such that
$r_{i}=d_{i}r_{i}'$
for each i. Fix an F-algebra embedding
$\bigoplus _{i=1}^{k}E_{i}\hookrightarrow \operatorname {M}_{r}(F)$
.-
(a) If
$d_{i}=r_{i}$
for each i, then for
$u=(u_{1},\dots ,u_{k}), v=(v_{1},\dots ,v_{k})\in \bigoplus _{i=1}^{k}E_{i}^{\times }$
, we have (4.10)
$$ \begin{align} [u,v]_{\sim}=\bigg[\prod_{i=1}^{k}(u_{i},v_{i})_{n,E_{i}}^{-\boldsymbol{d}}\bigg]\cdot(\operatorname{det}_{F}(u),\operatorname{det}_{F}(v))_{n,F}^{2\boldsymbol{c}+\boldsymbol{d}}. \end{align} $$
-
(b) In general, consider the centralizer of
$\bigoplus _{i=1}^{k}E_{i}$
in
$\operatorname {M}_{r}(F)$
, which induces an F-algebra embedding
$\operatorname {M}_{r_{1}'}(E_{1})\times \dots \times \operatorname {M}_{r_{k}'}(E_{k})\hookrightarrow \operatorname {M}_{r}(F)$
. Then for
$u=(u_{1},\dots ,u_{k})\in \bigoplus _{i=1}^{k}E_{i}^{\times }$
and
$v=(v_{1},\dots ,v_{k})\in \operatorname {GL}_{r_{1}'}(E_{1})\times \dots \times \operatorname {GL}_{r_{k}'}(E_{k})$
, we have (4.11)
$$ \begin{align} \begin{aligned} [u,v]_{\sim}&=\bigg[\prod_{i=1}^{k}(u_{i},\operatorname{det}_{E_{i}}(v_{i}))_{n,E_{i}}^{-\boldsymbol{d}}\bigg]\cdot(\operatorname{det}_{F}(u),\operatorname{det}_{F}(v))_{n,F}^{2\boldsymbol{c}+\boldsymbol{d}}\\ &=\prod_{i=1}^{k}(\operatorname{det}_{F}(u)^{2\boldsymbol{c}+\boldsymbol{d}}u_{i}^{-\boldsymbol{d}},\operatorname{det}_{E_{i}}(v_{i}))_{n,E_{i}}. \end{aligned} \end{align} $$
-
-
(6) The 2-cocycle
$\sigma $
splits on
$\operatorname {GL}_{r}(\mathfrak {o}_{F})\times \operatorname {GL}_{r}(\mathfrak {o}_{F})$
. Thus, there exists a splitting
$\operatorname {GL}_{r}(\mathfrak {o}_{F})\rightarrow \widetilde {G}$
, and any two splittings differ by a character of
$\mathfrak {o}_{F}^{\times }$
composing with the determinant map. In general, for any open compact subgroup K of
$\operatorname {GL}_{r}(F)$
, there exists a splitting
$K\rightarrow \widetilde {G}$
.
Proof. Statement (1) is direct.
Statement (2)(3)(4) follow from [Reference Kaplan, Lapid and Zou46, Lemma 4.1], and statement (5a) follows from [Reference Kazhdan and Patterson48, Proposition 0.1.5] in the case
$\boldsymbol {d}=1$
. The general cases follow easily from the fact that
$\sigma =\sigma _{\mathrm {KP}}^{\boldsymbol {d}}\cdot \sigma _{\operatorname {det}}^{\boldsymbol {c}}$
and a direct calculation (cf. (4.3)).
For statement (5b), we notice that
$[u,\cdot ]_{\sim }$
is a character of
$\operatorname {GL}_{r_{1}'}(E_{1})\times \dots \times \operatorname {GL}_{r_{k}'}(E_{k})$
, which is trivial on the derived subgroup
$\operatorname {SL}_{r_{1}'}(E_{1})\times \dots \times \operatorname {SL}_{r_{k}'}(E_{k})$
. So we only need to verify the formula (4.11) for those
$v_{i}$
diagonal in
$\operatorname {GL}_{r_{i}'}(E_{i})$
for each i. Then we may use (4.10) with respect to an F-algebra embedding
$$ \begin{align*}\underbrace{E_{1}\times\dots\times E_{1}}_{r_{1}'\text{-copies}}\times\dots\times \underbrace{E_{k}\times\dots\times E_{k}}_{r_{k}'\text{-copies}}\hookrightarrow \operatorname{M}_{r}(F).\end{align*} $$
The first part of statement (6) follows from [Reference Kazhdan and Patterson48, Proposition 0.1.2] and the fact that
$(\cdot ,\cdot )_{n,F}$
is trivial on
$\mathfrak {o}_{F}^{\times }\times \mathfrak {o}_{F}^{\times }$
when
$\operatorname {gcd}(q,n)=1$
. The second part is trivial. In the final part, since K and
$\operatorname {GL}_{r}(\mathfrak {o}_{F})$
are conjugate by some
$g\in G$
, we simply take the conjugation of the corresponding splitting of
$\operatorname {GL}_{r}(\mathfrak {o}_{F})$
as a splitting of K.
From now on, we fix
$r\geq 1$
,
$(\boldsymbol {c},\boldsymbol {d})\in \mathbb {Z}\times \mathbb {Z}$
and
$\sigma $
as above. We let
$\widetilde {G}$
be the n-fold metaplectic cover of
$G=\operatorname {GL}_{r}(F)$
corresponding to
$\sigma $
. For a closed subgroup H of G, we define
$$ \begin{align*}H^{(n)}=\{h\in H\mid\operatorname{det}(h)\in F^{\times n}\}.\end{align*} $$
Let
$P=MN$
be a parabolic subgroup of G with a Levi factor M and the unipotent radical N, where we assume that M is isomorphic to
$\operatorname {GL}_{r_{1}}(F)\times \dots \times \operatorname {GL}_{r_{k}}(F)$
with
$r=r_{1}+\dots +r_{k}$
. Since N is a pro-p-group, there exists a unique splitting of N into
$\widetilde {G}$
. Thus, we may realize N as a subgroup of
$\widetilde {G}$
, which we still denote by N. So
$\widetilde {P}=\widetilde {M}N$
is a parabolic subgroup of
$\widetilde {G}$
with a Levi factor
$\widetilde {M}$
and the unipotent radical N.
Let
$H=H_{1}\times \dots \times H_{k}$
be a subgroup of M, such that each
$H_{i}$
is a closed subgroup of
$\operatorname {GL}_{r_{i}}(F)$
. We call H block compatible if
$[H_{i},H_{j}]_{\sim }=\{1\}$
for any
$1\leq i<j\leq k$
. We notice that H is block compatible in the following two cases (cf. (4.8)):
-
• For any i, we have
$H_{i}=H_{i}^{(n)}$
; -
• For any i, the determinant of every element in
$H_{i}$
is in
$\mathfrak {o}_{F}^{\times }$
.
This concept becomes important when considering (exterior) tensor product of genuine representations. Let
$\widetilde {\rho }_{i}$
be genuine representations of
$\widetilde {H_{i}}$
for each i. We take the tensor product
$\widetilde {\rho }_{1}\boxtimes \dots \boxtimes \widetilde {\rho }_{k}$
as a representation of
$\widetilde {H_{1}}\times \dots \times \widetilde {H_{k}}$
, which is trivial on
$$ \begin{align*}\Xi=\{(\zeta_{1},\dots,\zeta_{k})\in\mu_{n}\times\dots\times\mu_{n}\mid \zeta_{1}\dots\zeta_{k}=1\}.\end{align*} $$
If H is block compatible, then it is clear that
$$ \begin{align*}\widetilde{H}\cong\widetilde{H_{1}}\times\dots\times\widetilde{H_{k}}/\Xi,\end{align*} $$
so we realize
$\widetilde {\rho }_{1}\boxtimes \dots \boxtimes \widetilde {\rho }_{k}$
as a genuine representation of
$\widetilde {H}$
.
In particular, we emphasize the following three special classes of covers:
-
• (Determinantal covers) When
$\boldsymbol {d}=0$
, we get determinantal covers. We remark that such a cover is not far from the corresponding linear group since for any closed subgroup H of G, the group
$\widetilde {H^{(n)}}$
is isomorphic to
$H^{(n)}\times \mu _{n}$
. Moreover,
$H/H^{(n)}$
is of finite index. So the representation theory of
$\widetilde {G}$
is easily deduced from that of G. -
• (The Kazhdan-Patterson covers) When
$\boldsymbol {d}=1$
, we get Kazhdan-Patterson covers (KP-covers for short) (cf. [Reference Kazhdan and Patterson48]) Such covers are natural, in the sense that they could be regarded as the Baer sum of the pull-back of the canonical cover of
$\operatorname {SL}_{r+1}(F)$
and a determinantal cover. Moreover, there exists a functorial lift from representations of a KP-cover to that of G; see, for instance, [Reference Flicker and Kazhdan28], [Reference Zou80], etc. -
• (Savin’s cover) When
$\boldsymbol {c}=-1$
and
$\boldsymbol {d}=2$
, we get a special cover constructed by Gordan Savin (S-cover for short); see, for instance, [Reference F. Gao and Weissman30, §4.1]. It can be realized as follows: first, we construct the canonical cover of the symplectic group
$\operatorname {Sp}_{2r}(F)$
with respect to the Steinberg symbol
$(\cdot ,\cdot )_{n}^{-1}$
, and then after identifying G with the Siegel Levi subgroup of
$\operatorname {Sp}_{2r}(F)$
, we get the S-cover of G. Every Levi subgroup of G is block compatible, which can be seen from formula (4.8) since
$2\boldsymbol {c}+\boldsymbol {d}=0$
.
5 Strata and simple characters
In this section, we recall the theory of strata and simple characters related to
$G=\operatorname {GL}_{r}(F)$
, developed by Bushnell and Kutzko. Our main reference is [Reference Bushnell and Kutzko19], [Reference Bushnell and Kutzko23] and [Reference Sécherre and Stevens66]. We also recommend [Reference Bushnell16] as an excellent survey.
5.1 Lattice sequences and lattice chains
Fix an r-dimensional vector space V over F and a basis
$\{v_{1},\dots ,v_{r}\}$
of V under which we identify G with
$\operatorname {Aut}_{F}(V)$
. We write
$A=\operatorname {End}_{F}(V)\cong \operatorname {M}_{r}(F)$
. For
$\beta \in A$
, we define
$\psi _{\beta }(x)=\psi _{F}(\operatorname {tr}(\beta (x-1)))$
for
$x\in A$
.
An
$\mathfrak {o}_{F}$
-lattice sequence
$\Lambda =(\Lambda _{k})_{k\in \mathbb {Z}}$
of V is a sequence of
$\mathfrak {o}_{F}$
-lattices of V, such that
-
•
$\Lambda _{k+1}\subset \Lambda _{k}$
for any
$k\in \mathbb {Z}$
. -
• There exists a positive integer
$e=e(\Lambda |\mathfrak {o}_{F})$
, called the period of
$\Lambda $
over
$\mathfrak {o}_{F}$
, such that
$\Lambda _{k+e}=\mathfrak {p}_{F}\Lambda _{k}$
for any
$k\in \mathbb {Z}$
.
When
$\Lambda _{k+1}\subsetneq \Lambda _{k}$
for each
$k\in \mathbb {Z}$
, we call
$\Lambda $
a strict lattice sequence, or a lattice chain of V. We denote by
$\mathscr {L}(V,\mathfrak {o}_{F})$
(resp.
$\mathscr {L}^{+}(V,\mathfrak {o}_{F})$
) the set of
$\mathfrak {o}_{F}$
-lattice sequences (resp.
$\mathfrak {o}_{F}$
-lattice chains) of V.
We may realize a lattice sequence
$\Lambda $
as a function defined on
$\mathbb {R}$
by imposing
$\Lambda _{x}=\Lambda _{\lceil x\rceil }$
for
$x\in \mathbb {R}$
.
For
$\Lambda \in \mathscr {L}(V,\mathfrak {o}_{F})$
, we define a lattice sequence
$\mathfrak {A}(\Lambda )\in \mathscr {L}(A,\mathfrak {o}_{F})$
by
$$ \begin{align*}\mathfrak{A}_{k}(\Lambda)=\{a\in A\mid a\Lambda_{l}\subset\Lambda_{l+k},\ l\in\mathbb{Z} \},\quad k\in\mathbb{Z}.\end{align*} $$
In particular,
$\mathfrak {a}=\mathfrak {A}_{0}(\Lambda )$
is a hereditary order in A, and
$\mathfrak {p}_{\mathfrak {a}}=\mathfrak {A}_{1}(\Lambda )$
is the Jacobson radical of
$\mathfrak {a}$
. We define the valuation map
$$ \begin{align*}v_{\Lambda}:A\rightarrow \mathbb{Z},\ x\mapsto\mathrm{max}\{k\in\mathbb{Z}\mid x\in\mathfrak{A}_{k}(\Lambda)\}\end{align*} $$
with the convention
$v_{\Lambda }(0)=\infty $
. We write
$U(\Lambda )=\mathfrak {A}_{0}^{\times }$
and
$U_{k}(\Lambda )=1+\mathfrak {A}_{k}(\Lambda )$
for
$k\geq 1$
.
Up to the choice of an F-basis of V, we may realize
$\mathfrak {a}$
as a standard hereditary order in
$\operatorname {M}_{r}(F)$
, meaning that there exists a composition
$r_{1}+\dots +r_{t}=r$
such that
$$ \begin{align*}\mathfrak{a}=\{(a_{ij})_{1\leq i,j\leq t}\mid a_{ij}\in\operatorname{M}_{r_{i}\times r_{j}}(\mathfrak{o}_{F})\ \text{for}\ 1\leq i\leq j\leq t\ \text{and}\ a_{ij}\in\operatorname{M}_{r_{i}\times r_{j}}(\mathfrak{p}_{F})\ \text{for}\ 1\leq j< i\leq t\}.\end{align*} $$
If
$\Lambda $
is strict, then
$\mathfrak {A}_{k}(\Lambda )=\mathfrak {p}_{\mathfrak {a}}^{k}$
for any
$k\in \mathbb {Z}$
. Indeed, it is not hard to show that
$\mathscr {L}^{+}(V,\mathfrak {o}_{F})\rightarrow \mathscr {L}^{+}(A,\mathfrak {o}_{F}),\ \Lambda \rightarrow \mathfrak {A}(\Lambda )$
is a bijection, so we may somehow recover the corresponding lattice chain from a given hereditary order
$\mathfrak {a}$
in A.
Let E be a subfield of A over F. Then we may realize V as a vector space over E, which we denote by
$V_{E}$
. Let
$B=\operatorname {End}_{E}(V)$
, which is an F-subalgebra of A. Then
$B^{\times }$
is the centralizer of
$E^{\times }$
in G. Let
$\psi _{E}$
be a character of E of conductor
$\mathfrak {p}_{E}$
. Then there exists a bi-B-module homomorphism
$s:A\rightarrow B$
such that
$$ \begin{align*}\psi_{E}(\operatorname{tr}_{E}(s(a)b))=\psi_{F}(\operatorname{tr}_{F}(ab)),\quad a\in A,\ b\in B,\end{align*} $$
called a tame corestriction on A.
A sequence
$\Lambda \in \mathscr {L}(V,\mathfrak {o}_{F})$
is called E-pure if it is normalized by
$E^{\times }$
. In this case, each
$\Lambda _{k}$
is an
$\mathfrak {o}_{E}$
-lattice. Moreover,
$\Lambda $
could be realized as an element in
$\mathscr {L}(V_{E},\mathfrak {o}_{E})$
, which we denote by
$\Lambda _{E}$
. By definition,
$\mathfrak {A}_{k}(\Lambda _{E})=\mathfrak {A}_{k}(\Lambda )\cap B$
for each
$k\in \mathbb {Z}$
. Let
$\mathfrak {b}=\mathfrak {A}_{0}(\Lambda _{E})$
, which is a hereditary order in B. Let
$\mathfrak {p}_{\mathfrak {b}}=\mathfrak {A}_{1}(\Lambda _{E})$
.
We consider a decomposition
$V=\bigoplus _{i=1}^{t} V^{i}$
of F-vector spaces. It is called an E-decomposition if each
$V^{i}$
is E-stable. In this case, we have
$V_{E}=\oplus _{i=1}^{t}V_{E}^{i}$
.
Let
$M=\prod _{i=1}^{t}\operatorname {Aut}_{F}(V^{i})\subset G$
and let
$P=MN$
be a parabolic subgroup of G having a Levi factor M and the unipotent radical N. For an E-decomposition
$V=\bigoplus _{i=1}^{t} V^{i}$
, we get a parabolic subgroup
$P_{E}=P\cap B^{\times }$
of
$B^{\times }$
, having a Levi factor
$M_{E}=M\cap B^{\times }$
and the unipotent radical
$N_{E}=N\cap B^{\times }$
.
Let
$\Lambda ^{i}\in \mathscr {L}(V^{i},\mathfrak {o}_{F})$
for
$i=1,\dots t$
. Then the direct sum
$\Lambda =\bigoplus _{i=1}^{t}\Lambda ^{i}$
is well-defined as an element in
$\mathscr {L}(V,\mathfrak {o}_{F})$
. On the other hand, we say that a decomposition
$V=\bigoplus _{i=1}^{t} V^{i}$
conforms with
$\Lambda \in \mathscr {L}(V,\mathfrak {o}_{F})$
if there exists
$\Lambda ^{i}\in \mathscr {L}(V^{i},\mathfrak {o}_{F})$
for each i such that
$\Lambda =\bigoplus _{i=1}^{t}\Lambda ^{i}$
. In this case, we necessarily have
$\Lambda ^{i}=\Lambda \cap V^{i}$
. Furthermore, if
$V=\bigoplus _{i=1}^{t} V^{i}$
is an E-decomposition and each
$\Lambda ^{i}$
is E-pure, we get the decomposition
$\Lambda _{E}=\bigoplus _{i=1}^{t}\Lambda _{E}^{i}$
.
5.2 Strata
A stratum in A is a
$4$
-tuple
$[\Lambda ,u,l,\beta ]$
, where
$\Lambda \in \mathscr {L}(V,\mathfrak {o}_{F})$
, and
$u,l$
are integers such that
$0\leq l\leq u-1$
, and
$\beta \in \mathfrak {A}_{-u}(\Lambda )$
.
If the stratum we consider is strict, saying that
$\Lambda $
is strict, then conventionally we often write
$[\mathfrak {a},u,l,\beta ]$
for the same stratum to emphasize this assumption, where
$\mathfrak {a}=\mathfrak {A}_{0}(\Lambda )$
. Conventionally, if an object
$\Gamma (\Lambda ,\beta ,\dots )$
is defined for a stratum with
$\Lambda $
strict, we often write
$\Gamma (\mathfrak {a},\beta ,\dots )$
instead.
Two strata
$[\Lambda ,u,l,\beta _{1}]$
and
$[\Lambda ,u,l,\beta _{2}]$
are called equivalent if
$\beta _{1}-\beta _{2}\in \mathfrak {A}_{-l}(\Lambda )$
.
For a stratum
$[\Lambda ,u,l,\beta ]$
in A such that
$0\leq l<u\leq 2l+1$
, we notice that
$\psi _{\beta }$
becomes a character of
$U^{l+1}(\Lambda )/U^{u+1}(\Lambda )$
, which depends only on the equivalence class of
$[\Lambda ,u,l,\beta ]$
.
Assume that
$[\Lambda ,u,l,\beta ]$
is pure, which means that
$E:=F[\beta ]$
is a field and
$\Lambda $
is E-pure. In this case, we let B be the centralizer of E in A. Once a related tame corestriction
$s:A\rightarrow B$
is fixed, a derived stratum of
$[\Lambda ,u,l,\beta ]$
is a stratum
$[\Lambda _{E},l,l-1,s(c)]$
in B with
$c\in \mathfrak {A}_{-l}(\Lambda )$
.
For
$k\in \mathbb {Z}$
, we define
$$ \begin{align*}\mathfrak{n}_{k}(\beta,\Lambda)=\{x\in\mathfrak{a}\mid \beta x-x\beta\in \mathfrak{A}_{k}(\Lambda)\}.\end{align*} $$
If
$E\neq F$
, there exists a maximal integer k such that
$\mathfrak {n}_{k}(\beta ,\Lambda )$
is not contained in
$\mathfrak {b}+\mathfrak {p}_{\mathfrak {a}}$
, which we denote by
$k_{0}(\beta ,\Lambda )$
. Then
$k_{0}(\beta ,\Lambda )\geq -u$
since
$\mathfrak {n}_{-u}(\beta ,\Lambda )=\mathfrak {a}$
. If
$E=F$
, we let
$k_{0}(\beta ,\Lambda )=-\infty $
. Then we call a pure stratum
$[\Lambda ,u,l,\beta ]$
simple if
$l<-k_{0}(\beta ,\Lambda )$
.
Assume that we have an E-decomposition
$V=\bigoplus _{i=1}^{t}V^{i}$
. Fix a simple stratum
$[\Lambda ,u,l,\beta ]$
in A and assume that
$\Lambda $
conforms with this decomposition. Then each
$[\Lambda ^{i},u,l,\beta ]$
is a simple stratum in
$A^{i}=\operatorname {End}_{F}(V^{i})$
for
$i=1,\dots ,t$
(cf. [Reference Sécherre and Stevens66, Proposition 1.20]).
In particular, we consider a stratum of the form
$[\Lambda ,u,u-1,b]$
. Let
$e=e(\Lambda |\mathfrak {o}_{F})$
. The element
$\varpi _{F}^{u/\operatorname {gcd}(u,e)}b^{e/\operatorname {gcd}(u,e)}$
is in
$\mathfrak {a}^{\times }$
. So its characteristic polynomial has coefficients in
$\mathfrak {o}_{F}$
, whose reduction module
$\mathfrak {p}_{F}$
in
$\boldsymbol {k}[X]$
is called the characteristic polynomial of
$[\Lambda ,u,u-1,b]$
and denoted by
$\varphi _{b}$
.
Then a stratum
$[\Lambda ,u,u-1,b]$
is called
-
• fundamental if
$\varphi _{b}$
is not a power of X. -
• split if
$\varphi _{b}$
has at least two different irreducible factors. -
• minimal if it is simple or, in other words,
$k_{0}(b,\Lambda )=-u$
.
Finally, we also allow the occurrence of a ‘null’ stratum
$[\Lambda ,0,0,\beta ]$
, where
$\Lambda $
is a lattice chain such that the corresponding hereditary order
$\mathfrak {a}$
is maximal in A, and
$\beta \in \mathfrak {o}_{F}$
. In this case, we have
$E=F$
and
$A=B$
.
5.3 Simple characters
Let
$[\Lambda ,u,0,\beta ]$
be a simple stratum in
$A=\operatorname {End}_{F}(V)$
and let
$E=F[\beta ]$
. We first assume
$\Lambda $
, as well as the occurring lattice sequences, to be strict. As in [Reference Bushnell and Kutzko19, §3] and [Reference Sécherre and Stevens66, §2],
-
(1) We define two sub-
$\mathfrak {o}_{F}$
-orders
$\mathfrak {H}(\beta ,\Lambda )\subset \mathfrak {J}(\beta ,\Lambda )$
of
$\mathfrak {a}$
, which depend only on the equivalence class of
$[\Lambda ,u,0,\beta ]$
. Each of them is filtered by a sequence of bilateral ideals correspondingly:
$$ \begin{align*}\mathfrak{H}^{k}(\beta,\Lambda)=\mathfrak{H}(\beta,\Lambda)\cap\mathfrak{A}_{k}(\Lambda),\quad \mathfrak{J}^{k}(\beta,\Lambda)=\mathfrak{J}(\beta,\Lambda)\cap\mathfrak{A}_{k}(\Lambda),\quad k\geq 1.\end{align*} $$
We denote by
$H(\beta ,\Lambda )$
(resp.
$J(\beta ,\Lambda )$
) the subgroup of invertible elements in
$\mathfrak {H}(\beta ,\Lambda )$
(resp.
$\mathfrak {J}(\beta ,\Lambda )$
). Then similarly, each of them is filtered by a sequence of open compact subgroups
$$ \begin{align*}H^{k}(\beta,\Lambda)=H(\beta,\Lambda)\cap U^{k}(\Lambda),\quad J^{k}(\beta,\Lambda)=J(\beta,\Lambda)\cap U^{k}(\Lambda),\quad k\geq 1.\end{align*} $$
We also have
$J(\beta ,\Lambda )=U(\Lambda _{E})J^{1}(\beta ,\Lambda )$
. -
(2) For each
$0\leq l\leq k_{0}(\beta ,\Lambda )-1$
, we define a finite set
$\mathcal {C}(\Lambda ,l,\beta )$
of characters of
$H^{l+1}(\beta ,\Lambda )$
, called simple characters of level l attached to
$[\Lambda ,u,0,\beta ]$
. We write
$\mathcal {C}(\Lambda ,\beta )=\mathcal {C}(\Lambda ,0,\beta )$
for short. We remark that
$\mathcal {C}(\Lambda ,l,\beta )$
depends on the choice of
$\psi _{F}$
. -
(3) Let
$v=-k_{0}(\beta ,\Lambda )>0$
. For
$k\geq 1$
, we define (5.1)
$$ \begin{align} \mathfrak{m}_{k}(\beta,\Lambda)=\mathfrak{A}_{k}(\Lambda)\cap\mathfrak{n}_{k-v}(\beta,\Lambda)+\mathfrak{J}^{\lceil v/2\rceil}(\beta,\Lambda)\quad\text{and}\quad\Omega_{k}(\beta,\Lambda)=1+\mathfrak{m}_{k}(\beta,\Lambda). \end{align} $$
Then for
$\theta \in \mathcal {C}(\Lambda ,l,\beta )$
, we have (5.2)
$$ \begin{align} I_{G}(\theta)=\Omega_{v-l}(\beta,\Lambda)B^{\times}\Omega_{v-l}(\beta,\Lambda). \end{align} $$
In particular, if
$l=0$
, we have (5.3)
$$ \begin{align} I_{G}(\theta)=J(\beta,\Lambda)B^{\times}J(\beta,\Lambda). \end{align} $$
-
(4) Let V,
$V'$
be two finite dimensional F-vector spaces, let
$A=\operatorname {End}_{F}(V)$
and
$A'=\operatorname {End}_{F}(V')$
, let
$E=F[\beta ]$
and
$E'=F[\beta ']$
be subfields of A and
$A'$
, respectively, with an isomorphism
$E\rightarrow E'$
mapping
$\beta $
to
$\beta '$
. Let
$[\Lambda ,u,0,\beta ]$
(resp.
$[\Lambda ',u',0,\beta ']$
) be a strict simple stratum in A (resp.
$A'$
). Then we have a transfer map as a bijection
$$ \begin{align*}t_{\mathfrak{a},\mathfrak{a}',\beta,\beta'}:\mathcal{C}(\Lambda,l,\beta)\rightarrow\mathcal{C}(\Lambda',l',\beta'),\end{align*} $$
where we assume
$0\leq l\leq u-1$
,
$0\leq l\leq u'-1$
and
$\lfloor l/e(\Lambda |\mathfrak {o}_{E})\rfloor =\lfloor l'/e(\Lambda '|\mathfrak {o}_{E})\rfloor $
.In particular, in the following cases, this transfer map could be further characterized.
-
(a) Assume
$V=V'$
,
$l=l'$
, and there exists
$g\in \operatorname {Aut}_{F}(V)$
such that
$\beta '=\beta ^{g}$
and
$\mathfrak {a}'=\mathfrak {a}^{g}$
. Then the transfer map is given by the g-conjugation. -
(b) Assume
$V=V'$
and
$\beta =\beta '$
. Then for
$\theta \in \mathcal {C}(\Lambda ,l,\beta )$
, the transfer of
$\theta $
to
$\mathcal {C}(\Lambda ',l',\beta )$
coincides with
$\theta $
on
$H^{l+1}(\beta ,\Lambda )\cap H^{l'+1}(\beta ,\Lambda ')$
. -
(c) Assume that
$V=V'\oplus V"$
is an E-decomposition, and there exists an E-pure lattice chain
$\Lambda "$
in
$V"$
such that
$\Lambda =\Lambda '\oplus \Lambda "$
. Then for any
$l\leq u-1$
, we have
$H^{l}(\beta ,\Lambda )\cap \operatorname {Aut}_{F}(V')=H^{l}(\beta ',\Lambda ')$
. Moreover, for
$l'=l$
, the transfer map is given by the restriction to
$H^{l}(\beta ',\Lambda ')$
.
-
-
(5) Let
$V=\bigoplus _{i=1}^{t}V^{i}$
be an E-decomposition with
$E=F[\beta ]$
. Let
$\Lambda ^{i}$
be an E-pure lattice chainFootnote
3
in
$V^{i}$
for each i, such that
$\Lambda =\bigoplus _{i=1}^{t}\Lambda ^{i}$
. Then each
$[\Lambda ^{i},u,0,\beta ]$
is a simple stratum in
$A^{i}=\operatorname {End}_{F}(V^{i})$
. Let
$M=\prod _{i=1}^{t}\operatorname {Aut}_{F}(V^{i})$
be the corresponding Levi subgroup of G, and let
$P=MN$
be a parabolic subgroup of G having a Levi factor M. Then for
$\theta \in \mathcal {C}(\Lambda ,l,\beta )$
,-
(a) The pair
$(H^{l+1}(\beta ,\Lambda ),\theta )$
is decomposed with respect to
$(M,P')$
for any parabolic subgroup
$P'$
of G with a Levi factor M (cf. §3.4). -
(b) Moreover, we have
(5.4)with each
$$ \begin{align} H^{l+1}(\beta,\Lambda)\cap M=\prod_{i=1}^{t}H^{l+1}(\beta,\Lambda^{i})\quad\text{and}\quad \theta_{M}:=\theta\lvert_{H^{l+1}(\beta,\Lambda)\cap M}=\theta_{1}\otimes\dots\otimes\theta_{t}, \end{align} $$
$\theta _{i}$
being the transfer of
$\theta $
to
$\mathcal {C}(\Lambda ^{i},l,\beta )$
.
-
Now we consider a general lattice sequence
$\Lambda $
, and we explain how to generalize the above theory in this case. We refer to [Reference Sécherre and Stevens66, §2] for the missing details.
We construct an E-decomposition of F-vector spaces
$V"=V\oplus V'$
. Write
$A"=\operatorname {End}_{F}(V")$
, which contains
$A=\operatorname {End}_{F}(V)$
as a sub-F-algebra. For
$e=e(\Lambda |\mathfrak {o}_{F})$
, we choose a strict E-pure lattice sequence
$\Lambda '$
in
$V'$
of period e. Then the E-pure lattice sequence
$\Lambda "=\Lambda \oplus \Lambda '$
in
$V"$
is also strict and of period e. Moreover,
$[\Lambda ",u,0,\beta ]$
(after identifying
$\beta $
with an element in
$A"$
) is a simple stratum in
$A"$
.
We define
$$ \begin{align*}\mathfrak{H}(\beta,\Lambda)=\mathfrak{H}(\beta,\Lambda")\cap A\quad\text{and}\quad\mathfrak{J}(\beta,\Lambda)=\mathfrak{J}(\beta,\Lambda")\cap A\end{align*} $$
as
$\mathfrak {o}_{F}$
-orders in A. Then, we define
$\mathfrak {H}^{k}(\beta ,\Lambda )$
,
$\mathfrak {J}^{k}(\beta ,\Lambda )$
,
$H(\beta ,\Lambda )$
,
$J(\beta ,\Lambda )$
,
$H^{k}(\beta ,\Lambda )$
,
$J^{k}(\beta ,\Lambda )$
,
$\mathfrak {m}_{k}(\beta ,\Lambda )$
,
$\Omega _{k}(\beta ,\Lambda )$
as above.
We have
$H^{l+1}(\beta ,\Lambda ")\cap A=H^{l+1}(\beta ,\Lambda )$
for any
$l\geq 0$
. Moreover, for
$0\leq l<-k_{0}(\beta ,\Lambda ")$
, we define simple characters of level l attached to
$[\Lambda ,u,0,\beta ]$
to be the restriction of characters in
$\mathcal {C}(\Lambda ",l,\beta )$
to
$H^{l+1}(\beta ,\Lambda )$
. We denote by
$\mathcal {C}(\Lambda ,l,\beta )$
the set of such characters.
We remark that the above notation is well-defined (i.e., independent of the choice of
$V'$
,
$V"$
and
$\Lambda '$
), and it is compatible with the original theory when
$\Lambda $
is strict. Moreover, all the results for simple characters listed above remain valid.
For any simple stratum
$[\Lambda ,u,0,\beta ]$
in A, we may define a related strict simple stratum
$[\mathfrak {a},u',0,\beta ]$
in A, where
$\mathfrak {a}=\mathfrak {A}_{0}(\Lambda )$
and
$u'=-v_{\mathfrak {a}}(\beta )$
.
We also briefly recall the concept ‘endo-class’ introduced by Bushnell and Henniart [Reference Bushnell and Henniart17], although it will not be essentially used in this article. Let
$V_{1}$
,
$V_{2}$
be two finite dimensional vector spaces over F. Let
$[\mathfrak {a}_{1},u_{1},0,\beta _{1}]$
(resp.
$[\mathfrak {a}_{2},u_{2},0,\beta _{2}]$
) be a strict simple stratum in
$A_{1}=\operatorname {End}_{F}(V_{1})$
(resp.
$A_{2}=\operatorname {End}_{F}(V_{2})$
). We call
$\theta _{1}\in \mathcal {C}(\mathfrak {a}_{1},0,\beta _{1})$
and
$\theta _{2}\in \mathcal {C}(\mathfrak {a}_{2},0,\beta _{2})$
endo-equivalent if there exist an F-vector space V containing
$V_{1}$
and
$V_{2}$
, and two simple strata
$[\mathfrak {a}_{1}',u_{1},0,\beta _{1}']$
and
$[\mathfrak {a}_{2}',u_{2},0,\beta _{2}']$
in
$\operatorname {End}_{F}(V)$
, with
$F[\beta _{1}]\cong F[\beta ']$
and
$F[\beta _{2}]\cong F[\beta _{2}']$
mapping
$\beta _{1}$
to
$\beta _{1}'$
and
$\beta _{2}$
to
$\beta _{2}'$
, such that the transfers
$t_{\mathfrak {a}_{1},\mathfrak {a}_{1}',\beta _{1},\beta _{1}'}(\theta _{1})$
and
$t_{\mathfrak {a}_{2},\mathfrak {a}_{2}',\beta _{2},\beta _{2}'}(\theta _{2})$
are conjugate by
$G=\operatorname {Aut}_{F}(V)$
.
We notice that such an equivalence relation is independent of various choices above. Thus, we introduced an equivalence relation on
$$ \begin{align*}\bigcup_{[\mathfrak{a},u,0,\beta]}\mathcal{C}(\mathfrak{a},0,\beta),\end{align*} $$
where the union ranges over all the strata in
$\operatorname {M}_{r}(F)$
with r ranging over all positive integers. Such an equivalence class is called an endo-class.
Finally, for a ‘null’ stratum
$[\Lambda ,0,0,\beta ]$
in A and
$\beta \in \mathfrak {o}_{F}$
, by convention we have
$\mathfrak {H}(\beta ,\mathfrak {a})=\mathfrak {J}(\beta ,\mathfrak {a})=\mathfrak {a}$
,
$\mathfrak {H}^{i}(\beta ,\mathfrak {a})=\mathfrak {J}^{i}(\beta ,\mathfrak {a})=\mathfrak {p}_{\mathfrak {a}}^{i}$
,
$H(\beta ,\mathfrak {a})=J(\beta ,\mathfrak {a})=U(\mathfrak {a})$
,
$H^{i}(\beta ,\mathfrak {a})=J^{i}(\beta ,\mathfrak {a})=U^{i}(\mathfrak {a})$
and
$\mathcal {C}(\mathfrak {a},\beta )=\{1\}$
. In this case, the corresponding endo-class is trivial.
5.4 Heisenberg representations and
$\beta $
-extensions
The reference here is [Reference Bushnell and Kutzko19, §5.1, 5.2, 7.1, 7.2] and [Reference Sécherre64]. Let
$[\mathfrak {a},u,0,\beta ]$
be a strict simple stratum in
$A=\operatorname {End}_{F}(V)$
, where we denote by
$\Lambda $
the lattice chain related to
$\mathfrak {a}$
. Still we write
$E=F[\beta ]$
and
$B=\operatorname {End}_{E}(V_{E})$
. Let
$\theta \in \mathcal {C}(\mathfrak {a},\beta )$
.
There exists a unique irreducible representation
$\eta $
of
$J^{1}(\beta ,\mathfrak {a})$
, called the Heisenberg representation of
$\theta $
, whose restriction to
$H^{1}(\beta ,\mathfrak {a})$
contains
$\theta $
. The restriction of
$\eta $
to
$H^{1}(\beta ,\mathfrak {a})$
is isomorphic to
$[J^{1}(\beta ,\mathfrak {a}):H^{1}(\beta ,\mathfrak {a})]^{1/2}\cdot \theta $
. Also, we have
$$ \begin{align} I_{G}(\eta)=I_{G}(\theta)=J(\beta,\mathfrak{a})B^{\times}J(\beta,\mathfrak{a}). \end{align} $$
Moreover, each related intertwining space of
$\eta $
is of dimension
$1$
.
A representation
$\kappa $
of
$J(\beta ,\mathfrak {a})=U(\mathfrak {b})J^{1}(\beta ,\mathfrak {a})$
is called a
$\beta $
-extension of
$\eta $
if its restriction to
$J^{1}(\beta ,\mathfrak {a})$
is
$\eta $
, and moreover,
$I_{G}(\kappa )=I_{G}(\eta )$
. We notice that such
$\kappa $
exists, and all the other
$\beta $
-extensions of
$\eta $
are of the form
$\kappa \chi $
, where
$\chi $
ranges over characters of
$J(\beta ,\mathfrak {a})/J^{1}(\beta ,\mathfrak {a})\cong U(\mathfrak {b})/U^{1}(\mathfrak {b})$
that factor through
$\operatorname {det}_{E}:B^{\times }\rightarrow E^{\times }$
.
We define
$\boldsymbol {J}(\beta ,\mathfrak {a})=N_{B^{\times }}(U(\mathfrak {b}))J(\beta ,\mathfrak {a})$
as a compact modulo center subgroup of G. In particular, if
$\mathfrak {b}$
is a maximal hereditary order, then
$\boldsymbol {J}(\beta ,\mathfrak {a})=E^{\times }J(\beta ,\mathfrak {a})$
. Notice that
$\boldsymbol {J}(\beta ,\mathfrak {a})$
is indeed the normalizer of the simple character
$\theta $
; thus, it does not depend on the choice of the simple stratum
$[\mathfrak {a},u,0,\beta ]$
, but only on
$\theta $
.
Now we consider E-pure lattice chains
$\Lambda '$
and
$\Lambda "$
in A, such that the corresponding hereditary orders
$\mathfrak {a}'$
and
$\mathfrak {a}"$
satisfy
$\mathfrak {a}'\subset \mathfrak {a}\subset \mathfrak {a}"$
. Let
$u'=-v_{\mathfrak {a}'}(\beta )$
and
$u"=-v_{\mathfrak {a}"}(\beta )$
be two positive integers. Then
$[\mathfrak {a}',u',0,\beta ]$
and
$[\mathfrak {a}",u",0,\beta ]$
are simple strata in A. Let
$\theta '\in \mathcal {C}(\mathfrak {a}',\beta )$
and
$\theta "\in \mathcal {C}(\mathfrak {a}",\beta )$
be the corresponding transfers of
$\theta $
, and let
$\eta '$
and
$\eta "$
be the Heisenberg representations of
$\theta '$
and
$\theta "$
, respectively. Then, there exist unique
$\beta $
-extensions
$\kappa '$
of
$\eta '$
and
$\kappa "$
of
$\eta "$
, such that
$$ \begin{align} \begin{aligned} &\operatorname{ind}_{U(\mathfrak{b}')J^{1}(\beta,\mathfrak{a})}^{U(\mathfrak{b}')U^{1}(\mathfrak{a}')}(\kappa\lvert_{U(\mathfrak{b}')J^{1}(\beta,\mathfrak{a})})\cong\operatorname{ind}_{J(\beta,\mathfrak{a}')}^{U(\mathfrak{b}')U^{1}(\mathfrak{a}')}(\kappa')\\ \text{and}\quad&\operatorname{ind}_{U(\mathfrak{b})J^{1}(\beta,\mathfrak{a}")}^{U(\mathfrak{b})U^{1}(\mathfrak{a})}(\kappa"\lvert_{U(\mathfrak{b})J^{1}(\beta,\mathfrak{a}")})\cong\operatorname{ind}_{J(\beta,\mathfrak{a})}^{U(\mathfrak{b})U^{1}(\mathfrak{a})}(\kappa) \end{aligned} \end{align} $$
as irreducible representations (cf. [Reference Bushnell and Kutzko19, §5.2.14]). We call
$\kappa '$
(resp.
$\kappa "$
) the
$\beta $
-extension related to
$\kappa $
.
Finally, we consider an E-decomposition
$V=\bigoplus _{i=1}^{t}V^{i}$
which conforms with
$\Lambda $
. Let
$M=\prod _{i=1}^{t}\operatorname {Aut}_{F}(V^{i})$
be the corresponding Levi subgroup of G. We fix a parabolic subgroup
$P=MN$
of G having a Levi factor M.
Write
$\Lambda ^{i}=\Lambda \cap V^{i}$
,
$\mathfrak {a}^{i}=\mathfrak {A}_{0}(\Lambda ^{i})$
and
$\mathfrak {b}^{i}=\mathfrak {A}_{0}(\Lambda _E^{i})$
for
$i=1,\dots ,t$
.
Let
$\theta _{i}\in \mathcal {C}(\Lambda ^{i},\beta )$
be defined as in (5.4). Let
$\eta _{i}$
be the Heisenberg representation of
$\theta _{i}$
as a representation of
$J^{1}(\beta ,\Lambda ^{i})$
, and let
$\eta _{M}=\eta _{1}\boxtimes \dots \boxtimes \eta _{t}$
be an irreducible representation of
$$ \begin{align*}J^{1}_{M}(\beta,\mathfrak{a}):=J^{1}(\beta,\mathfrak{a})\cap M=J^{1}(\beta,\Lambda^{1})\times\dots\times J^{1}(\beta,\Lambda^{t}).\end{align*} $$
We define
$$ \begin{align} J^{1}_{P}(\beta,\mathfrak{a})=H^{1}(\beta,\mathfrak{a})(J^{1}(\beta,\mathfrak{a})\cap P)=(H^{1}(\beta,\mathfrak{a})\cap N^{-})\cdot(J^{1}(\beta,\mathfrak{a})\cap M)\cdot(J^{1}(\beta,\mathfrak{a})\cap N) \end{align} $$
as a pro-p-subgroup of
$J^{1}(\beta ,\mathfrak {a})$
, then there exists a unique irreducible representation
$\eta _{P}$
of
$J^{1}_{P}(\beta ,\mathfrak {a})$
, such that
-
•
$(J^{1}_{P}(\beta ,\mathfrak {a}),\eta _{P})$
is decomposed with respect to
$(M,P')$
for any parabolic subgroup
$P'$
of G with a Levi factor M. -
•
$\eta _{P}\lvert _{J^{1}_{M}(\beta ,\mathfrak {a})}=\eta _{M}$
. -
•
$\operatorname {ind}_{J^{1}_{P}(\beta ,\mathfrak {a})}^{J^{1}(\beta ,\mathfrak {a})}\eta _{P}=\eta $
.
To proceed, we further assume that the E-decomposition
$V=\bigoplus _{i=1}^{t}V^{i}$
is properly subordinate to
$\Lambda $
, meaning that (cf. [Reference Stevens73, Definition 5.1])
-
• it conforms with
$\Lambda $
; -
• for
$i=1,\dots ,t$
and
$j\in \mathbb {Z}$
, we have
$$ \begin{align*}\Lambda_{tj}^i=\Lambda_{tj+1}^i=\dots=\Lambda_{tj+i-1}^i\supsetneq \Lambda_{tj+i}^i=\dots=\Lambda_{t(j+1)}^i;\end{align*} $$
-
• for each
$i=1,\dots ,t$
, the hereditary order
$\mathfrak {b}^{i}$
in
$\operatorname {End}_E(V_E^i)$
is maximal.
In this case, the hereditary order
$\mathfrak {b}$
is
$B^{\times }$
-conjugate to the standard hereditary order in
$B=\operatorname {End}_{E}(V_{E})$
with respect to the composition
$(\operatorname {dim}_{E}(V_{E}^{1}),\dots ,\operatorname {dim}_{E}(V_{E}^{t}))$
of
$\operatorname {dim}_{E}(V_{E})$
. Also, for each i, we necessarily have (cf. [Reference Bushnell and Kutzko19, Proposition 7.1.12, Theorem 7.1.14])
$$ \begin{align*}H^{1}(\beta,\Lambda^i)=H^{1}(\beta,\mathfrak{a}^i),\ J^{1}(\beta,\Lambda^i)=J^{1}(\beta,\mathfrak{a}^i),\ J(\beta,\Lambda^i)=J(\beta,\mathfrak{a}^i)\quad \text{and}\quad \mathcal{C}(\Lambda^i,\beta)=\mathcal{C}(\mathfrak{a}^i,\beta),\end{align*} $$
and
$$ \begin{align*}J_{M}(\beta,\mathfrak{a}):=J(\beta,\mathfrak{a})\cap M=J(\beta,\mathfrak{a}^{1})\times\dots\times J(\beta,\mathfrak{a}^{t})\end{align*} $$
as a subgroup of M, and
$$ \begin{align} J_{P}(\beta,\mathfrak{a}):=H^{1}(\beta,\mathfrak{a})(J(\beta,\mathfrak{a})\cap P)=(H^{1}(\beta,\mathfrak{a})\cap N^{-})\cdot(J(\beta,\mathfrak{a})\cap M)\cdot(J^{1}(\beta,\mathfrak{a})\cap N) \end{align} $$
as a subgroup of
$J(\beta ,\mathfrak {a})$
.
Let
$\kappa _{P}$
be the representation of
$J_{P}(\beta ,\mathfrak {a})$
defined on the space of
$J^{1}(\beta ,\mathfrak {a})\cap N^{-}$
-fixed vectors in
$\eta $
. Then
-
•
$(J_{P}(\beta ,\mathfrak {a}),\kappa _{P})$
is decomposed with respect to
$(M,P')$
for any parabolic subgroup
$P'$
of G with a Levi factor M. -
•
$\kappa _{P}\lvert _{J_{M}(\beta ,\mathfrak {a})}=\kappa _{M}:=\kappa _{1}\boxtimes \dots \boxtimes \kappa _{t}$
, where
$\kappa _{i}$
is a
$\beta $
-extension of
$\eta _{i}$
for each i. In particular,
$\kappa _{M}$
does not depend on the choice of P. -
•
$\operatorname {ind}_{J_{P}(\beta ,\mathfrak {a})}^{J(\beta ,\mathfrak {a})}\kappa _{P}=\kappa $
.
In the case
$\operatorname {dim}_{F}(V^{1})=\dots =\operatorname {dim}_{F}(V^{t})$
, we necessarily have
$\theta _{1}=\dots =\theta _{t}$
,
$\eta _{1}\cong \dots \cong \eta _{t}$
and
$\kappa _{1}\cong \dots \cong \kappa _{t}$
.
Finally, we notice that when considering a null stratum
$[\mathfrak {a},0,0,\beta ]$
, our simple character
$\theta $
and Heisenberg representation
$\eta $
are identity characters, and the corresponding
$\beta $
-extensions we are considering are characters of
$U(\mathfrak {a})/U^{1}(\mathfrak {a})$
. We choose the identity character to be our initial
$\beta $
-extension
$\kappa $
. We say that we are in the ‘level 0’ case once we consider a null stratum as so.
6 Simple types
In this section, we introduce simple types. These are types related to certain inertial equivalence classes of
$\widetilde {G}=\widetilde {\operatorname {GL}_{r}(F)}$
in the sense of §3.3 – in particular, those inertial equivalence classes containing a discrete series representation for KP-covers and the S-cover.
6.1 Homogeneous types
Let
$[\mathfrak {a},u,0,\beta ]$
be a strict simple stratum in
$A=\operatorname {End}_{F}(V)$
, with V being an r-dimensional vector space over F and
$\Lambda $
being the corresponding lattice chain of
$\mathfrak {a}$
. As before, let
$E=F[\beta ]$
,
$B=\operatorname {End}_{E}(V_{E})$
and
$\mathfrak {b}=\mathfrak {a}\cap A$
. Let
$d=[E:F]$
and
$m=r/d$
. Let
$d=ef$
, where e denotes the ramification index and f denotes the unramified degree of
$E/F$
. Let
$\boldsymbol {l}$
be the residue field of E.
Consider a containment of E-pure hereditary orders
$\mathfrak {a}_{\text {min}}\subset \mathfrak {a}\subset \mathfrak {a}_{\text {max}}$
, such that
$\mathfrak {b}_{\text {min}}=B\cap \mathfrak {a}_{\text {min}}$
is a minimal hereditary order, and
$\mathfrak {b}_{\text {max}}=B\cap \mathfrak {a}_{\text {max}}$
is a maximal hereditary order in B. Let
$u_{\mathrm {min}}=-v_{\mathfrak {a}_{\text {min}}}(\beta )$
and
$u_{\mathrm {max}}=-v_{\mathfrak {a}_{\text {max}}}(\beta )$
. Then
$[\mathfrak {a}_{\text {min}},u_{\mathrm {min}},0,\beta ]$
and
$[\mathfrak {a}_{\text {max}},u_{\mathrm {max}},0,\beta ]$
are also simple strata in A. Let
$\Lambda _{\text {min}}$
and
$\Lambda _{\text {max}}$
be the corresponding lattice chains with respect to
$\mathfrak {a}_{\text {min}}$
and
$\mathfrak {a}_{\text {max}}$
, respectively.
Consider an E-decomposition
$V=\bigoplus _{i=1}^{t}V^{i}$
that conforms with
$\Lambda $
,
$\Lambda _{\text {max}}$
,
$\Lambda _{\text {min}}$
and in particular is properly subordinate to
$\Lambda $
. Let
$P=MN$
be a corresponding parabolic subgroup of V with a Levi factor M being
$\prod _{i=1}^{t}\operatorname {Aut}_{F}(V^{i})$
. We write
$r_{i}=\operatorname {dim}_{F}(V^{i})$
and
$m_{i}=\operatorname {dim}_{E}(V^{i}_{E})=\operatorname {dim}_{F}(V^{i})/d$
for each i. Then
$m_{1}+\dots +m_{t}=m$
and
$r_{1}+\dots +r_{t}=r$
.
For
$i=1,\dots ,t$
, let
$A^{i}=\operatorname {End}_{F}(V^{i})$
(resp.
$B^{i}=\operatorname {End}_{E}(V_{E}^{i})$
) which is identified with a subalgebra of A (resp. B) via the i-th block diagonal embedding. Let
$\mathfrak {a}^{i}=A^{i}\cap \mathfrak {a}$
and
$\mathfrak {b}^{i}=B^{i}\cap \mathfrak {b}$
. Let
$\mathcal {G}^{i}=\operatorname {GL}_{m_{i}}(\boldsymbol {l})\cong U(\mathfrak {b}^{i})/U^{1}(\mathfrak {b}^{i})$
.
Consider
$$ \begin{align*}H^{1}=H^{1}(\beta,\mathfrak{a})\subset J^{1}=J^{1}(\beta,\mathfrak{a})\subset J=J(\beta,\mathfrak{a})\end{align*} $$
as subgroups of
$U(\mathfrak {a})$
,
$$ \begin{align*}H_{\text{min}}^{1}=H^{1}(\beta,\mathfrak{a}_{\text{min}})\subset J_{\text{min}}^{1}=J^{1}(\beta,\mathfrak{a}_{\text{min}})\subset J_{\text{min}}=J(\beta,\mathfrak{a}_{\text{min}})\end{align*} $$
as subgroups of
$U(\mathfrak {a}_{\text {min}})$
, and
$$ \begin{align*}H_{\text{max}}^{1}=H^{1}(\beta,\mathfrak{a}_{\text{max}})\subset J_{\text{max}}^{1}=J^{1}(\beta,\mathfrak{a}_{\text{max}})\subset J_{\text{max}}=J(\beta,\mathfrak{a}_{\text{max}})\end{align*} $$
as subgroups of
$U(\mathfrak {a}_{\text {max}})$
. Then,
$$ \begin{align*}\mathcal{G}=\operatorname{GL}_{m}(\boldsymbol{l})\cong U(\mathfrak{b}_{\text{max}})/U^{1}(\mathfrak{b}_{\text{max}})\cong J_{\text{max}}/J_{\text{max}}^{1}.\end{align*} $$
Moreover,
$\mathcal {P}\cong U(\mathfrak {b})/U^{1}(\mathfrak {b}_{\text {max}})$
is a parabolic subgroup of
$\mathcal {G}$
having a Levi factor is
$$ \begin{align*}\mathcal{M}=\mathcal{G}^{1}\times\dots\times\mathcal{G}^{t}\cong U(\mathfrak{b})/U^{1}(\mathfrak{b})\cong J/J^{1}.\end{align*} $$
Moreover,
$$ \begin{align*}\widetilde{\mathcal{G}}=\widetilde{U(\mathfrak{b}_{\text{max}})}/\,_{s}U^{1}(\mathfrak{b}_{\text{max}})=\widetilde{J_{\text{max}}}/\,_{s}J_{\text{max}}^{1}\end{align*} $$
is an n-fold central extension of
$\mathcal {G}$
. We define
$\widetilde {\mathcal {P}}$
and
$$ \begin{align*}\widetilde{\mathcal{M}}=\widetilde{U(\mathfrak{b})}/\,_{s}U^{1}(\mathfrak{b})\cong\widetilde{J}/\,_{s}J^{1}\end{align*} $$
as the preimage in
$\widetilde {\mathcal {G}}$
of
$\mathcal {P}$
and
$\mathcal {M}$
, respectively.
Choose a maximal open compact subgroup K of G that contains
$U(\mathfrak {a})$
. Fix a splitting
$\boldsymbol {s}:K\rightarrow \widetilde {G}$
of K. Then the restriction of
$\boldsymbol {s}$
to
$U(\mathfrak {a})$
is also a splitting. In general, we may also assume that K contains
$U(\mathfrak {a}_{\max })$
. Then such
$\boldsymbol {s}$
also induces splittings of
$U(\mathfrak {a}_{\text {min}})$
and
$U(\mathfrak {a}_{\text {max}})$
. Such an
$\boldsymbol {s}$
also induces a splitting of
$\widetilde {\mathcal {G}}$
. Then, we have an identification
$\widetilde {\mathcal {G}}=\mu _{n}\times \,_{s}\mathcal {G}$
depending on the choice of K and
$\boldsymbol {s}$
.
Let
$\theta \in \mathcal {C}(\mathfrak {a},\beta )$
, let
$\eta $
be the Heisenberg representation of
$\theta $
, and let
$\kappa $
be a
$\beta $
-extension of
$\eta $
. Let
$\widetilde {\kappa }$
be the pull-back of
$\kappa $
as a (non-genuine) representation of
$\widetilde {J}$
.
Let
$\varrho =\varrho _{1}\boxtimes \dots \boxtimes \varrho _{t}$
be a cuspidal representation of
$\mathcal {M}$
that also extends trivially to a representation of
$\mathcal {P}$
, where each
$\varrho _{i}$
is a cuspidal representation of
$\mathcal {G}^{i}$
. Let
$\,_{s}\varrho $
be the corresponding representation of
$\,_{s}\mathcal {M}$
, and let
$\epsilon \cdot \,_{s}\varrho $
be the extension of
$\,_{s}\varrho $
to
$\widetilde {\mathcal {M}}=\mu _{n}\times \,_{s}\mathcal {M}$
with
$\mu _{n}$
acting by
$\epsilon $
. Then
$\widetilde {\rho }:=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s}\varrho )$
is a genuine irreducible representation of
$\widetilde {J}$
.
Let
$\widetilde {\lambda }=\widetilde {\kappa }\otimes \widetilde {\rho }$
, which is a genuine irreducible representation of
$\widetilde {J}$
.
Definition 6.1. A homogeneous type
Footnote
4
of
$\widetilde {G}$
is the pair
$(\widetilde {J},\widetilde {\lambda })$
defined as above.
We verify that this definition is independent of the choice of K and the splitting
$\boldsymbol {s}$
. Indeed, let
$\boldsymbol {s}'$
be a splitting of another maximal compact subgroup
$K'$
of G that contains
$U(\mathfrak {a})$
. Let
$(\widetilde {J},\widetilde {\lambda }')$
be the pair constructed as above, but with the splitting
$\boldsymbol {s}'$
replaced by
$\boldsymbol {s}$
. More precisely, we have
$\widetilde {\lambda }=\widetilde {\kappa }\otimes \widetilde {\rho }'$
with
$\widetilde {\rho }'=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s'}\varrho )$
. We notice that
$$ \begin{align*}\chi_{\boldsymbol{s}|\boldsymbol{s}'}:x\mapsto\boldsymbol{s}'(x)/\boldsymbol{s}(x)\end{align*} $$
defines a character of
$\mathcal {M}\cong J/J^{1}$
. Moreover, by definition, we have
$$ \begin{align*}\widetilde{\rho}'=\operatorname{Inf}_{\widetilde{\mathcal{M}}}^{\widetilde{J}}(\epsilon\cdot\,_{s}(\varrho\cdot\chi_{\boldsymbol{s}|\boldsymbol{s}'}))\quad \text{and}\quad \widetilde{\lambda}'\cong\widetilde{\lambda}\cdot\chi_{\boldsymbol{s}|\boldsymbol{s}'}.\end{align*} $$
It means that
$(\widetilde {J},\widetilde {\lambda }')$
is also a homogeneous type with respect to the pair
$(K,\boldsymbol {s})$
. From now on, in considering a homogeneous type, we may fix any K and
$\boldsymbol {s}$
as above.
Finally, we construct two pairs of representations related to
$(\widetilde {J},\widetilde {\lambda })$
. Let
$$ \begin{align*}J_{M}=J\cap M,\ J_{M}^{1}=J^{1}\cap M,\ J_{P}^{1}=(H^{1}\cap N^{-})(J^{1}\cap P),\ J_{P}=(H^{1}\cap N^{-})(J\cap P)\end{align*} $$
and let
$\kappa _{P}$
,
$\kappa _{M}$
be defined as in §5.4. Let
$\widetilde {\kappa }_{P}$
(resp.
$\widetilde {\kappa }_{M}$
) be the pull-back of
$\kappa _{P}$
(resp.
$\kappa _{M}$
) to
$\widetilde {J_{P}}$
(resp.
$\widetilde {J_{M}}$
) as a non-genuine irreducible representation. Since
$$ \begin{align*}J_{P}/J_{P}^{1}\cong J_{M}/J_{M}^{1}\cong\mathcal{M},\end{align*} $$
we may realize
$\widetilde {\rho }$
as genuine irreducible representations of
$\widetilde {J_{P}}$
and
$\widetilde {J_{M}}$
by taking the restriction, denoted by
$\widetilde {\rho }_{P}$
and
$\widetilde {\rho }_{M}$
, respectively. In other words, we have
$\widetilde {\rho }_{P}=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J_{P}}}(\epsilon \cdot \,_{s}\varrho )$
and
$\widetilde {\rho }_{M}=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J_{M}}}(\epsilon \cdot \,_{s}\varrho )$
. Let
$\widetilde {\lambda }_{P}=\widetilde {\kappa }_{P}\otimes \widetilde {\rho }_{P}$
(resp.
$\widetilde {\lambda }_{M}=\widetilde {\kappa }_{M}\otimes \widetilde {\rho }_{M}$
), which is a genuine irreducible representation of
$\widetilde {J_{P}}$
(resp.
$\widetilde {J_{M}}$
).
Using the statements in §5.4, it is direct to verify that
-
•
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
is decomposed with respect to
$(M,P')$
for every parabolic subgroup
$P'$
of G with a Levi factor M. -
•
$\widetilde {J_{P}}\cap \widetilde {M}=\widetilde {J_{M}}$
and
$\widetilde {\lambda }_{P}\lvert _{\widetilde {J_{M}}}=\widetilde {\lambda }_{M}$
. -
•
$\operatorname {ind}_{\widetilde {J_{P}}}^{\widetilde {J}}\widetilde {\lambda }_{P}\cong \widetilde {\lambda }$
.
As a result, the following lemma is valid (cf. [Reference Bushnell and Kutzko19, Proposition 4.1.3]).
Lemma 6.2. We have a canonical isomorphism of Hecke algebras:
$$ \begin{align*}\mathcal{H}(\widetilde{G},\widetilde{\lambda}_{P})\cong\mathcal{H}(\widetilde{G},\widetilde{\lambda}).\end{align*} $$
It preserves the support, in the sense that, for
$\phi _P\in \mathcal {H}(\widetilde {G},\widetilde {\lambda }_{P})$
supported on
$\widetilde {J_P}g\widetilde {J_P}$
, the related function
$\phi \in \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
is supported on
$\widetilde {J}g\widetilde {J}$
.
We may further explain
$\widetilde {\lambda }_{M}$
. As before,
$\Lambda ^{i}=\Lambda \cap V^{i}$
is a lattice sequence of
$V^{i}$
, and
$[\Lambda ^{i},u,0,\beta ]$
is a simple stratum in
$A^{i}$
for each
$i=1,\dots ,t$
, and we consider the related strict simple stratum
$[\mathfrak {a}^{i},u_{i},0,\beta ]$
in
$A^{i}$
. Let
$\kappa _{i}$
be defined as in §5.4, let
$\widetilde {\kappa }_{i}$
be its pull-back as a non-genuine representation of
$\widetilde {J(\beta ,\mathfrak {a}^{i})}$
, and let
$\widetilde {\rho }_{i}=\operatorname {Inf}^{\widetilde {J(\beta ,\mathfrak {a}^{i})}}_{\widetilde {\mathcal {G}_{i}}}(\epsilon \cdot \,_{s}\varrho _{i})$
. Let
$\widetilde {\lambda }_{i}=\widetilde {\kappa }_{i}\otimes \widetilde {\rho }_{i}$
be a genuine irreducible representation of
$\widetilde {J(\beta ,\mathfrak {a}^{i})}$
. Then by definition, we have
$$ \begin{align*}\widetilde{\lambda}_{M}\cong\widetilde{\lambda}_{1}\boxtimes\dots\boxtimes\widetilde{\lambda}_{t}\end{align*} $$
as a representation of
$$ \begin{align*}\widetilde{J_{M}}=\boldsymbol{p}^{-1}(J(\beta,\mathfrak{a}^{1})\times\dots\times J(\beta,\mathfrak{a}^{t})).\end{align*} $$
Here, the related tensor product makes sense since
$J_{M}$
is block compatible. Indeed, each pair
$(\widetilde {J(\beta ,\mathfrak {a}^{i})},\widetilde {\lambda }_{i})$
is a so-called maximal simple type of
$\widetilde {(A^{i})^{\times }}$
, a concept to be introduced later (cf. Definition 6.10). By (5.4), for
$i=1,\dots ,t$
, the simple characters
$\theta _{i}$
contained in
$\kappa _{i}$
are transfers of each other. Thus, they lie in the same endo-class.
6.2 Intertwining set of a homogeneous type
Our next goal is to study the intertwining set of
$\widetilde {\lambda }$
.
Proposition 6.3. We have
$I_{G}(\widetilde {\lambda })=JI_{B^{\times }}(\widetilde {\rho })J.$
Proof. Since
$I_{G}(\widetilde {\kappa })=JB^{\times }J$
and
$\operatorname {dim}_{\mathbb {C}}\operatorname {Hom}_{\widetilde {J}^{g}\cap \widetilde {J}}(\widetilde {\kappa }^{g},\widetilde {\kappa })=1$
for
$g\in I_G(\widetilde {\kappa })$
, the result follows from the same argument of [Reference Bushnell and Kutzko19, Proposition 5.3.2].
Then we need to study
$I_{B^{\times }}(\widetilde {\rho })$
. We introduce more notation.
Fix a certain E-basis of
$V_{E}$
to identify B with
$\operatorname {M}_{m}(E)$
, such that
$\mathfrak {b}_{\text {max}}$
is identified with
$\operatorname {M}_{m}(\mathfrak {o}_{E})$
, and
$\mathfrak {b}$
is identified with the standard hereditary order in B with respect to the composition
$m_{1}+\dots +m_{t}=m$
, and
$\mathfrak {b}_{\text {min}}$
is identified with the standard minimal hereditary order in B.
Under this basis, let
$$ \begin{align*}T(B)=\{\operatorname{diag}(\varpi_{E}^{s_{1}},\dots,\varpi_{E}^{s_{m}})\in B^{\times}\mid s_{i}\in \mathbb{Z},\ i=1,\dots,m\}\end{align*} $$
and
$$ \begin{align*}T(\mathfrak{b})=\{\operatorname{diag}(\varpi_{E}^{s_{1}}I_{m_{1}},\dots,\varpi_{E}^{s_{t}}I_{m_{t}})\in B^{\times}\mid s_{i}\in \mathbb{Z},\ i=1,\dots,t\},\end{align*} $$
where we fix a uniformizer
$\varpi _{E}$
of E. Let
$M^{0}(\mathfrak {b})=M\cap U(\mathfrak {b})$
and
$M^{1}(\mathfrak {b})=M\cap U^{1}(\mathfrak {b})$
. Then
$\mathcal {M}\cong M^{0}(\mathfrak {b})/M^{1}(\mathfrak {b})$
. Also,
$T(\mathfrak {b})$
commutes with both
$M^{0}(\mathfrak {b})$
and
$M^{1}(\mathfrak {b})$
.
The restriction of
$\widetilde {\rho }$
to
$\widetilde {M^{0}(\mathfrak {b})}$
is the inflation
$\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {M^{0}(\mathfrak {b})}}(\epsilon \cdot \,_{s}\varrho )$
.
Let
$W_{0}(B)$
be the subgroup of permutation matrices in
$B^{\times }\cong \operatorname {GL}_{m}(E)$
which is embedded in
$\mathfrak {b}_{\text {max}}^{\times }$
, and let
$W_{0}(\mathfrak {b})$
be the stabilizer of
$T(\mathfrak {b})$
in
$W_{0}(B)$
. Let
$W(B)=W_{0}(B)\ltimes T(B)$
be the semi-direct product as a subgroup of
$B^{\times }$
. Let
$W(\mathfrak {b})=W_{0}(\mathfrak {b})\ltimes T(\mathfrak {b})$
, which is a subgroup of
$W(B)$
. By direct verification, the normalizer of
$M^{0}(\mathfrak {b})$
in
$W(B)$
is
$W(\mathfrak {b})$
.
We have the Bruhat decomposition
$$ \begin{align*}B^{\times}=U(\mathfrak{b}_{\text{min}})W(B)U(\mathfrak{b}_{\text{min}}).\end{align*} $$
Since
$U(\mathfrak {b}_{\text {min}})\subset U(\mathfrak {b})$
normalizes
$\widetilde {\rho }$
, to study
$I_{B^{\times }}(\widetilde {\rho })$
, we only need to calculate
$I_{W(B)}(\widetilde {\rho })$
.
Proposition 6.4. An element
$w\in W(B)$
intertwines
$\widetilde {\rho }$
if and only if it normalizes
$M^{0}(\mathfrak {b})$
and
$\widetilde {\rho }\lvert _{\widetilde {M^{0}(\mathfrak {b})}}$
. Moreover, for
$g\in I_{B^{\times }}(\widetilde {\rho })$
, we have
$$ \begin{align*}\operatorname{dim}_{\mathbb{C}}\operatorname{Hom}_{\widetilde{J}^{g}\cap \widetilde{J}}(\widetilde{\rho}^{g},\widetilde{\rho})=1.\end{align*} $$
Proof. For
$w\in I_{W(B)}(\widetilde {\rho })$
, we necessarily have that
$$ \begin{align} \operatorname{Hom}_{\widetilde{M^{0}(\mathfrak{b})}\cap\widetilde{M^{0}(\mathfrak{b})^{w}}}(\widetilde{\rho},\widetilde{\rho}^{w})\neq 0. \end{align} $$
The argument of the ‘only if’ part follows from the proof of [Reference Bushnell and Kutzko19, Proposition 5.5.5], which we explain as follows. If w does not normalize
$M^{0}(\mathfrak {b})$
, then as in loc. cit. there exist a certain
$i=1,\dots ,t$
, a standard hereditary order
$\mathfrak {b}'$
in
$B^{i}=\operatorname {End}_{E}(V_{E}^{i})$
with respect to the decomposition
$V_{E}=\bigoplus _{i=1}^{t}V_{E}^{i}$
, such that
$$ \begin{align*}U^{1}(\mathfrak{b}^{i})\subsetneq U^{1}(\mathfrak{b}')\subset U(\mathfrak{b}^{i})\quad \text{and}\quad U^{1}(\mathfrak{b}')\subset M^{1}(\mathfrak{b})^{w}.\end{align*} $$
We consider
$\mathcal {N}'= U^{1}(\mathfrak {b}')/U^{1}(\mathfrak {b}^{i})\cong \,_{s}U^{1}(\mathfrak {b}')/\,_{s}U^{1}(\mathfrak {b}^{i})$
, which is a proper unipotent subgroup of
$\mathcal {G}^{i}$
. Then, restricting (6.1) to
$\,_{s}U^{1}(\mathfrak {b}')$
and modulo
$\,_{s}U^{1}(\mathfrak {b}^{i})$
, we have
$$ \begin{align*}\operatorname{Hom}_{\mathcal{N}'}(\varrho_{i},1)\neq 0,\end{align*} $$
contradicting the fact that
$\varrho _{i}$
is cuspidal. So w normalizes
$M^{0}(\mathfrak {b})$
.
On the other hand, assume
$w\in W(B)$
normalizes
$M^{0}(\mathfrak {b})$
and
$\widetilde {\rho }\lvert _{\widetilde {M^{0}(\mathfrak {b})}}$
. We claim that
$$ \begin{align} \operatorname{Hom}_{\widetilde{J}\cap\widetilde{J}^{w}}(\widetilde{\rho},\widetilde{\rho}^{w}) =\operatorname{Hom}_{\widetilde{M^{0}(\mathfrak{b})}}(\widetilde{\rho},\widetilde{\rho}^{w})=\mathbb{C}. \end{align} $$
It suffices to show the first equality. Remark that we have decompositions
$$ \begin{align*}J=M^{0}(\mathfrak{b})J^1\quad\text{and}\quad J^w=M^{0}(\mathfrak{b})^wJ^{1w}=M^{0}(\mathfrak{b})J^{1w},\end{align*} $$
and thus, we have
$$ \begin{align*}J\cap J^w=M^{0}(\mathfrak{b})(J^{1}\cap M^{0}(\mathfrak{b})J^{1w}).\end{align*} $$
We claim that
$$ \begin{align*}J^{1}\cap M^{0}(\mathfrak{b})J^{1w}=J^{1}\cap J^{1w},\end{align*} $$
which suffices to show the first equality of (6.2) since both
$\widetilde {\rho }$
and
$\widetilde {\rho }^w$
are trivial on
$\widetilde {J^1}\cap \widetilde {J^{1w}}$
. Assume that there exist
$m_0\in M^{0}(\mathfrak {b})$
,
$g_1\in J^{1}\subset U^1(\mathfrak {a})$
,
$g_2\in J^{1w}\subset U^{1}(\mathfrak {a})^w$
, such that
$m_0=g_1g_2$
. It suffices to show that
$m_0\in M^{1}(\mathfrak {b})$
, or a fortiori, it suffices to show that
$$ \begin{align*}M^0(\mathfrak{b})\cap U^{1}(\mathfrak{a})w^{-1}U^{1}(\mathfrak{a})w=M^1(\mathfrak{b}).\end{align*} $$
Using [Reference Bushnell and Kutzko19, Theorem 1.6.1], we have
$$ \begin{align*}M^0(\mathfrak{b})\cap U^{1}(\mathfrak{a})w^{-1}U^{1}(\mathfrak{a})w=M^0(\mathfrak{b})\cap U^{1}(\mathfrak{b})w^{-1}U^{1}(\mathfrak{b})w.\end{align*} $$
Thus, we only need to show thatFootnote 5
$$ \begin{align*}U^{0}(\mathfrak{b})^{w}\cap U^{1}(\mathfrak{b})=M^0(\mathfrak{b})U^{1}(\mathfrak{b})^w\cap U^{1}(\mathfrak{b})\subset U^{1}(\mathfrak{b})^w.\end{align*} $$
To show the last claim, suppose we have
$g\in U^{0}(\mathfrak {b})$
such that
$g^{w}\in U^{0}(\mathfrak {b})^{w}\cap U^{1}(\mathfrak {b})$
. Consider the Iwahori decomposition
$$ \begin{align*}g=n_1mn_2\quad \text{in}\quad U^{0}(\mathfrak{b})=(U^{0}(\mathfrak{b})\cap N^{-})(U^{0}(\mathfrak{b})\cap M)(U^{0}(\mathfrak{b})\cap N);\end{align*} $$
thus,
$$ \begin{align*}g^{w}=n_1^{w}m^{w}n_2^{w}\quad \text{in}\quad U^{0}(\mathfrak{b})=(U^{0}(\mathfrak{b})\cap N^{-w})(U^{0}(\mathfrak{b})\cap M)(U^{0}(\mathfrak{b})\cap N^{w})\end{align*} $$
is the related Iwahori decomposition of
$g^{w}$
. Since
$g^{w}\in U^{1}(\mathfrak {b})$
, both
$m^{w}$
and m are in
$U^{1}(\mathfrak {b})\cap M$
. Thus,
$g\in U^{1}(\mathfrak {b})$
and
$g^{w}\in U^{1}(\mathfrak {b})^{w}$
.
Finally, the second statement of the proposition follows from (6.2).
As a direct corollary of Proposition 6.3 and Proposition 6.4, we have the following.
Corollary 6.5. We have
$$ \begin{align*}\operatorname{dim}_{\mathbb{C}}\operatorname{Hom}_{\widetilde{J}^{g}\cap \widetilde{J}}(\widetilde{\lambda}^{g},\widetilde{\lambda})=1\end{align*} $$
for any
$g\in I_{G}(\widetilde {\lambda })$
. Thus, there exists a unique
$\phi \in \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
up to a scalar that is supported on
$\widetilde {J}g\widetilde {J}$
.
We first study
$I_{W_{0}(B)}(\widetilde {\rho })$
. We may regard
$W_{0}(B)$
as a subgroup of
$\mathcal {G}$
modulo
$U^{1}(\mathfrak {b}_{\text {max}})$
.
Proposition 6.6. We have that
$w\in I_{W_{0}(B)}(\widetilde {\rho })$
if and only if w normalizes
$\varrho =\varrho _{1}\boxtimes \dots \boxtimes \varrho _{t}$
. In particular,
$I_{W_{0}(B)}(\widetilde {\rho })$
is contained in
$W_{0}(\mathfrak {b})$
.
Proof. If w normalizes
$\varrho $
, then it also normalizes
$\widetilde {\rho }\lvert _{\widetilde {M^{0}(\mathfrak {b})}}$
. It is because both
$M^{0}(\mathfrak {b})$
and w are in K; thus, we may simply take the splitting
$\boldsymbol {s}$
of K. Thus, by Proposition 6.4, w intertwines
$\widetilde {\rho }$
.
Conversely, if
$w\in W_{0}(B)$
intertwines
$\widetilde {\rho }$
, by Proposition 6.4, we have that w normalizes
$M^{0}(\mathfrak {b})$
and is in
$W_{0}(\mathfrak {b})$
. So
$$ \begin{align*}0\neq\operatorname{Hom}_{\widetilde{J}^{w}\cap\widetilde{J}}(\widetilde{\rho}^{w},\widetilde{\rho})\cong\operatorname{Hom}_{\widetilde{M^{0}(\mathfrak{b})}}(\widetilde{\rho}^{w},\widetilde{\rho})\cong \operatorname{Hom}_{\widetilde{\mathcal{M}}}((\epsilon\cdot\varrho)^{w},\epsilon\cdot\varrho)\cong\operatorname{Hom}_{\mathcal{M}}(\varrho^{w},\varrho).\end{align*} $$
Thus, w normalizes
$\varrho $
.
We also study
$I_{T(B)}(\widetilde {\rho })$
. The normalizer of
$M^{0}(\mathfrak {b})$
in
$T(B)$
is
$T(\mathfrak {b})$
, so we only need to investigate the intertwining set
$I_{T(\mathfrak {b})}(\widetilde {\rho })$
.
Before that, we need to say something for
$\varrho =\varrho _{1}\boxtimes \dots \boxtimes \varrho _{t}$
.
Let
$l_{i}$
be the maximal positive integer dividing n, such that
$\varrho _{i}$
is isomorphic to its twist by a character of
$\mathcal {G}^{i}$
of order
$l_{i}$
.
We may further use the theory of Green [Reference Green36] or the Deligne-Lusztig theory [Reference Deligne and Lusztig26] to describe
$l_{i}$
. For each i, let
$\boldsymbol {l}_{m_{i}}$
be the finite extension of degree
$m_{i}$
over
$\boldsymbol {l}$
, and let
$\xi _{i}$
be a regular character of
$\boldsymbol {l}_{m_{i}}^{\times }$
that constructs
$\varrho _{i}$
in the sense of the above two theories. Here, by regular we mean that the orbit of
$\xi _{i}$
under the action of the Galois group
$\mathrm {Gal}(\boldsymbol {l}_{m_{i}}/\boldsymbol {l})$
is of cardinality
$m_i$
.
Fix a Frobenius element in
$\mathrm {Gal}(\boldsymbol {l}_{m_{i}}/\boldsymbol {l})$
as the
$q_{\boldsymbol {l}}$
’s power map, where
$q_{\boldsymbol {l}}$
denotes the cardinality of
$\boldsymbol {l}$
. Then there exists a smallest positive integer
$o_{i}$
, such that
$\xi _{i}^{q_{\boldsymbol {l}}^{o_{i}}}/\xi _{i}$
is a character of
$\boldsymbol {l}_{m_{i}}^{\times }$
of order dividing n. An easy exercise implies that
$o_{i}l_{i}=m_{i}$
, and in particular,
$l_{i}$
divides
$m_{i}$
.
Proposition 6.7. Consider the following linear congruence equations:
$$ \begin{align} l_{i}[(s_{1}r_{1}+\dots+s_{t}r_{t})(2\boldsymbol{c}+\boldsymbol{d})-s_{i}\boldsymbol{d}]\equiv 0\quad(\mathrm{mod}\ n),\quad i=1,\dots t. \end{align} $$
Then the intertwining set
$I_{T(\mathfrak {b})}(\widetilde {\rho })=I_{T(\mathfrak {b})}(\widetilde {\rho }\lvert _{\widetilde {M^{0}(\mathfrak {b})}})$
equals
$$ \begin{align} T(\varrho):=\{\operatorname{diag}(\varpi_{E}^{s_{1}}I_{m_{1}},\dots,\varpi_{E}^{s_{t}}I_{m_{t}})\mid s_{1},\dots,s_{t}\in \mathbb{Z}\ \text{satisfy}\ (6.3)\}. \end{align} $$
Proof. Let
$h=\operatorname {diag}(\varpi _{E}^{s_{1}}I_{m_{1}},\dots ,\varpi _{E}^{s_{t}}I_{m_{t}})$
that intertwines
$\widetilde {\rho }$
. By definition, h commutes with
$M^{0}(\mathfrak {b})$
. So we have that
$\widetilde {\rho }^{h}=\widetilde {\rho }\cdot \chi _{h}$
, where
$\chi _{h}:=\epsilon ([h,\cdot ]_{\sim })$
is a character of
$M^{0}(\mathfrak {b})$
of order dividing n. For
$g=\operatorname {diag}(g_{1},\dots ,g_{t})\in M^{0}(\mathfrak {b})$
, using (4.11), we have
$$ \begin{align} \begin{aligned} [h,g]_{\sim}&=[\operatorname{diag}(\varpi_{E}^{s_{1}}I_{m_{1}},\dots,\varpi_{E}^{s_{t}}I_{m_{t}}),\operatorname{diag}(g_{1},\dots,g_{t})]_{\sim}\\ &=\prod_{i=1}^{t}(\operatorname{det}_{F}(h)^{2\boldsymbol{c}+\boldsymbol{d}}\varpi_{E}^{-s_{i}\boldsymbol{d}},\operatorname{det}_{E}(g_{i}))_{n,E}\\ &=\prod_{i=1}^{t}(\varpi_{E}^{(s_{1}r_{1}+\dots+s_{t}r_{t})(2\boldsymbol{c}+\boldsymbol{d})-s_{i}\boldsymbol{d}},\operatorname{det}_{E}(g_{i}))_{n,E}. \end{aligned} \end{align} $$
Let
$\chi _{\varpi _{E}}=\epsilon ((\varpi _{E},\cdot )_{n,E})$
be a character of
$\mathfrak {o}_{E}^{\times }$
of order n. Then we have
$$ \begin{align} \chi_{h}(g)=\prod_{i=1}^{t}\chi_{\varpi_{E}}(\operatorname{det}_{E}(g_{i}))^{(s_{1}r_{1}+\dots+s_{t}r_{t})(2\boldsymbol{c}+\boldsymbol{d})-s_{i}\boldsymbol{d}}. \end{align} $$
Noting that
$(1+\mathfrak {p}_{E})^{n}=1+\mathfrak {p}_{E}$
when
$\operatorname {gcd}(q,n)=1$
, so
$\chi _{\varpi _{E}}$
is trivial on
$1+\mathfrak {p}_{E}$
. Thus, it can be regarded as a character of
$\boldsymbol {l}^{\times }\cong \mathfrak {o}_{E}^{\times }/1+\mathfrak {p}_{E}$
. Similarly,
$\chi _{h}$
can be regarded as a character of
$\mathcal {M}\cong M^{0}(\mathfrak {b})/M^{1}(\mathfrak {b})$
.
Then h intertwines
$\widetilde {\rho }$
if and only if
$\widetilde {\rho }\lvert _{\widetilde {M^{0}}(\mathfrak {b})}\cdot \chi _{h}\cong \widetilde {\rho }\lvert _{\widetilde {M^{0}}(\mathfrak {b})}$
, if and only if
$\varrho \cdot \chi _{h}\cong \varrho $
, if and only if
$$ \begin{align*}\varrho_{i}\cdot(\chi_{\varpi_{E}}\circ\operatorname{det}_{\boldsymbol{l}})^{(s_{1}r_{1}+\dots+s_{t}r_{t})(2\boldsymbol{c}+\boldsymbol{d})-s_{i}\boldsymbol{d}}\cong\varrho_{i},\quad i=1,\dots,t.\end{align*} $$
Since
$\chi _{\varpi _{E}}\circ \operatorname {det}_{\boldsymbol {l}}$
is a character of order n, the above relation is equivalent to the following linear congruence equations:
$$ \begin{align*}(s_{1}r_{1}+\dots+s_{t}r_{t})(2\boldsymbol{c}+\boldsymbol{d})-s_{i}\boldsymbol{d}\equiv 0\quad(\mathrm{mod}\ n/l_{i}),\quad i=1,\dots ,t.\end{align*} $$
So the result follows.
In general, the solution of (6.3) could be quite messy. But in the following two cases, it is rather neat.
Corollary 6.8. The solution of equations (6.3) is
-
• if
$\widetilde {G}$
is a KP-cover, then where
$$ \begin{align*}s_{i}=k_{i}n/l_{i}+k(2\boldsymbol{c}+1)n/\operatorname{gcd}(n,2r\boldsymbol{c}+r-1),\quad i=1,\dots,t,\end{align*} $$
$k\in \mathbb {Z}$
and
$k_{i}\in \mathbb {Z}$
for
$i=1,\dots ,t$
.
-
• if
$\widetilde {G}$
is the S-cover, then where
$$ \begin{align*}s_{i}=k_{i}n/\operatorname{gcd}(n,2l_{i}),\quad i=1,\dots,t,\end{align*} $$
$k_{i}\in \mathbb {Z}$
for
$i=1,\dots ,t$
.
Proof. If
$\widetilde {G}$
is a KP-cover, then
$\boldsymbol {d}=1$
. Write
$\Gamma =s_{1}r_{1}+\cdots +s_{t}r_{t}$
. We multiply the i-th equation in (6.3) by
$r_{i}/l_{i}$
and sum them together, which induces
$$ \begin{align*}(2\boldsymbol{c}r+\boldsymbol{c}-1)\Gamma\equiv 0\quad(\mathrm{mod}\ n).\end{align*} $$
Also, let
$s_{i}'=s_{i}-(2\boldsymbol {c}+1)\Gamma $
. Then (6.3) becomes
$$ \begin{align*}l_{i}s_{i}'\equiv 0 \quad(\mathrm{mod}\ n).\end{align*} $$
So solving these equations for
$s_{i}'$
and
$\Gamma $
, we get the desired result.
If
$\widetilde {G}$
is the S-cover, then
$\boldsymbol {d}=2$
and
$2\boldsymbol {c}+\boldsymbol {d}=0$
. So (6.3) becomes
$$ \begin{align*}2l_{i}s_{i}\equiv 0 \quad(\mathrm{mod}\ n),\quad i=1,\dots,t,\end{align*} $$
which can also be easily solved.
We also calculate the intertwining set
$I_{M}(\widetilde {\lambda }_{M})$
and the normalizer
$N_{M}(\widetilde {\lambda }_{M})$
.
Proposition 6.9. We have
$I_{M}(\widetilde {\lambda }_{M})=N_{M}(\widetilde {\lambda }_{M})=T(\varrho )J_{M}$
, where
$T(\varrho )$
is given by Proposition 6.7.
Proof. First we notice that
$I_{M}(\widetilde {\kappa }_{M})=J_{M}(M\cap B^{\times })J_{M}$
and
$\operatorname {Hom}_{\widetilde {J_{M}^{g}}\cap \widetilde {J_{M}}}(\widetilde {\kappa }_{M}^{g},\widetilde {\kappa }_{M})\cong \mathbb {C}$
for
$g\in I_{M}(\widetilde {\kappa }_{M})$
. This simply follows from the fact that
$J_{M}=J(\beta ,\mathfrak {a}^{1})\times \dots \times J(\beta ,\mathfrak {a}^{t})$
and
$\kappa _{M}=\kappa _{1}\boxtimes \dots \boxtimes \kappa _{t}$
, where
$\kappa _{i}$
is a
$\beta $
-extension of
$J(\beta ,\mathfrak {a}^{i})$
for
$i=1,\dots ,t$
. Then, as in Proposition 6.3, we have
$$ \begin{align*}I_{M}(\widetilde{\lambda}_{M})=J_{M}I_{M\cap B^{\times}}(\widetilde{\rho}\lvert_{M^{0}(\mathfrak{b})})J_{M}.\end{align*} $$
Using the Cartan decomposition, we have
$$ \begin{align*}M\cap B^{\times}=(U(\mathfrak{b})\cap M)T(B)(U(\mathfrak{b})\cap M).\end{align*} $$
Since
$U(\mathfrak {b})\cap M$
is contained in
$J_{M}$
, we have
$$ \begin{align*}I_{M}(\widetilde{\lambda}_{M})=J_{M}I_{T(B)}(\widetilde{\rho}\lvert_{M^{0}(\mathfrak{b})})J_{M}.\end{align*} $$
Finally, since the normalizer of
$M^{0}(\mathfrak {b})$
in
$T(B)$
is
$T(\mathfrak {b})$
, by Proposition 6.4, we have
$$ \begin{align*}I_{M}(\widetilde{\lambda}_{M})=J_{M}I_{T(\mathfrak{b})}(\widetilde{\rho}\lvert_{M^{0}(\mathfrak{b})})J_{M}=T(\varrho)J_{M}.\end{align*} $$
Also, since the group
$\boldsymbol {J}_{M}=T(\mathfrak {b})J_{M}$
contains
$I_{M}(\widetilde {\lambda }_{M})=T(\varrho )J_{M}$
, we also have
$N_{M}(\widetilde {\lambda }_{M})=T(\varrho )J_{M}$
.
6.3 Simple types
We keep the notation of previous subsections. We study a special class of homogeneous types, the so-called simple types.
Definition 6.10. A twisted simple type of
$\widetilde {G}$
is a homogeneous type
$(\widetilde {J},\widetilde {\lambda })$
as before, satisfying the following properties:
-
•
$\widetilde {\lambda }=\widetilde {\kappa }\otimes \widetilde {\rho }$
with
$\widetilde {\rho }=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s}\varrho )$
. -
•
$m_{1}=\dots =m_{t}$
. Then we write
$m_{0}=m/t$
and
$r_{0}=r/t$
. -
• There exist an irreducible cuspidal representation
$\varrho _{0}$
of
$\operatorname {GL}_{m_{0}}(\boldsymbol {l})$
and
$g_{0}\in T(\mathfrak {b})$
, such that
$\varrho $
is isomorphic to
$(\varrho _{0}\boxtimes \dots \boxtimes \varrho _{0})\chi _{g_{0}}$
as a representation of
$\mathcal {M}=\mathcal {G}^{1}\times \dots \times \mathcal {G}^{t}$
, where
$\mathcal {G}^{i}=\operatorname {GL}_{m_{0}}(\boldsymbol {l})$
for
$i=1,\dots ,t$
, and
$\chi _{g_{0}}:=\epsilon ([g_{0},\cdot ]_{\sim })$
is a character of
$\mathcal {M}\cong M^{0}(\mathfrak {b})/M^{1}(\mathfrak {b})$
.
If
$g_{0}=1$
, we call the corresponding
$(\widetilde {J},\widetilde {\lambda })$
a simple type of
$\widetilde {G}$
.
If the corresponding hereditary order
$\mathfrak {b}$
is maximal, or equivalently
$t=1$
, we call the corresponding
$(\widetilde {J},\widetilde {\lambda })$
a maximal simple type of
$\widetilde {G}$
.
If we fix
$\widetilde {\kappa }$
and
$\varrho _{0}$
and let
$g_{0}$
range over
$T(\mathfrak {b})$
, then the corresponding
$\widetilde {\lambda }$
forms a finite set of representations of
$\widetilde {J}$
, which we denote by
$[\widetilde {\lambda }]$
and call the weak equivalence class of
$\widetilde {\lambda }$
.
Still, we verify that the definition of twisted simple types is independent of the choice of K and
$\boldsymbol {s}$
. Let
$K'$
be another maximal open compact subgroup of G that contains
$U(\mathfrak {a})$
, and let
$\boldsymbol {s}'$
be a splitting of
$K'$
.
We first prove the following claim.
Lemma 6.11. There exists
$g\in W(\mathfrak {b})$
such that
$U(\mathfrak {b})^{g}=U(\mathfrak {b})$
and
$K'=K^{g}$
.
Proof. Let
$\mathfrak {a}$
be the corresponding hereditary order in A in defining our twisted simple type.
We first notice that when g ranges over the normalizer
$N_{G}(U(\mathfrak {a}))$
, the corresponding
$K^{g}$
ranges over all the maximal open compact subgroup of G that contains
$U(\mathfrak {a})$
. To see this, we may without loss of generality assume that
$\mathfrak {a}$
is a standard hereditary order. In this case, the normalizer
$N_{G}(U(\mathfrak {a}))$
is generated by
$U(\mathfrak {a})$
and the element
$$ \begin{align*}\Pi_{\mathfrak{a}}=\begin{pmatrix} & I_{m_{0}f(et-1)} \\ \varpi_{F}I_{m_{0}f} & \end{pmatrix}\in\operatorname{GL}_{r}(F).\end{align*} $$
Thus, in this case K,
$K^{\Pi _{\mathfrak {a}}},\dots ,K^{\Pi _{\mathfrak {a}}^{et-1}}$
are all the maximal compact subgroups containing
$U(\mathfrak {a})$
.
We also claim that there exists
$h\in W(\mathfrak {b})\cap N_{B^{\times }}(U(\mathfrak {b}))$
such that
$N_{G}(U(\mathfrak {a}))=\langle h\rangle U(\mathfrak {a})$
. Indeed, let
$\Lambda $
be the corresponding lattice chain of
$\mathfrak {a}$
. Then
$N_{G}(U(\mathfrak {a}))$
is generated by
$U(\mathfrak {a})$
and an element h in G that maps
$\Lambda ^{i}$
to
$\Lambda ^{i+1}$
for each
$i\in \mathbb {Z}$
(In the above standard case, it could be the element
$\Pi _{\mathfrak {a}}$
as above). Or, since
$\Lambda $
is E-pure, such h can be chosen to be an element in
$B^{\times }$
that maps
$\Lambda _{E}^{i}$
to
$\Lambda _{E}^{i+1}$
for each
$i\in \mathbb {Z}$
. Such h, by definition, can be chosen as an element in
$W(\mathfrak {b})\cap N_{B^{\times }}(U(\mathfrak {b}))$
.
Thus, we may choose
$g\in N_{G}(U(\mathfrak {a}))$
, such that
$K'=K^{g}$
. Since
$U(\mathfrak {a})\subset K$
, we may also assume that
$g\in \langle h\rangle $
. Thus, we also have
$U(\mathfrak {b})^{g}=U(\mathfrak {b})$
, which finishes the proof.
Let
$(\widetilde {J},\widetilde {\lambda }')$
be the corresponding twisted simple type constructed using the pair
$(K',\boldsymbol {s}')$
instead of
$(K,\boldsymbol {s})$
. More precisely, we have
$\widetilde {\lambda }'=\widetilde {\kappa }\otimes \widetilde {\rho }'$
, where
$\widetilde {\rho }'=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s'}\varrho )$
. We would like to show that
$(\widetilde {J},\widetilde {\lambda }')$
is a twisted simple type with respect to the pair
$(K,\boldsymbol {s})$
. We write
$\varrho =(\varrho _{0}\boxtimes \dots \boxtimes \varrho _{0})\chi _{g_{0}}$
with
$g_{0}\in T(\mathfrak {b})$
.
Choose g as in the lemma, and write
$g=w_{0}h$
with
$w_{0}\in W_{0}(\mathfrak {b})$
and
$h\in T(\mathfrak {b})$
. We write
$h'=g_{0}^{-1}w_{0}^{-1}g_{0}w_{0}h\in T(\mathfrak {b})$
since
$g_{0}, w_{0}^{-1}g_{0}w_{0}, h\in T(\mathfrak {b})$
. By definition, we have
$$ \begin{align*}\widetilde{\rho}'=\operatorname{Inf}_{\widetilde{\mathcal{M}}}^{\widetilde{J}}((\epsilon\cdot\,_{s}\varrho)^{g}\chi_{\boldsymbol{s}^{g}|\boldsymbol{s}'})=\operatorname{Inf}_{\widetilde{\mathcal{M}}}^{\widetilde{J}}((\epsilon\cdot\,_{s}\varrho)^{h'}\chi_{\boldsymbol{s}^{g}|\boldsymbol{s}'}).\end{align*} $$
The character
$\chi _{\boldsymbol {s}^{g}|\boldsymbol {s}'}(x)=\boldsymbol {s}'(x)/\boldsymbol {s}^{g}(x)$
of
$K'$
can be written as a character
$\chi $
of
$\mathfrak {o}_{F}^{\times }/1+\mathfrak {p}_{F}\cong \boldsymbol {k}^{\times }$
composing with the determinant
$\operatorname {det}_{F}$
. Let
$$ \begin{align*}\varrho'=\varrho_{0}(\chi\circ\operatorname{N}_{\boldsymbol{l}/\boldsymbol{k}}\circ\operatorname{det}_{\boldsymbol{l}})\boxtimes\cdots\boxtimes \varrho_{0}(\chi\circ\operatorname{N}_{\boldsymbol{l}/\boldsymbol{k}}\circ\operatorname{det}_{\boldsymbol{l}}).\end{align*} $$
Then by direct verification, we have
$\varrho \chi _{\boldsymbol {s}^{g}|\boldsymbol {s}'}=\varrho '\chi _{g_0}$
and
$\widetilde {\rho }'=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s}(\varrho '\chi _{g_{0}h'}))$
. Thus,
$(\widetilde {J},\widetilde {\lambda }')$
is also a twisted simple type with respect to the pair
$(K,\boldsymbol {s})$
. Thus, in considering a twisted simple type, we may fix any K and
$\boldsymbol {s}$
as above.
Remark 6.12. However, the definition of a simple type indeed depends on the choice of the maximal compact subgroup K containing J and the splitting
$\boldsymbol {s}$
of K.
In the rest of this subsection, let
$(\widetilde {J},\widetilde {\lambda })$
be a twisted simple type of
$\widetilde {G}$
. We further study the intertwining set of
$\widetilde {\lambda }$
.
Let
$l_{0}$
be the maximal positive integer dividing n, such that
$\varrho _{0}$
is isomorphic to its twist by a certain character of
$\operatorname {GL}_{m_{0}}(\boldsymbol {l})$
of order
$l_{0}$
. As before,
$l_{0}$
divides
$m_{0}$
.
Let
$T(r_{0},m_{0},l_{0};t)$
be the group
$T(\varrho )$
in (6.4) with
$l_{1}=\dots =l_{t}=l_{0}$
,
$m_{1}=\dots =m_{t}=m_{0}$
and
$r_{1}=\dots =r_{t}=r_{0}$
. Then
$T(r_{0},m_{0},l_{0};t)$
is normalized by
$W(\mathfrak {b})$
.
Let
$$ \begin{align*}W(r_{0},m_{0},l_{0};t)=W_{0}(\mathfrak{b})\ltimes T(r_{0},m_{0},l_{0};t),\end{align*} $$
which is a subgroup of
$W(\mathfrak {b})$
.
Proposition 6.13. We have
$I_{G}(\widetilde {\lambda })=JW(r_{0},m_{0},l_{0};t)^{g_{0}}J$
.
Proof. Using Proposition 6.3 and Proposition 6.4, we only need to show that the normalizer
$N_{W(\mathfrak {b})}(\widetilde {\varrho }\lvert _{M(\mathfrak {b})})$
equals
$W(r_{0},m_{0},l_{0};t)^{g_{0}}$
. Since
$\widetilde {\varrho }=(\epsilon \cdot \,_{s}(\varrho _{0}\boxtimes \dots \boxtimes \varrho _{0}))^{g_0}$
, by extracting the
$g_0$
-conjugation, we may assume
$\varrho =\varrho _{0}\boxtimes \dots \boxtimes \varrho _{0}$
and
$g_{0}=1$
without loss of generality. Then the proposition follows from Proposition 6.6, Proposition 6.7, and the fact that
$W_{0}(\mathfrak {b})$
normalizes
$\varrho $
.
We give a more concrete description of
$W(r_{0},m_{0},l_{0};t)$
. As before, we choose an E-basis of
$V_{E}=V_{E}^{1}\oplus \cdots \oplus V_{E}^{t}$
, such that
$\mathfrak {b}_{\text {max}}$
,
$\mathfrak {b}$
and
$\mathfrak {b}_{\text {min}}$
are standard hereditary orders of
$B\cong \operatorname {M}_{m}(E)$
. Under such basis,
$W_{0}(\mathfrak {b})$
is identified with the group of transposition matrices of the form
$$ \begin{align*}(\delta_{\varsigma(i)j}I_{m_{0}})_{1\leq i,j\leq t},\end{align*} $$
where
$\varsigma \in \mathfrak {S}_{t}$
, and
$\delta _{ij}=1$
if
$i=j$
and
$0$
otherwise. In particular,
$$ \begin{align} \mathcal{F}_{0}:\mathfrak{S}_{t}\rightarrow W_{0}(\mathfrak{b}),\quad \varsigma\mapsto (\delta_{\varsigma(i)j}I_{m_{0}})_{1\leq i,j\leq t} \end{align} $$
is an isomorphism. Let
$\varsigma _{i}$
denote the transposition of i and
$i+1$
and let
$\sigma _{i}:=\mathcal {F}_{0}(\varsigma _{i})$
for
$i=1,\dots ,t-1$
. Then
$\{\sigma _{1},\dots ,\sigma _{t-1}\}$
is a set of generators of
$W_{0}(\mathfrak {b})$
.
Consider the following linear congruence equations:
$$ \begin{align} l_{0}[(s_{1}+\dots+s_{t})r_{0}(2\boldsymbol{c}+\boldsymbol{d})-s_{i}\boldsymbol{d}]\equiv 0\quad(\mathrm{mod}\ n),\quad i=1,\dots,t. \end{align} $$
Using (6.4), we have
$$ \begin{align} T(r_{0},m_{0},l_{0};t)=\{\operatorname{diag}(\varpi_{E}^{s_{1}}I_{m_{0}},\dots,\varpi_{E}^{s_{t}}I_{m_{0}})\mid s_{1},\dots,s_{t}\in \mathbb{Z}\ \text{satisfies}\ (6.8)\}. \end{align} $$
Consider the solutions of (6.8) such that
$s_{1}=\dots =s_{t-1}=0$
. Then it is required that
$$ \begin{align*}l_{0}[(2\boldsymbol{c}+\boldsymbol{d})r_{0}-\boldsymbol{d}]s_{t}\equiv 0\ (\mathrm{mod}\ n)\quad \text{and}\quad l_{0}\boldsymbol{d}s_{t}\equiv 0\ (\mathrm{mod}\ n),\end{align*} $$
so
$s_{t}=kn_{r_{0},l_{0}}$
for
$k\in \mathbb {Z}$
, where
$$ \begin{align} n_{r_{0},l_{0}}:=n/\operatorname{gcd}(n,(2\boldsymbol{c}+\boldsymbol{d})r_{0}l_{0},\boldsymbol{d}l_{0}). \end{align} $$
In particular,
$$ \begin{align}n_{r_{0},l_{0}}=\begin{cases} n/l_{0}&\quad \text{if}\ \widetilde{G}\ \text{is a KP-cover},\\ n/\operatorname{gcd}(n,2l_{0}) &\quad \text{if}\ \widetilde{G}\ \text{is the S-cover}. \end{cases} \end{align} $$
We also consider the solutions of (6.8) such that
$s:=s_{1}=\dots =s_{t}$
. Then it is required that
$$ \begin{align*}l_{0}[(2\boldsymbol{c}+\boldsymbol{d})r-\boldsymbol{d}]s\equiv0\ (\text{mod}\ n).\end{align*} $$
So
$s_{1}=\dots =s_{t}=kd_{r,l_{0}}$
for
$k\in \mathbb {Z}$
, where
$$ \begin{align} d_{r,l_{0}}=n/\operatorname{gcd}(n,l_{0}(2\boldsymbol{c}r+\boldsymbol{d}r-\boldsymbol{d})). \end{align} $$
In particular,
$$ \begin{align} d_{r,l_{0}}=\begin{cases}n/(l_{0}\operatorname{gcd}(n,2\boldsymbol{c}r+r-1))&\quad \text{if}\ \widetilde{G}\ \text{is a KP-cover},\\ n/\operatorname{gcd}(n,2l_{0}) &\quad \text{if}\ \widetilde{G}\ \text{is the S-cover}. \end{cases} \end{align} $$
Note that for the KP-cover, we use the fact that
$l_{0}$
divides r and
$\operatorname {gcd}(l_{0},2\boldsymbol {c}r+r-1)=1$
.
By definition,
$d_{r,l_{0}}$
divides
$n_{r_{0},l_{0}}$
. We write
$$ \begin{align} s_{r_{0},l_{0}}=n_{r_{0},l_{0}}/d_{r,l_{0}}. \end{align} $$
For most cases, we write
$n_{0}=n_{r_{0},l_{0}}$
,
$d_{0}=d_{r,l_{0}}$
and
$s_{0}=s_{r_{0},l_{0}}$
for short.
Let
$\varsigma '$
be the permutation
$1\mapsto 2\mapsto \dots \mapsto t-1\mapsto t\mapsto 1$
. Let
$$ \begin{align} \Pi_{E}=\operatorname{diag}(\underbrace{I_{m_{0}},\dots,I_{m_{0}},\varpi_{E}^{n_{0}}I_{m_{0}}}_{t\text{-terms}})\mathcal{F}_{0}(\varsigma')\quad\text{and}\quad \zeta_{E} =\operatorname{diag}(\underbrace{\varpi_{E}^{d_{0}}I_{m_{0}},\dots,\varpi_{E}^{d_{0}}I_{m_{0}}}_{t\text{-terms}}) \end{align} $$
be elements in
$W(r_{0},m_{0},l_{0};t)$
. By definition, we have
$\Pi _{E}^{t}=\zeta _{E}^{s_{0}}$
.
The elements
$\sigma _{1},\dots ,\sigma _{k-1}$
,
$\Pi _{E}$
and
$\zeta _{E}$
generate a normal subgroup of
$W(r_{0},m_{0},l_{0};t)$
of finite index, which we denote by
$W'(r_{0},m_{0},l_{0};t)$
.
We often write
$T_{0}=T(r_{0},m_{0},l_{0};t)$
,
$W_{0}=W(r_{0},m_{0},l_{0};t)$
and
$W_{0}'=W'(r_{0},m_{0},l_{0};t)$
for short.
Proposition 6.14. If
$\widetilde {G}$
is either a KP-cover or the S-cover, then
$W_{0}=W_{0}'$
.
Proof. Using Proposition 6.7, Corollary 6.8, (6.11), (6.13), we may verify directly that
$\sigma _{1},\dots ,\sigma _{k-1}$
,
$\Pi _{E}$
and
$\zeta _{E}$
generate
$W_0$
.
In particular, for the S-cover, we have
$s_{0}=1$
and
$\Pi _{E}^{t}=\zeta _{E}$
; hence,
$\sigma _{1}\dots ,\sigma _{t-1}$
and
$\Pi _{E}$
generate
$W_{0}$
.
6.4 Main results for homogeneous and simple types
We list our main results for homogeneous and (twisted) simple types.
First, we let
$(\widetilde {J},\widetilde {\lambda })$
be a homogeneous type of
$\widetilde {G}$
, and we construct the related pairs
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
and
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
as before.
An inertial equivalence class
$\mathfrak {s}_{M}=(\widetilde {M},\mathcal {O}_{M})$
of
$\widetilde {M}$
is called cuspidal if
$\mathcal {O}_{M}$
consists of (genuine) cuspidal representations of
$\widetilde {M}$
.
Theorem 6.15. The pair
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
is a type related to a cuspidal inertial equivalence class of
$\widetilde {M}$
.
Proof. We define
$\boldsymbol {J}_{M}=T(\mathfrak {b})J_{M}$
as a subgroup in M. By Proposition 6.9,
$\boldsymbol {J}_{M}$
contains the normalizer and the intertwining set
$I_{M}(\widetilde {\lambda }_{M})=N_{M}(\widetilde {\lambda }_{M})$
. Let
$Z(\widetilde {M})$
be the center of
$\widetilde {M}$
. Then both
$\widetilde {\boldsymbol {J}_{M}}$
and
$N_{\widetilde {M}}(\widetilde {\lambda }_{M})$
contain
$Z(\widetilde {M})$
. Moreover, the quotient
$\widetilde {\boldsymbol {J}_{M}}/Z(\widetilde {M})\widetilde {J_{M}}$
is a finite abelian group.
We first extend
$\widetilde {\lambda }_{M}$
to an irreducible representation
$\widetilde {\lambda }_{M}'$
of
$Z(\widetilde {M})\widetilde {J_{M}}$
, which could be done by choosing a compatible central character. Using [Reference Gelbart and Knapp31, Lemma 2.1], Frobenius reciprocity and the Mackey formula, we may easily deduce that
-
• There exists an irreducible representation
$\widetilde {\boldsymbol {\lambda }}_{M}$
of
$\widetilde {\boldsymbol {J}_{M}}$
, whose restriction to
$Z(\widetilde {M})\widetilde {J_{M}}$
contains
$\widetilde {\lambda }_{M}'$
. -
• There exist positive integers k and d, such that
$\left |N_{M}(\widetilde {\lambda })/\boldsymbol {p}(Z(\widetilde {M}))J_{M}\right |=dk^{2}$
, and (6.16)
$$ \begin{align} \widetilde{\boldsymbol{\lambda}}_{M}\lvert_{Z(\widetilde{M})\widetilde{J_{M}}}\cong\bigoplus_{g\in\boldsymbol{J}_{M}/N_{M}(\widetilde{\lambda}_{M})}k\cdot\widetilde{\lambda}_{M}^{\prime g}. \end{align} $$
-
• There exists a finite set
$\{\chi _{1},\dots ,\chi _{d}\}$
of characters of
$J_{M}$
that are trivial on
$\boldsymbol {p}(Z(\widetilde {M}))$
, such that
$\widetilde {\boldsymbol {\lambda }}_{M}\cdot \chi _{i}$
are pairwise inequivalent for
$i=1,\dots ,d$
. Moreover, (6.17)
$$ \begin{align} \operatorname{ind}_{Z(\widetilde{M})\widetilde{J_{M}}}^{\widetilde{\boldsymbol{J}_{M}}}\widetilde{\lambda}_{M}'\cong\bigoplus_{i=1}^{d}k\cdot(\widetilde{\boldsymbol{\lambda}}_{M}\cdot\chi_{i}). \end{align} $$
For
$g\in I_{M}(\widetilde {\boldsymbol {\lambda }}_{M})$
, restricting
$\widetilde {\boldsymbol {\lambda }}_{M}^{g}$
and
$\widetilde {\boldsymbol {\lambda }}_{M}$
to
$\widetilde {J_{M}^{g}}\cap \widetilde {J_{M}}$
and using (6.16), there exists
$g'\in \boldsymbol {J}_{M}$
such that g intertwines
$\widetilde {\lambda }_{M}^{g'}$
with
$\widetilde {\lambda }_{M}$
. Thus,
$g'g\in I_{M}(\widetilde {\lambda }_{M})$
, implying that
$g\in \boldsymbol {J}_{M}$
. So the intertwining set
$I_{M}(\widetilde {\boldsymbol {\lambda }}_{M})$
equals
$\boldsymbol {J}_{M}$
. Using Lemma 3.2, the compact induction
$\widetilde {\pi }=\operatorname {ind}_{\widetilde {\boldsymbol {J}_{M}}}^{\widetilde {M}}\widetilde {\boldsymbol {\lambda }}_{M}$
is a genuine irreducible cuspidal representation of
$\widetilde {M}$
.
Let
$\mathfrak {s}_{M}$
be the corresponding inertial equivalence class of
$\widetilde {M}$
that contains
$\widetilde {\pi }$
. Let
$M^{0}$
denote the subgroup of M as the intersection of the kernel of all the unramified characters of M. Then by definition,
$Z(\widetilde {M})\cap \widetilde {M^{0}}$
is contained in
$\widetilde {J_{M}}$
. Moreover, we have
$J_{M}=\boldsymbol {J}_{M}\cap M^{0}$
, which induces an embedding
$\boldsymbol {J}_{M}/J_{M}\hookrightarrow M/M^{0}$
. For each
$i=1,\dots ,d$
, the character
$\chi _{i}$
, regarded as character of
$\boldsymbol {J}_{M}/J_{M}$
, can be extended to a character of
$M/M^{0}$
, which is still denoted by
$\chi _{i}$
. Then, taking the compact induction functor
$\operatorname {ind}_{\widetilde {\boldsymbol {J}_{M}}}^{\widetilde {M}}$
for (6.17), we get
$$ \begin{align*}\operatorname{ind}_{Z(\widetilde{M})\widetilde{J_{M}}}^{\widetilde{M}}\widetilde{\lambda}_{M}'\cong\bigoplus_{i=1}^{d}k\cdot(\widetilde{\pi}\chi_{i}).\end{align*} $$
Thus, by [Reference Bushnell and Kutzko22, Proposition 5.2],
$(\widetilde {J}_{M},\widetilde {\lambda }_{M})$
is an
$\mathfrak {s}_{M}$
-type, which finishes the proof.
We further assume
$(\widetilde {J},\widetilde {\lambda })$
to be a simple type of
$\widetilde {G}$
.
Theorem 6.16. Let
$(\widetilde {J},\widetilde {\lambda })$
be a simple type of
$\widetilde {G}$
. Then
$(\widetilde {J}_{P},\widetilde {\lambda }_{P})$
is a covering pair of
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
, and both
$(\widetilde {J},\widetilde {\lambda })$
and
$(\widetilde {J}_{P},\widetilde {\lambda }_{P})$
are types of
$\widetilde {G}$
.
Theorem 6.16 will be proved in the next section.
Remark 6.17. Indeed, Theorem 6.16 is expected to be true for homogeneous types, which, however, will not be discussed in this article and will be written down elsewhere.
In particular, if
$(\widetilde {J},\widetilde {\lambda })$
is a maximal simple type of
$\widetilde {G}$
, then it is a type related to a cuspidal inertial equivalence class of
$\widetilde {G}$
.
Finally, we have the following theorem, stating that intertwining of twisted simple types implies conjugacy of corresponding weak equivalence classes:
Theorem 6.18. Let
$(\widetilde {J},\widetilde {\lambda })$
,
$(\widetilde {J}',\widetilde {\lambda }')$
be twisted simple types of
$\widetilde {G}$
, attached to hereditary orders
$\mathfrak {a}$
,
$\mathfrak {a}'$
in A. Suppose that
$\mathfrak {a}$
and
$\mathfrak {a}'$
are conjugate by G, and
$\widetilde {\lambda }$
intertwines with
$\widetilde {\lambda }'$
in G. Then, there exists
$g\in G$
such that
$J'=J^{g}$
and
$[\widetilde {\lambda }']\cong [\widetilde {\lambda }^{g}]$
.
Proof. The argument follows from that of [Reference Bushnell and Kutzko19, Theorem 5.7.1] (also see [Reference V. Sécherre and Stevens67, Theorem 6.1]). As in loc. cit., up to G-conjugacy we may assume that there exist an r-dimensional vector space V over F, and two strict simple stratum
$[\mathfrak {a},u,0,\beta ]$
and
$[\mathfrak {a},u,0,\beta ']$
in
$A=\operatorname {End}_{F}(V)$
such that
-
(1)
$E=F[\beta ]$
and
$E'=F[\beta ']$
are fields of degree d over F, having the same residue field denoted by
$\boldsymbol {l}$
. Write
$m=r/d$
. Let
$B=\operatorname {End}_{E}(V_{E})$
,
$\mathfrak {b}=B\cap \mathfrak {a}$
. We may also assume that
$H^{1}=H^{1}(\beta ,\mathfrak {a})=H^{1}(\beta ',\mathfrak {a})$
,
$J^{1}=J^{1}(\beta ,\mathfrak {a})=J^{1}(\beta ',\mathfrak {a})$
and
$J=J(\beta ,\mathfrak {a})=J(\beta ',\mathfrak {a})$
. -
(2) There exist a simple character
$\theta \in \mathcal {C}(\mathfrak {a},\beta )\cap \mathcal {C}(\mathfrak {a},\beta ')$
, the Heisenberg representation
$\eta $
of
$\theta $
, a
$\beta $
-extension
$\kappa $
of
$\eta $
, two cuspidal representations
$\varrho $
and
$\varrho '$
of
$\mathcal {M}\cong U(\mathfrak {b})/U^{1}(\mathfrak {b})\cong J/J^{1}$
and the corresponding inflations
$\widetilde {\rho }=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s}\varrho )$
and
$\widetilde {\rho }'=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s}\varrho ')$
, such that
$\widetilde {\lambda }\cong \widetilde {\kappa }\otimes \widetilde {\rho }$
and
$\widetilde {\lambda }'\cong \widetilde {\kappa }\otimes \widetilde {\rho }'$
. -
(3) Write
$\mathcal {M}=\mathcal {G}^{1}\times \dots \times \mathcal {G}^{t}$
, where
$\mathcal {G}^{1}\cong \dots \cong \mathcal {G}^{t}\cong \operatorname {GL}_{m_{0}}(\boldsymbol {l})$
with
$m_{0}=m/t$
. Then, there exist a cuspidal representation
$\varrho _{0}$
of
$\operatorname {GL}_{m_{0}}(\boldsymbol {l})$
and
$g_{0}\in T(\mathfrak {b})$
, such that
$\varrho \cong (\varrho _{0}\boxtimes \dots \boxtimes \varrho _{0})\chi _{g_{0}}$
.
Let
$x\in G$
that intertwines
$\widetilde {\lambda }$
and
$\widetilde {\lambda }'$
. Restricting to
$\,_{s}H^{1}\cap \,_{s}H^{1x}$
, we deduce that x intertwines
$\,_{s}\theta $
, then
$x\in JB^{\times }J$
. Using the Bruhat decomposition, we have
$JB^{\times }J=JU(\mathfrak {b}_{m})W(B)U(\mathfrak {b}_{m})J=JW(B)J$
. So we may assume
$x\in W(B)$
without loss of generality. Since
$$ \begin{align*}\operatorname{Hom}_{\widetilde{J}^{x}\cap\widetilde{J}}(\widetilde{\lambda}^{x},\widetilde{\lambda}')=\operatorname{Hom}_{\widetilde{J}^{x}\cap\widetilde{J}}(\widetilde{\rho}^{x},\widetilde{\rho}')\neq 0,\end{align*} $$
Proposition 6.4, or more precisely its proof, shows that x normalizes
$M^{0}(\mathfrak {b})$
,
$M^{1}(\mathfrak {b})$
and
$\mathcal {M}$
. Up to changing the
$U(\mathfrak {b})$
-
$U(\mathfrak {b})$
double coset of x, we may further assume that
$x\in W(\mathfrak {b})$
. Thus, we have
$$ \begin{align} 0\neq\operatorname{Hom}_{\widetilde{J}^{x}\cap\widetilde{J}}(\widetilde{\lambda}^{x},\widetilde{\lambda}')=\operatorname{Hom}_{\widetilde{J}^{x}\cap\widetilde{J}}(\widetilde{\rho}^{x},\widetilde{\rho}')= \operatorname{Hom}_{\widetilde{\mathcal{M}}}((\epsilon\cdot\,_{s}\varrho)^{x},\epsilon\cdot\,_{s}\varrho'). \end{align} $$
Write
$x=wx'$
with
$w\in W_{0}(\mathfrak {b})$
and
$x'\in T(\mathfrak {b})$
. Then
$h=w^{-1}g_{0}wx'$
is also in
$T(\mathfrak {b})$
. Moreover, we have
$$ \begin{align*}(\epsilon\cdot\,_{s}\varrho)^{x}\cong(\epsilon\cdot\,_{s}(\varrho_{0}\boxtimes\dots\boxtimes\varrho_{0}))^{g_{0}x}=(\epsilon\cdot\,_{s}(\varrho_{0}\boxtimes\dots\boxtimes\varrho_{0}))^{wh}=(\epsilon\cdot\,_{s}(\varrho_{0}\boxtimes\dots\boxtimes\varrho_{0}))\chi_{h}.\end{align*} $$
Thus, (6.18) implies that
$\varrho '\cong (\varrho _{0}\boxtimes \dots \boxtimes \varrho _{0})\chi _{h}$
, meaning that
$[\widetilde {\lambda }']= [\widetilde {\lambda }]$
. So the proof is finished.
We extract the following corollary from the argument above.
Corollary 6.19. Let
$(\widetilde {J},\widetilde {\lambda })$
and
$(\widetilde {J},\widetilde {\lambda '})$
be twisted simple types of
$\widetilde {G}$
attached to the same hereditary order. If
$x\in G$
intertwines
$\widetilde {\lambda }$
and
$\widetilde {\lambda '}$
, then
$x\in JW(\mathfrak {b})J$
.
Remark 6.20. The above theorem cannot be relaxed to ‘intertwining implies conjugation’, as in [Reference Bushnell and Kutzko19, Theorem 5.7.1] when
$n=1$
. Indeed, two twisted simple types in the same weak equivalence class are intertwined by an element in
$T(\mathfrak {b})$
. However, it is easy to cook up an example that two weakly equivalent twisted simple types are not necessarily conjugate by G.
7 Calculation of Hecke algebra
In this section, we keep the notation of Section 6. Our main goal is to prove Theorem 6.16 by giving a precise description of the Hecke algebra
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
, where
$(\widetilde {J},\widetilde {\lambda })$
is a simple type. Along the way, we show that
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
is indeed an affine Hecke algebra of type A if
$\widetilde {G}$
is a KP-cover or the S-cover.
7.1 Finite and affine Hecke algebras of type A
In this part, we recall known results on finite and affine Hecke algebras of type A (cf. [Reference Bushnell and Kutzko19, §5.4] and [Reference Solleveld68, §1]). We fix a real number
$z>1$
and two positive integers t, s.
First, we define the finite Hecke algebra
$$ \begin{align*}\mathcal{H}_{0}(t,z)=\mathbb{C}[1,[\varsigma_{i}]\mid i=1,\dots,t-1],\end{align*} $$
where the generators
$1$
,
$[\varsigma _{i}]$
are subject to the following relations
-
(0) 1 is the unit element.
-
(1)
$[\varsigma _{i}][\varsigma _{j}]=[\varsigma _{j}][\varsigma _{i}]$
,
$1\leq i,j\leq t-1$
,
$\left |i-j\right |\geq 2$
. -
(2)
$[\varsigma _{i}][\varsigma _{i+1}][\varsigma _{i}]=[\varsigma _{i+1}][\varsigma _{i}][\varsigma _{i+1}]$
,
$i=1,\dots ,t-2$
. -
(3)
$([\varsigma _{i}]-z)([\varsigma _{i}]+1)=0$
,
$i=1,\dots ,t-1$
.
We identify
$\varsigma _{i}$
with the transposition of i and
$i+1$
in
$\mathfrak {S}_{t}$
. For any
$\varsigma \in \mathfrak {S}_{t}$
, we consider a reduced decomposition
$$ \begin{align*}\varsigma=\prod_{i=1}^{l}\varsigma_{i}',\end{align*} $$
where
$\varsigma ^{\prime }_{i}\in \{\varsigma _{1},\dots \varsigma _{t-1}\}$
such that l is minimal. Then, the element
$$ \begin{align*}[\varsigma]:=\prod_{i=1}^{l}[\varsigma_{i}']\in\mathcal{H}_{0}(t,z)\end{align*} $$
is independent of the choice of the above decomposition. Here, by convention, we write
$[1]=1$
. The underlying vector space of the finite Hecke algebra is exactly
$$ \begin{align*}\mathbb{C}\langle[\varsigma]\mid\varsigma\in\mathfrak{S}_{t}\rangle,\end{align*} $$
which is
$t!$
-dimensional.
Then we define the linear affine Hecke algebra
$$ \begin{align*}\mathcal{H}(t,z)=\mathbb{C}[1,[\varsigma_{i}],[\Pi]\mid i=1,\dots,t-1],\end{align*} $$
where the generators
$1,[\varsigma _{i}],[\Pi ]$
are subject to the relations (0)–(3) and
-
(4)
$[\Pi ]$
is invertible with respect to the multiplication. -
(5)
$[\Pi ][\varsigma _{i}]=[\varsigma _{i-1}][\Pi ]$
,
$i=2,\dots ,t-1$
. -
(6)
$[\Pi ]^{2}[\varsigma _{1}]=[\varsigma _{t-1}][\Pi ]^{2}$
.
In particular, we define
$[\varsigma _{0}]=[\Pi ][\varsigma _{1}][\Pi ]^{-1}=[\Pi ]^{-1}[\varsigma _{t-1}][\Pi ]$
.
We consider the (extended) affine Weyl group
$W_{t}^{\mathrm {aff}}=\mathbb {Z}^{t}\rtimes \mathfrak {S}_{t}$
, where the semi-direct product is given by
$(k_{\varsigma (1)},\dots ,k_{\varsigma (t)})\cdot \varsigma =\varsigma \cdot (k_{1},\dots ,k_{t})$
for
$(k_{1},\dots ,k_{t})\in \mathbb {Z}^{t}$
and
$\varsigma \in \mathfrak {S}_{t}$
.
Still, we identify
$\varsigma _{i}$
with elements in
$\mathfrak {S}_{t}\subset W_{t}^{\mathrm {aff}}$
as above and
$\Pi $
with the element
$$ \begin{align*}(0,\dots,0,1)\cdot \varsigma'\in W_{t}^{\mathrm{aff}},\end{align*} $$
where
$\varsigma '$
denotes the permutation
$1\mapsto 2\mapsto \dots \mapsto t-1\mapsto t\mapsto 1$
. We define
$\varsigma _{0}=\Pi \varsigma _{1}\Pi ^{-1}\in W_{t}^{\mathrm {aff}}$
.
For any
$w\in W_{t}^{\mathrm {aff}}$
, similarly we may consider a decomposition
$$ \begin{align*}w=\Pi^{a}\cdot\prod_{i=1}^{l}\varsigma_{i}',\end{align*} $$
where
$a\in \mathbb {Z}$
is an integer uniquely determined by w, and
$\varsigma ^{\prime }_{i}\in \{\varsigma _{0},\varsigma _{1},\dots \varsigma _{t-1}\}$
such that l is minimal. The element
$$ \begin{align*}[w]:=[\Pi]^{a}\cdot\prod_{i=1}^{l}[\varsigma_{i}']\in\mathcal{H}(t,z)\end{align*} $$
is independent of the choice of the above decomposition. Then, the underlying vector space of the linear affine Hecke algebra is
$$ \begin{align*}\mathbb{C}\langle[w]\mid w\in W_{t}^{\mathrm{aff}}\rangle.\end{align*} $$
In particular,
$[\Pi ]^{t}$
is central in
$\mathcal {H}(t,z)$
. We write
$$ \begin{align*}\mathcal{A}(t):=\mathbb{C}[[\lambda]\mid \lambda\in\mathbb{Z}^{t}\subset W_{t}^{\mathrm{aff}}],\end{align*} $$
which turns out to be a commutative algebra isomorphic to the polynomial algebra
$$ \begin{align*}\mathbb{C}[X_{1},X_{1}^{-1},\dots,X_{t},X_{t}^{-1}],\end{align*} $$
where
$X_{i}=[(0,\dots ,0,1,0,\dots ,0)]$
with 1 in the i-th row. Then we have an
$\mathbb {C}$
-algebra isomorphism
$$ \begin{align*}\mathcal{H}(t,z)\cong\mathcal{A}(t)\otimes_{\mathbb{C}}\mathcal{H}_{0}(t,z).\end{align*} $$
The results listed above could be found in [Reference Bushnell and Kutzko19, §5.4].
We also slightly generalize the above discussion to define the twisted affine Hecke algebra
$$ \begin{align*}\widetilde{\mathcal{H}}(t,s,z)=\mathbb{C}[1,[\varsigma_{i}],[\Pi],[\zeta]\mid i=1,\dots,t-1],\end{align*} $$
where the generators
$1,[\varsigma _{i}],[\Pi ],[\zeta ]$
are subject to the relations (0)–(6) and
-
(7)
$[\zeta ]$
is central and invertible with respect to the multiplication. -
(8)
$[\zeta ]^{s}=[\Pi ]^{t}$
.
In particular,
$\mathcal {H}(t,z)$
is a subalgebra of
$\widetilde {\mathcal {H}}(t,s,z)$
of index s. If
$s=1$
, we simply have
$\widetilde {\mathcal {H}}(t,s,z)=\mathcal {H}(t,z)$
.
Later on, we will see that for KP-covers and the S-cover, the Hecke algebra of a simple type is exactly a twisted affine Hecke algebra. Indeed, for the S-cover, we have
$s=1$
, so it is reduced to the linear case.
We consider the twisted affine Weyl group
$$ \begin{align*}\widetilde{W}_{t,s}^{\mathrm{aff}}=\mathbb{Z}_{1/s}^{t}\rtimes\mathfrak{S}_{t},\end{align*} $$
where
$\mathbb {Z}_{1/s}^{t}$
denotes the sub-lattice of
$\mathbb {Q}^{t}$
generated by
$\mathbb {Z}^{t}$
and
$(1/s,1/s,\dots ,1/s)$
, and the semi-direct product is similarly given as before. We identify
$\varsigma _{i}$
and
$\Pi $
with elements in
$W_{t}^{\mathrm {aff}}\subset \widetilde {W}_{t,s}^{\mathrm {aff}}$
as before, and
$\zeta $
with
$(1/s,1/s,\dots ,1/s)\in \mathbb {Z}_{1/s}^{t}\subset \widetilde {W}_{t,s}^{\mathrm {aff}}$
.
For any
$w\in \widetilde {W}_{t,s}^{\mathrm {aff}}$
, we may consider a decomposition
$$ \begin{align*}w=\Pi^{a}\cdot\zeta^{b}\cdot\prod_{i=1}^{l}\varsigma_{i}',\end{align*} $$
where
$a\in \mathbb {Z}$
and
$b\in \{0,1,\dots s-1\}$
are uniquely determined by w, and
$\varsigma ^{\prime }_{i}\in \{\varsigma _{0},\varsigma _{1},\dots \varsigma _{t-1}\}$
such that l is minimal. Then, the element
$$ \begin{align} [w]:=[\Pi]^{a}\cdot[\zeta]^{b}\cdot\prod_{i=1}^{l}[\varsigma_{i}']\in\widetilde{\mathcal{H}}(t,s,z) \end{align} $$
is independent of the choice of the above decomposition. The underlying vector space of the twisted affine Hecke algebra is
$$ \begin{align*}\mathbb{C}\langle[w]\mid w\in\widetilde{W}_{t,s}^{\mathrm{aff}}\rangle.\end{align*} $$
We write
$$ \begin{align*}\widetilde{\mathcal{A}}(t,s):=\mathbb{C}[[\lambda]\mid \lambda\in\mathbb{Z}_{1/s}^{t}\subset\widetilde{W}_{t,s}^{\mathrm{aff}}],\end{align*} $$
which turns out to be a commutative algebra isomorphic to the polynomial algebra
$$ \begin{align*}\mathbb{C}[X_{1},X_{1}^{-1},\dots,X_{t},X_{t}^{-1},Z,Z^{-1}\mid Z^{s}=X_{1}\dots X_{t}],\end{align*} $$
where
$X_{i}$
is as before and
$Z=[(1/s,\dots ,1/s)]$
. Then we have an
$\mathbb {C}$
-algebra isomorphism
$$ \begin{align*}\widetilde{\mathcal{H}}(t,s,z)=\widetilde{\mathcal{A}}(t,s)\otimes_{\mathbb{C}}\mathcal{H}_{0}(t,z).\end{align*} $$
In particular,
$\mathcal {A}(t)$
is a subalgebra of
$\widetilde {\mathcal {A}}(t,s)$
of index s.
We define a canonical hermitian form
$\langle \cdot ,\cdot \rangle :\widetilde {\mathcal {H}}(t,s,z)\rightarrow \mathbb {C}$
by linearity, such that
$[w]\in \widetilde {W}_{s,t}^{\mathrm {aff}}$
forms an orthogonal basis, and moreover,
$$ \begin{align*}\langle[w],[w]\rangle=z^{l},\end{align*} $$
where the length l is defined as in (7.1). Restricting to
$\mathcal {H}(t,z)$
,
$\widetilde {\mathcal {A}}(t,s,z)$
and
$\widetilde {\mathcal {A}}(t)$
, we get the corresponding hermitian forms.
Remark 7.1. The affine Hecke algebras
$\mathcal {H}(t,z)$
and
$\widetilde {\mathcal {H}}(t,s,z)$
are indeed affine Hecke algebras related to a based root datum of type A (in the sense of [Reference Solleveld68, §1.3], for instance), where
$\mathcal {A}(t)$
(resp.
$\widetilde {\mathcal {A}}(t,s)$
) is the lattice part (i.e.,
$\mathbb {C}[X]$
in loc. cit.), and
$\mathcal {H}_{0}(t,z)$
is the finite part (i.e.,
$\mathcal {H}(W,q)$
in loc. cit.).
Finally, we define the induction functor
$$ \begin{align*}\operatorname{Ind}_{\mathcal{A}(t)}^{\mathcal{H}(t,z)}:\operatorname{Mod}(\mathcal{A}(t))\rightarrow\operatorname{Mod}(\mathcal{H}(t,z))\end{align*} $$
given by the tensor product
$(\mathcal {H}(t,z)\otimes _{\mathcal {A}(t)}\cdot )$
or the Hom-functor
$\operatorname {Hom}_{\mathcal {A}(t)}(\mathcal {H}(t,z),\cdot )$
, and the induction functor
$$ \begin{align*}\operatorname{Ind}_{\widetilde{\mathcal{A}}(t,s)}^{\widetilde{\mathcal{H}}(t,s,z)}:\operatorname{Mod}(\widetilde{\mathcal{A}}(t,s))\rightarrow\operatorname{Mod}(\widetilde{\mathcal{H}}(t,s,z))\end{align*} $$
given by the tensor product
$(\widetilde {\mathcal {H}}(t,s,z)\otimes _{\widetilde {\mathcal {A}}(t,s)}\cdot )$
or the Hom-functor
$\operatorname {Hom}_{\widetilde {\mathcal {A}}(t,s)}(\widetilde {\mathcal {H}}(t,s,z),\cdot )$
. In particular, they map finite dimensional modules to finite dimensional modules. Clearly, we have a commutative diagram:
Remark 7.2. In particular, since
$[\zeta ]$
is contained in the center of
$\widetilde {\mathcal {H}}(t,s,z)$
, it is easy to verify that the restriction of a finite dimensional representation
$\pi $
of
$\widetilde {\mathcal {H}}(t,s,z)$
to
$\mathcal {H}(t,z)$
is irreducible, if and only if
$\pi $
is irreducible.
7.2 Finite part of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
In this part, we study the subalgebra of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
arising from a cuspidal representation of a finite general linear group, where
$(\widetilde {J},\widetilde {\lambda })$
is a simple type of
$\widetilde {G}$
.
Fix a maximal open compact subgroup K of G that contains
$U(\mathfrak {a}_{\text {max}})$
and a splitting
$\boldsymbol {s}$
of K, such that our simple type is of the form
$\widetilde {\lambda }=\widetilde {\kappa }\otimes \widetilde {\rho }$
, where
$\widetilde {\kappa }$
is the pull-back of a
$\beta $
-extension,
$\widetilde {\rho }=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s}\varrho )$
with
$\varrho =\varrho _{0}\boxtimes \dots \boxtimes \varrho _{0}$
being a cuspidal representation of
$\mathcal {M}\cong U(\mathfrak {b})/U^{1}(\mathfrak {b})$
, and
$\varrho _{0}$
is a cuspidal representation of
$\operatorname {GL}_{m_{0}}(\boldsymbol {l})$
.
Let
$J'=U(\mathfrak {b})J_{\text {max}}^{1}$
, which is a subgroup of
$J_{\text {max}}$
. So we have
$J'/J_{\text {max}}^{1}\cong U(\mathfrak {b})/U^{1}(\mathfrak {b}_{\text {max}})\cong \mathcal {P}$
and
$J_{\text {max}}/J_{\text {max}}^{1}\cong U(\mathfrak {b}_{\text {max}})/U^{1}(\mathfrak {b}_{\text {max}})=\mathcal {G}$
. We may extend
$\varrho $
to an irreducible representation of
$\mathcal {P}$
, which we still denote by
$\varrho $
.
As in §5.4, we construct a
$\beta $
-extension
$\kappa _{\mathrm {max}}$
of
$J_{\text {max}}$
related to
$\kappa $
, and we let
$\widetilde {\kappa }_{\mathrm {max}}$
be its pull-back to
$\widetilde {J_{\text {max}}}$
. Let
$\widetilde {\rho }'=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J'}}(\epsilon \cdot \,_{s}\varrho )$
, which is a genuine irreducible representation of
$\widetilde {J'}$
. Finally, let
$\widetilde {\lambda }'=\widetilde {\kappa }_{\mathrm {max}}\lvert _{\widetilde {J'}}\otimes \widetilde {\rho }'$
, which is a genuine irreducible representation of
$\widetilde {J}'$
.
Lemma 7.3. We have
$\operatorname {ind}_{\widetilde {J'}}^{\widetilde {U(\mathfrak {b})}\widetilde {U^{1}(\mathfrak {a})}}\widetilde {\lambda }'\cong \operatorname {ind}_{\widetilde {J}}^{\widetilde {U(\mathfrak {b})}\widetilde {U^{1}(\mathfrak {a})}}\widetilde {\lambda }$
. Then we obtain a canonical isomorphism
$$ \begin{align} \mathcal{H}(\widetilde{G},\widetilde{\lambda}')\cong\mathcal{H}(\widetilde{G},\widetilde{\lambda}), \end{align} $$
mapping a function
$\phi '$
supported on
$\widetilde {J'}y\widetilde {J'}$
to a function
$\phi $
supported on
$\widetilde {J}y\widetilde {J}$
for any
$y\in B^\times $
.
Proof. We regard
$\widetilde {\rho }'$
(resp.
$\widetilde {\rho }$
) as a genuine representation of
$\widetilde {U(\mathfrak {b})}\widetilde {U^{1}(\mathfrak {a})}$
whose restriction to
$\,_{s}U^{1}(\mathfrak {a})$
is trivial. Then using (5.6), we have
$$ \begin{align*}\operatorname{ind}_{\widetilde{J'}}^{\widetilde{U(\mathfrak{b})}\widetilde{U^{1}(\mathfrak{a})}}\widetilde{\lambda}'\cong(\operatorname{ind}_{\widetilde{J'}}^{\widetilde{U(\mathfrak{b})}\widetilde{U^{1}(\mathfrak{a})}}\widetilde{\kappa}_{\mathrm{max}}\lvert_{\widetilde{J'}})\otimes\widetilde{\rho}'\cong(\operatorname{ind}_{\widetilde{J}}^{\widetilde{U(\mathfrak{b})}\widetilde{U^{1}(\mathfrak{a})}}\widetilde{\kappa})\otimes\widetilde{\rho}\cong\operatorname{ind}_{\widetilde{J}}^{\widetilde{U(\mathfrak{b})}\widetilde{U^{1}(\mathfrak{a})}}\widetilde{\lambda}.\end{align*} $$
The second statement follows from a similar argument as [Reference Bushnell and Kutzko19, Proposition 5.5.13].
We consider a subalgebra
$\mathcal {H}(\widetilde {J_{\text {max}}},\widetilde {\lambda }')$
of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda }')\cong \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
. We write
$\boldsymbol {q}_{0}=q^{m_{0}f}$
to simplify our notation, where f is the unramified degree of
$E/F$
. Indeed,
$\boldsymbol {q}_{0}$
is the cardinality of the field
$\boldsymbol {l}_{m_{0}}$
, where
$\boldsymbol {l}_{m_{0}}/\boldsymbol {l}$
is of degree
$m_{0}$
.
Proposition 7.4. We have
$$ \begin{align} \mathcal{H}_{0}(t,\boldsymbol{q}_{0})\cong\mathcal{H}(\mathcal{G},\varrho)\cong\mathcal{H}(\widetilde{U(\mathfrak{b}_{\text{max}})},\widetilde{\rho}'\lvert_{\widetilde{U(\mathfrak{b})}})\cong\mathcal{H}(\widetilde{J_{\text{max}}},\widetilde{\lambda}'). \end{align} $$
Moreover, let
$\varsigma \in \mathfrak {S}_{t}$
, let
$[\varsigma ]$
be the corresponding element in
$\mathcal {H}_{0}(t,\boldsymbol {q}_{0})$
, and let
$\phi _{\varsigma }\in \mathcal {H}(\widetilde {J_{\text {max}}},\widetilde {\lambda }')$
be the image of
$[\varsigma ]$
via the isomorphism (7.4). Then the support of
$\phi _{\varsigma }$
is
$\widetilde {J'}\mathcal {F}_{0}(\varsigma )\widetilde {J'}$
(cf. (6.7)).
Proof. The argument of [Reference Bushnell and Kutzko19, Proposition 5.6.4] works here without change.
Composing with (7.3), we get an embedding of algebras
$$ \begin{align} \Psi_{0}:\mathcal{H}_{0}(t,\boldsymbol{q}_{0})\hookrightarrow\mathcal{H}(\widetilde{G},\widetilde{\lambda}). \end{align} $$
Indeed,
$\Psi _{0}(\mathcal {H}_{0}(t,\boldsymbol {q}_{0}))$
is the subalgebra of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
consisting of functions supported on
$\widetilde {J}W_{0}(\mathfrak {b})\widetilde {J}$
. This is because
$J'\backslash J_{\text {max}}/J'\cong U^{0}(\mathfrak {b}) \backslash U^0(\mathfrak {b}_{\text {max}})/U^{0}(\mathfrak {b})$
, which is represented by elements in
$W_0(\mathfrak {b})$
.
7.3 Proof of Theorem 6.16
Let
$(\widetilde {J},\widetilde {\lambda })$
be a simple type of
$\widetilde {G}$
as above. We define the related pairs
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
and
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
as in §6.1. Then we have a natural isomorphism
$\mathcal {H}(\widetilde {G},\widetilde {\lambda }_{P})\cong \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
.
Let
$\Pi _{E}$
,
$\zeta _{E}$
,
$W_{0}=W(r_{0},m_{0},l_{0};t)$
and
$W_{0}'=W'(r_{0},m_{0},l_{0};t)$
be defined as in §6.3. We extend the isomorphism (6.7) to an isomorphism
$$ \begin{align} \mathcal{F}:\widetilde{W}_{t,s_{0}}^{\mathrm{aff}}\cong W_{0}' \end{align} $$
by imposing
$\Pi _{E}=\mathcal {F}(\Pi )$
and
$\zeta _{E}=\mathcal {F}(\zeta )$
. We refer to (6.10), (6.12) and (6.14) for the definition of
$s_{0}=s_{r_{0},l_{0}}$
.
The main goal is to extend
$\Psi _{0}$
to an embedding
$\widetilde {\mathcal {H}}(t,s_{0},\boldsymbol {q}_{0})\hookrightarrow \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
.
Theorem 7.5.
-
(1) There exists a nonzero element
$\phi _{\Pi }\in \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
supported on
$\widetilde {J}\Pi _{E}\widetilde {J}$
, which is unique up to a scalar. -
(2) There exists a nonzero element
$\phi _{\zeta }\in \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
supported on
$\widetilde {J}\zeta _{E}\widetilde {J}$
, unique up to a scalar in
$\mu _{s_{0}}$
, such that
$\phi _{\zeta }^{s_{0}}=\phi _{\Pi }^{t}$
. Such
$\phi _{\zeta }$
is central in
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
. -
(3) For any
$\phi _{\Pi }$
,
$\phi _{\zeta }$
as above, there exists a unique algebra homomorphism (7.7)
$$ \begin{align} \Psi:\widetilde{\mathcal{H}}(t,s_{0},\boldsymbol{q}_{0})\rightarrow\mathcal{H}(\widetilde{G},\widetilde{\lambda}), \end{align} $$
which extends
$\Psi _{0}$
and satisfies
$\Psi ([\Pi ])=\phi _{\Pi }$
and
$\Psi ([\zeta ])=\phi _{\zeta }$
.
Every
$\Psi $
as above is an embedding of algebras and preserves the support of functions, in the sense that, for
$w\in \widetilde {W}_{t,s_{0}}^{\mathrm {aff}} $
, the function
$\Psi ([w])$
is nonzero and supported on
$\widetilde {J}\mathcal {F}(w)\widetilde {J}$
. Thus, the image of
$\Psi $
consists of functions in
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
supported on
$\widetilde {J}W_{0}'\widetilde {J}$
.
Remark 7.6. By abuse of notation, it is convenient to regard
$\Psi $
as an embedding
$$ \begin{align*}\widetilde{\mathcal{H}}(t,s_{0},\boldsymbol{q}_{0})\hookrightarrow\mathcal{H}(\widetilde{G},\widetilde{\lambda}_{P}),\end{align*} $$
by composing the original
$\Psi $
with the isomorphism in Lemma 6.2.
Proof. The proof follows from [Reference Sécherre65, Théorème 4.6], which we shall sketch here. Since
$\Pi _{E}$
(resp.
$\zeta _{E}$
) intertwines
$\widetilde {\lambda }$
, using Corollary 6.5 the space of functions supported on
$\widetilde {J}\zeta _{E}\widetilde {J}$
(resp.
$\widetilde {J}\Pi _{E}\widetilde {J}$
) is one-dimensional. So up to a scalar in
$\mathbb {C}^{\times }$
, there exists a unique
$\phi _{\Pi }\in \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
supported on
$\widetilde {J}\Pi _{E}\widetilde {J}$
. Similarly, up to a scalar in
$\mu _{s_{0}}$
, there exists a unique
$\phi _{\zeta }\in \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
supported on
$\widetilde {J}\zeta _{E}\widetilde {J}$
, such that
$\phi _{\zeta }^{s_{0}}=\phi _{\Pi }^{t}$
. We need the following two lemmas:
Lemma 7.7 ([Reference Sécherre65, Lemma 4.12]).
For any
$w\in W(\mathfrak {b})$
, we have
$$ \begin{align*}JwJ\Pi_{E}J\cap W(\mathfrak{b})=w\Pi_{E}\quad\text{and}\quad J\Pi_{E}JwJ\cap W(\mathfrak{b})=\Pi_{E}w\end{align*} $$
and
$$ \begin{align*}JwJ\Pi_{E}^{-1}J\cap W(\mathfrak{b})=w\Pi_{E}^{-1}\quad\text{and}\quad J\Pi_{E}^{-1}JwJ\cap W(\mathfrak{b})=\Pi_{E}^{-1}w.\end{align*} $$
Lemma 7.8. For any
$w\in W(\mathfrak {b})$
, we have
$$ \begin{align*}JwJ\zeta_{E}J=Jw\zeta_{E}J=J\zeta_{E}wJ=J\zeta_{E}JwJ\end{align*} $$
and
$$ \begin{align*}JwJ\zeta_{E}^{-1}J=Jw\zeta_{E}^{-1}J=J\zeta_{E}^{-1}wJ=J\zeta_{E}^{-1}JwJ.\end{align*} $$
Proof. It follows easily from the fact that
$\zeta _{E}$
normalizes J and
$\zeta _{E}$
commutes with w.
As a corollary of the above two lemma, we have the following.
Corollary 7.9.
-
(1) For any
$w\in W_{0}$
and
$ f\in \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
supported on
$\widetilde {J}w\widetilde {J}$
, the functions
$\phi _{\Pi _{E}}\ast f$
,
$f\ast \phi _{\Pi _{E}}$
and
$\phi _{\zeta _{E}}\ast f=f\ast \phi _{\zeta _{E}}$
are supported on
$\widetilde {J}\Pi _{E}w\widetilde {J},\ \widetilde {J}w\Pi _{E}\widetilde {J},\ \widetilde {J}\zeta _{E}w\widetilde {J}$
, respectively. -
(2) The elements
$\phi _{\Pi _{E}}$
and
$\phi _{\zeta _{E}}$
are invertible in
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
.
Proof. The statement (1) follows from Proposition 6.13 and the above two lemmas.
For statement (2), we consider
$\phi _{\Pi _{E}}\ast \phi _{\Pi _{E}^{-1}}$
and
$\phi _{\zeta _{E}}\ast \phi _{\zeta _{E}^{-1}}$
. Using statement (1), both of them are supported on
$\widetilde {J}$
. Using Corollary 6.5, there exist complex numbers
$c_{1},c_{2}$
such that
$\phi _{\Pi _{E}}\ast \phi _{\Pi _{E}^{-1}}=c_{1}\cdot e$
and
$\phi _{\zeta _{E}}\ast \phi _{\zeta _{E}^{-1}}=c_{2}\cdot e$
, where e denotes the unit element in
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
. Then we may show that both
$c_{1}$
and
$c_{2}$
are nonzero following a similar argument to [Reference Sécherre65, Lemme 4.14]. So statement (2) is also proved.
Come back to the original proof. We define
$\Psi $
as in statement (3). We need to show that
$\Psi $
indeed extends to a homomorphism of algebras. It remains to show the following lemma, which follows from the same argument as [Reference Sécherre65, Lemme 4.15].
Lemma 7.10. We have
$\phi _{\Pi _{E}}\ast \Psi ([\varsigma _{i}])\ast \phi _{\Pi _{E}}^{-1}=\Psi ([\varsigma _{i-1}])$
for
$i=2,\dots ,t-1$
and
$\phi _{\Pi _{E}}^{2}\ast \Psi ([\varsigma _{1}])\ast \phi _{\Pi _{E}}^{-2}=\Psi ([\varsigma _{t-1}])$
.
Finally, we need to show that
$\Psi $
is an embedding and preserves the support. We only need to show that for
$w\in \widetilde {W}_{t,s_{0}}^{\mathrm {aff}} $
, the function
$\Psi ([w])$
is nonzero and supported on
$\widetilde {J}\mathcal {F}(w)\widetilde {J}$
. Then the injectivity follows from Corollary 6.5. Using [Reference Sécherre65, Proposition 4.16], whose statement and proof can be transplanted here without change, the function
$\Psi ([w'])$
is nonzero and supported on
$\widetilde {J}\mathcal {F}(w')\widetilde {J}$
for
$w'\in W_{t}^{\mathrm {aff}}$
. Since every
$w\in \widetilde {W}_{t,s_{0}}^{\mathrm {aff}}$
can be written as
$\zeta ^{b}w'$
with
$b\in \{0,1,\dots ,s-1\}$
and
$w'\in W_{t}^{\mathrm {aff}}$
, using Corollary 7.9, the function
$\Psi ([w])=\phi _{\zeta }^{b}\ast \Psi ([w'])$
is nonzero and supported on
$\widetilde {J}\mathcal {F}(w)\widetilde {J}$
. So we finish the proof of Theorem 7.5.
Remark 7.11. Theorem 7.5 dates back to [Reference Bushnell and Kutzko19, Theorem 5.6.6], which unfortunately cannot be adapted here. Indeed, in loc. cit. they used the fact that
$\Pi _{E}$
normalizes
$\widetilde {\lambda }$
, which is not true here if
$n_{0}=n_{r_{0},l_{0}}>1$
.
As a corollary of Proposition 6.14 and Theorem 7.5, we have the following.
Corollary 7.12. When
$\widetilde {G}$
is either a KP-cover or the S-cover, (7.7) is an isomorphism of algebras
$$ \begin{align*}\Psi:\widetilde{\mathcal{H}}(t,s_{0},\boldsymbol{q}_{0})\cong\mathcal{H}(\widetilde{G},\widetilde{\lambda}).\end{align*} $$
The following corollary follows from the same proof as [Reference Bushnell and Kutzko19, Corollary 5.6.17].
Corollary 7.13. Under the assumption of Corollary 7.12, we may choose
$\Psi $
such that it is an isometry with respect to the hermitian form of
$\widetilde {\mathcal {H}}(t,s_{0},\boldsymbol {q}_{0})$
and
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
.
More precisely, choose
$\Psi $
such that
$\Psi ([\Pi ])\ast \overline {\Psi ([\Pi ])}=1$
and
$\Psi ([\zeta ])\ast \overline {\Psi ([\zeta ])}=1$
. Then for the canonical hermitian form
$\langle \cdot ,\cdot \rangle $
of
$\widetilde {\mathcal {H}}(t,s_{0},\boldsymbol {q}_{0})$
and the hermitian form
$\operatorname {dim}(\widetilde {\lambda })^{-1}\cdot h_{G}$
of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
, we have
$$ \begin{align*}\operatorname{dim}(\widetilde{\lambda})^{-1}\cdot h_{G}(\Psi(x),\Psi(y))=\langle x,y\rangle,\quad x,y\in\widetilde{\mathcal{H}}(t,s_{0},\boldsymbol{q}_{0}).\end{align*} $$
Finally, we are able to prove Theorem 6.16.
Proof of Theorem 6.16.
To show that
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
is a covering pair of
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
, it remains to verify the condition (3) in §3.4.
Indeed, given a parabolic subgroup
$P'$
of G with a Levi factor M, we may choose an element
$z\in Z(\widetilde {M})\cap \widetilde {J} W_{0}'\widetilde {J}$
that is strongly
$(\widetilde {P'},\widetilde {J})$
-positive. For instance, if
$P'$
denotes the standard upper triangular parabolic group with respect to the E-basis of
$V_{E}$
we fixed before, the element
$$ \begin{align*}z=\boldsymbol{s}(\operatorname{diag}(\varpi_{F}^{ns_{1}}I_{r_{0}},\varpi_{F}^{ns_{2}}I_{r_{0}},\dots,\varpi_{F}^{ns_{t}}I_{r_{0}}))\end{align*} $$
satisfies the conditions we want for any sequence of integers
$s_{1}>s_{2}>\dots >s_{t}$
. Then, using Lemma 6.2 and Theorem 7.5, there exists an invertible element
$\phi _{z}$
in
$\mathcal {H}(\widetilde {G},\widetilde {\lambda }_{P})$
supported on
$\widetilde {J_{P}}z\widetilde {J_{P}}$
, verifying the condition (3).
So
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
is a covering pair of
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
. The rest follows from Theorem 3.3, Theorem 6.15 and the fact
$\operatorname {ind}_{\widetilde {J}_{P}}^{\widetilde {J}}\widetilde {\lambda }_{P}\cong \widetilde {\lambda }$
.
7.4 Lattice part of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
We also study another subalgebra of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
. Since
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
is a covering pair of
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
, we have an embedding
$$ \begin{align*}t_{P}:\mathcal{H}(\widetilde{M},\widetilde{\lambda}_{M})\rightarrow\mathcal{H}(\widetilde{G},\widetilde{\lambda}_{P}).\end{align*} $$
Composing with the isomorphism
$\mathcal {H}(\widetilde {G},\widetilde {\lambda }_{P})\cong \mathcal {H}(\widetilde {G},\widetilde {\lambda })$
given by Lemma 6.2, we get an embedding
$$ \begin{align*}\mathcal{H}(\widetilde{M},\widetilde{\lambda}_{M})\rightarrow\mathcal{H}(\widetilde{G},\widetilde{\lambda}),\end{align*} $$
which we still denote by
$t_{P}$
. We first study
$\mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M})$
.
Lemma 7.14.
$\mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M})$
is isomorphic to the commutative group algebra
$\mathbb {C}[T_{0}]$
.
Proof. By Proposition 6.9, we have
$N_{M}(\widetilde {\lambda })=I_{M}(\widetilde {\lambda })=T_{0}J_{M}$
. Since
$T_{0}$
is abelian and normalizes
$J_{M}$
, it is easy to verify that
$\mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M})$
is commutative with respect to the convolution. Since
$T_{0}$
is a free abelian group of rank t, we may choose free generators
$b_{1}=I_{r},b_{2},\dots ,b_{t}\in T_{0}$
. Choose functions
$\phi _{b_{1}},\dots ,\phi _{b_{t}}\in \mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M})$
such that
$\phi _{b_{i}}$
is supported on
$b_{i}\widetilde {J_{M}}$
for each i, and
$\phi _{b_{1}}\ast \phi _{b_{1}}=\phi _{b_{1}}$
. Then we get an isomorphism of algebras
$\mathbb {C}[T_{0}]\rightarrow \mathcal {H}(\widetilde {M},\widetilde {\lambda })$
which maps
$b_{i}$
to
$\phi _{b_{i}}$
.
Remark 7.15. If
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })_{\widetilde {M}}$
is a subalgebra of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
(cf. §3.4), which is true for KP-covers and the S-cover (cf. Corollary 7.12), then the map
$t_{P}$
preserves the support. Thus, the subalgebra
$t_{P}(\mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M}))$
of
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
consists of functions in
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
supported on
$\widetilde {J}T_{0}\widetilde {J}$
.
We expect the following conjecture in general.
Conjecture 7.16.
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })$
is an affine Hecke algebra of type A. More precisely, we have an isomorphism of algebras
$$ \begin{align*}t_{P}(\mathcal{H}(\widetilde{M},\widetilde{\lambda}_{M}))\otimes_{\mathbb{C}}\Psi_{0}(\mathcal{H}_{0}(t,\boldsymbol{q}_{0}))\cong \mathcal{H}(\widetilde{G},\widetilde{\lambda})\end{align*} $$
where
$t_{P}(\mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M}))$
corresponds to the lattice part and
$\Psi _{0}(\mathcal {H}_{0}(t,\boldsymbol {q}_{0}))$
corresponds to the finite part of an affine Hecke algebra of type A, and the product structure on the left-hand side is defined accordingly.
When
$\widetilde {G}$
is either a KP-cover or the S-cover, by Corollary 7.12, the conjecture is verified.
Remark 7.17. It is expected that all the results listed in Section 7 hold for twisted simple types as well with minor changes. However, it seems that our proof above cannot be adapted to this case directly.
8 Maximal simple types
In this section, we further study maximal simple types and state our main theorem of constructing cuspidal representations of
$\widetilde {G}$
, as well as its Levi subgroup
$\widetilde {M}$
.
8.1 Maximal simple types of
$\widetilde {G}$
We keep the notation of Section 6. In particular, we call the hereditary order
$\mathfrak {a}$
in A, or the related simple stratum
$[\mathfrak {a},u,0,\beta ]$
, maximal if the corresponding hereditary order
$\mathfrak {b}=B\cap \mathfrak {a}$
is a maximal hereditary order in B with respect to the containment.
Fix a strict maximal simple stratum
$[\mathfrak {a},u,0,\beta ]$
as before. We construct groups
$H^{1}$
,
$J^{1}$
, J and related representations
$\theta $
,
$\eta $
,
$\kappa $
. In this case,
$$ \begin{align*}J/J^{1}\cong U(\mathfrak{b})/U^{1}(\mathfrak{b})\cong\mathcal{G}=\operatorname{GL}_{m}(\boldsymbol{l}),\end{align*} $$
where
$\boldsymbol {l}$
denotes the residue field of E, and
$d=[E:F]$
and
$r=md$
. Let
$\widetilde {\kappa }$
be the pull-back of
$\kappa $
as an irreducible representation of
$\widetilde {J}$
. Also, we fix a maximal open compact subgroup K of G that contains
$U(\mathfrak {a})$
and a splitting
$\boldsymbol {s}$
of K. Let
$\varrho $
be a cuspidal representation of
$\mathcal {G}$
. Then the inflation
$\widetilde {\rho }=\operatorname {Inf}_{\widetilde {\mathcal {G}}}^{\widetilde {J}}(\epsilon \cdot \,_{s}\varrho )$
is a genuine irreducible representation of
$\widetilde {J}$
. Let
$\widetilde {\lambda }=\widetilde {\kappa }\otimes \widetilde {\rho }$
.
Definition 8.1. A maximal simple type of
$\widetilde {G}$
consists of a pair
$(\widetilde {J},\widetilde {\lambda })$
with
$\widetilde {J}$
and
$\widetilde {\lambda }$
defined as above. Or equivalently, a maximal simple type is a simple type related to a maximal simple stratum.
We write
$\boldsymbol {J}=\boldsymbol {J}(\beta ,\mathfrak {a}):=E^{\times }J$
as a subgroup of G.
Definition 8.2. An extended maximal simple type (EMST for short) extending
$(\widetilde {J},\widetilde {\lambda })$
consists of a pair
$(\widetilde {\boldsymbol {J}},\widetilde {\boldsymbol {\lambda }})$
, where
$\widetilde {\boldsymbol {J}}$
is the pull-back of
$\boldsymbol {J}$
as above, and
$\widetilde {\boldsymbol {\lambda }}$
is a genuine irreducible representation of
$\widetilde {\boldsymbol {J}}$
whose restriction to
$\widetilde {J}$
contains
$\widetilde {\lambda }$
.
We list several facts that can be easily deduced from Lemma 3.2 and the argument of Theorem 6.15.
Proposition 8.3.
-
(1) An EMST
$(\widetilde {\boldsymbol {J}},\widetilde {\boldsymbol {\lambda }})$
exists and can be constructed as in Theorem 6.15. -
(2) The normalizer of
$\widetilde {\boldsymbol {\lambda }}$
in G is
$\boldsymbol {J}$
. -
(3) Any two simple types
$\widetilde {\lambda }$
and
$\widetilde {\lambda }'$
contained in
$\widetilde {\boldsymbol {\lambda }}\lvert _{\widetilde {J}}$
are conjugate by
$\boldsymbol {J}$
. -
(4) The compact induction
$\operatorname {ind}_{\widetilde {\boldsymbol {J}}}^{\widetilde {G}}\widetilde {\boldsymbol {\lambda }}$
is a genuine cuspidal representation of
$\widetilde {G}$
.
We state our main theorem for genuine cuspidal representations of
$\widetilde {G}$
.
Theorem 8.4.
-
(1) Given an EMST of
$\widetilde {G}$
, the compact induction
$\widetilde {\pi }=\operatorname {ind}_{\widetilde {\boldsymbol {J}}}^{\widetilde {G}}\widetilde {\boldsymbol {\lambda }}$
is a genuine cuspidal representation of
$\widetilde {G}$
. -
(2) Every genuine cuspidal representation of
$\widetilde {G}$
is constructed as in (1). -
(3) Two EMSTs of
$\widetilde {G}$
are intertwined if and only if they are conjugate by G. So the EMST constructing
$\widetilde {\pi }$
is unique up to G-conjugacy.
We have proved statement (1). Statement (2) will be done in Section 10. Now we prove statement (3).
Given two maximal simple types
$(\widetilde {J},\widetilde {\lambda })$
and
$(\widetilde {J}',\widetilde {\lambda }')$
of
$\widetilde {G}$
and two corresponding EMSTs
$(\widetilde {\boldsymbol {J}},\widetilde {\boldsymbol {\lambda }})$
and
$(\widetilde {\boldsymbol {J}}',\widetilde {\boldsymbol {\lambda }}')$
, we need to show that
$\widetilde {\boldsymbol {\lambda }}$
and
$\widetilde {\boldsymbol {\lambda }}'$
are conjugate by G if they are intertwined. Taking the restriction, we deduce that
$\widetilde {\lambda }$
and
$\widetilde {\lambda }'$
are also intertwined. Thus, by Theorem 6.18, there exists
$g\in G$
such that
$J'=J^{g}$
,
$\boldsymbol {J}'=\boldsymbol {J}^{g}$
and
$[\widetilde {\lambda }']=[\widetilde {\lambda }^{g}]$
. In the maximal case, all the simple types in the class
$[\widetilde {\lambda }]$
can be realized by conjugation of elements in
$E^{\times }\subset \boldsymbol {J}$
, so we may further assume that
$\widetilde {\lambda '}=\widetilde {\lambda }^{g}$
.
Suppose
$h\in G$
intertwines
$\widetilde {\boldsymbol {\lambda }}'$
and
$\widetilde {\boldsymbol {\lambda }}^{g}$
. Then there exists
$h'\in \boldsymbol {J}'$
, such that h intertwines
$\widetilde {\lambda }^{\prime h'}$
and
$\widetilde {\lambda }^{g}=\widetilde {\lambda }'$
. Using Corollary 6.19 and the fact that
$W(\mathfrak {b})=\langle \varpi _{E}\rangle $
in the maximal case, we have
$h\in \boldsymbol {J}'$
. Thus,
$$ \begin{align*}0\neq\operatorname{Hom}_{\widetilde{\boldsymbol{J}}^{\prime h}\cap\widetilde{\boldsymbol{J}}'}(\widetilde{\boldsymbol{\lambda}}^{\prime h},\widetilde{\boldsymbol{\lambda}}^{g})=\operatorname{Hom}_{\widetilde{\boldsymbol{J}}'}(\widetilde{\boldsymbol{\lambda}}',\widetilde{\boldsymbol{\lambda}}^{g}),\end{align*} $$
implying that
$\widetilde {\boldsymbol {\lambda }}'\cong \widetilde {\boldsymbol {\lambda }}^{g}$
. So statement (3) is proved.
Summing up Theorem 6.15, Theorem 6.18 and Theorem 8.4,
Corollary 8.5. We have a bijection between the set of G-conjugacy classes of weak equivalence classes of maximal simple types
$(\widetilde {J},\widetilde {\lambda })$
and the set of cuspidal inertial equivalence classes
$\mathfrak {s}$
of
$\widetilde {G}$
, such that
$(\widetilde {J},\widetilde {\lambda })$
is an
$\mathfrak {s}$
-type.
8.2 Maximal simple types of
$\widetilde {M}$
In this part, let
$M=G_{r_{1}}\times \dots \times G_{r_{t}}$
be a Levi subgroup of G.
Definition 8.6. A maximal simple type of
$\widetilde {M}$
consists of a pair
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
, such that
$J_{M}=J_{1}\times \dots \times J_{t}$
and
$\widetilde {\lambda }_{M}=\widetilde {\lambda }_{1}\boxtimes \dots \boxtimes \widetilde {\lambda }_{t}$
, where
$(\widetilde {J_{i}},\widetilde {\lambda _{i}})$
is a maximal simple type of
$\widetilde {G_{r_{i}}}$
for
$i=1,\dots ,t$
.
We remark that since
$\operatorname {det}(J_{i})\subset \mathfrak {o}_{F}^{\times }$
for each i, the group
$J=J_{1}\times \dots \times J_{t}$
is block compatible, so the tensor product
$\widetilde {\lambda }_{1}\boxtimes \dots \boxtimes \widetilde {\lambda }_{t}$
makes sense.
Also, as already been explained in the last paragraph of §6.1, those
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
in §6.1 consist of all the maximal simple types of
$\widetilde {M}$
in the homogeneous case (saying that the corresponding simple characters
$\theta _{i}$
of
$\widetilde {\lambda }_{i}$
are in the same endo-class).
Let
$\boldsymbol {J}_{i}=E_{i}^{\times }J_{i}$
in
$G_{r_{i}}$
for each i and let
$\boldsymbol {J}_{M}=\boldsymbol {J}_{1}\times \dots \times \boldsymbol {J}_{t}$
which contains
$J_{M}$
. Here, each
$E_{i}=F[\beta _{i}]$
is the field related to the stratum
$[\mathfrak {a}_{i},u_{i},0,\beta _{i}]$
in constructing the simple type
$\widetilde {\lambda }_{i}$
.
Definition 8.7. An extended maximal simple type (EMST for short) extending
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
is a pair
$(\widetilde {\boldsymbol {J}_{M}},\widetilde {\boldsymbol {\lambda }}_{M})$
, where
$\widetilde {\boldsymbol {\lambda }}_{M}$
is an irreducible representation of
$\widetilde {\boldsymbol {J}_{M}}$
whose restriction to
$\widetilde {J_{M}}$
contains
$\widetilde {\lambda }_{M}$
.
Proposition 8.8. For a maximal simple type
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
of
$\widetilde {M}$
, we have
$I_{M}(\widetilde {\lambda }_{M})=N_{M}(\widetilde {\lambda }_{M})$
, which is contained in
$\boldsymbol {J}_{M}$
. More generally, given two maximal simple types
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
and
$(\widetilde {J_{M}},\widetilde {\lambda }_{M}')$
of
$\widetilde {M}$
, if
$g\in M$
intertwines
$\widetilde {\lambda }_M$
and
$\widetilde {\lambda }_{M}'$
, then g is in
$\boldsymbol {J}_M$
and
$\widetilde {\lambda }_{M}'\cong \widetilde {\lambda }_{M}^{g}$
.
Proof. We need the following lemma, whose proof follows directly from the formula (4.7).
Lemma 8.9. For
$\widetilde {\lambda }_{M}=\widetilde {\lambda }_{1}\boxtimes \dots \boxtimes \widetilde {\lambda }_{t}$
and
$g=\operatorname {diag}(g_{1},\dots ,g_{t})\in M$
, there exists a character
$\chi =\chi _{1}\boxtimes \dots \boxtimes \chi _{t}$
of
$J_{M}=J_{1}\times \dots \times J_{t}$
of order dividing n, which depends on g but is independent of
$\widetilde {\lambda }_{M}$
, such that
$\widetilde {\lambda }_{M}^{g}\cong (\widetilde {\lambda }_{1}\chi _{1})^{g_{1}}\boxtimes \dots \boxtimes (\widetilde {\lambda }_{t}\chi _{t})^{g_{t}}$
as representations of
$\widetilde {J_{M}^{g}}$
.
We only need to prove the second stronger statement. Write
$\widetilde {\lambda }_M'=\widetilde {\lambda }_{1}'\boxtimes \dots \boxtimes \widetilde {\lambda }_{t}'$
, where
$(\widetilde {J_i},\widetilde {\lambda }_{i}')$
is a maximal simple type of
$\widetilde {G_{r_{i}}}$
. Assume that
$g=\operatorname {diag}(g_{1},\dots ,g_{t})\in M$
intertwines
$\widetilde {\lambda }_M$
and
$\widetilde {\lambda }_{M}'$
. Using the above lemma, for each i, we have
$$ \begin{align*}\operatorname{Hom}_{\widetilde{J_{i}^{g_{i}}}\cap\widetilde{J_{i}}}((\widetilde{\lambda}_{i}\chi_{i})^{g_{i}},\widetilde{\lambda}_{i}')\neq 0,\end{align*} $$
and thus by Corollary 6.19, we have
$g_{i}\in \boldsymbol {J}_{i}$
and
$g\in \boldsymbol {J}_M$
. Finally, since g normalizes
$J_{M}$
, we have
$\widetilde {\lambda }_{M}'\cong \widetilde {\lambda }_{M}^{g}$
.
The following proposition is parallel to Proposition 8.3, with a similar proof. We only need to use Proposition 8.8 to replace Proposition 6.9 in the argument of Theorem 6.15.
Proposition 8.10.
-
(1) An EMST
$(\widetilde {\boldsymbol {J}_{M}},\widetilde {\boldsymbol {\lambda }}_{M})$
exists and can be constructed as in Theorem 6.15. -
(2) The normalizer of
$\widetilde {\boldsymbol {\lambda }}_{M}$
in M is
$\boldsymbol {J}_{M}$
. -
(3) Any two simple types
$\widetilde {\lambda }_{M}$
and
$\widetilde {\lambda }_{M}'$
contained in
$\widetilde {\boldsymbol {\lambda }}_{M}\lvert _{\widetilde {J}_{M}}$
are conjugate by
$\boldsymbol {J}_{M}$
. -
(4) The compact induction
$\operatorname {ind}_{\widetilde {\boldsymbol {J}_{M}}}^{\widetilde {M}}\widetilde {\boldsymbol {\lambda }}_{M}$
is a genuine cuspidal representation of
$\widetilde {M}$
.
We state the corresponding theorem for cuspidal representations of
$\widetilde {M}$
. The proof relies on Theorem 8.4.
Theorem 8.11.
-
(1) Given an EMST of
$\widetilde {M}$
, the compact induction
$\widetilde {\pi }=\operatorname {ind}_{\widetilde {\boldsymbol {J}_{M}}}^{\widetilde {M}}\widetilde {\boldsymbol {\lambda }}_{M}$
is a genuine cuspidal representation of
$\widetilde {M}$
. -
(2) Every genuine cuspidal representation of
$\widetilde {M}$
contains a simple type
$\widetilde {\lambda }_{M}$
, and thus is constructed as in (1). -
(3) Two EMSTs of
$\widetilde {M}$
are intertwined if and only if they are conjugate by M. So the EMST constructing
$\widetilde{\pi} $
is unique up to M-conjugacy.
Proof. The statement (1) has been verified.
For statement (2), let
$\widetilde {\pi }$
be a genuine cuspidal representation of
$\widetilde {M}$
. Let
$M_{r_{1},\dots ,r_{t}}^{(n)}:=G_{r_{1}}^{(n)}\times \dots \times G_{r_{t}}^{(n)}$
, which is a block compatible subgroup of M of finite index. Let
$\widetilde {\tau }$
be an irreducible subrepresentation of the semi-simple representation
$\widetilde {\pi }\lvert _{\boldsymbol {p}^{-1}(M_{r_{1},\dots ,r_{t}}^{(n)})}$
. Since
$M_{r_{1},\dots ,r_{t}}^{(n)}$
is block compatible,
$\widetilde {\tau }$
can be written as a tensor product
$$ \begin{align*}\widetilde{\tau}_{1}\boxtimes\dots\boxtimes\widetilde{\tau}_{t}\end{align*} $$
with
$\widetilde {\tau }_{i}$
a genuine irreducible representation of
$\widetilde {G_{r_{i}}^{(n)}}$
. For each i, we take an irreducible subrepresentation
$\widetilde {\pi }_{i}$
of the induction
$\operatorname {Ind}_{\widetilde {G_{r_{i}}^{(n)}}}^{\widetilde {G_{r_{i}}}}\widetilde {\tau }_{i}$
. Then by Definition 3.1.(3),
$\widetilde {\pi }_{i}$
is a genuine cuspidal representation of
$\widetilde {G_{r_{i}}}$
. Using Theorem 8.4.(2), for each i, we may choose a maximal simple type
$\widetilde {\lambda }_{i}$
of
$\widetilde {G_{r_{i}}}$
contained in
$\widetilde {\pi }_{i}$
.
Using Frobenius reciprocity and the Mackey formula, we may show that
$\widetilde {\lambda }_{M}':=\widetilde {\lambda }_{1}\boxtimes \dots \boxtimes \widetilde {\lambda }_{t}$
is contained in the semi-simple representation
$\operatorname {Ind}_{\boldsymbol {p}^{-1}(M_{r_{1},\dots ,r_{t}}^{(n)})}^{\widetilde {M}}\widetilde {\tau }$
. More precisely, we have
$$ \begin{align*} \begin{aligned} 0\neq &\operatorname{Hom}_{\widetilde{J_{1}}}(\operatorname{Ind}_{\widetilde{G_{r_{1}}^{(n)}}}^{\widetilde{G_{r_{1}}}}\widetilde{\tau}_{1},\widetilde{\lambda}_{1})\times\dots\times\operatorname{Hom}_{\widetilde{J_{t}}}(\operatorname{Ind}_{\widetilde{G_{r_{t}}^{(n)}}}^{\widetilde{G_{r_{t}}}}\widetilde{\tau}_{t},\widetilde{\lambda}_{t})\\ \cong& \operatorname{Hom}_{\widetilde{J_{1}}\cap\widetilde{G_{r_{1}}^{(n)}}}(\widetilde{\tau}_{1},\widetilde{\lambda}_{1})\times\dots\times\operatorname{Hom}_{\widetilde{J_{t}}\cap\widetilde{G_{r_{t}}^{(n)}}}(\widetilde{\tau}_{t},\widetilde{\lambda}_{t})\\ \cong&\operatorname{Hom}_{\widetilde{J_{M}}\cap \boldsymbol{p}^{-1}(M_{r_{1},\dots,r_{t}}^{(n)})}(\widetilde{\tau}_{1}\boxtimes\dots\boxtimes\widetilde{\tau}_{t},\widetilde{\lambda}_{M}')\quad \\ & \quad (\text{Since}\ J_M\ \text{and}\ M_{r_{1},\dots,r_{t}}^{(n)}\ \text{are block compatible})\\ \cong&\operatorname{Hom}_{\widetilde{J_{M}}}(\operatorname{Ind}_{\widetilde{J_{M}}\cap \boldsymbol{p}^{-1}(M_{r_{1},\dots,r_{t}}^{(n)})}^{\widetilde{J_M}}(\widetilde{\tau}\lvert_{\widetilde{J_{M}}\cap \boldsymbol{p}^{-1}(M_{r_{1},\dots,r_{t}}^{(n)})}),\widetilde{\lambda}_{M}')\\ \subset&\operatorname{Hom}_{\widetilde{J_{M}}}(\operatorname{Ind}_{\boldsymbol{p}^{-1}(M_{r_{1},\dots,r_{t}}^{(n)})}^{\widetilde{M}}\widetilde{\tau},\widetilde{\lambda}_{M}')\quad (\text{By the Mackey formula}).\\ \end{aligned} \end{align*} $$
Using [Reference Gelbart and Knapp31, Lemma 2.1], there exists an irreducible subrepresentation
$\widetilde {\pi }'$
of
$\operatorname {Ind}_{\boldsymbol {p}^{-1}(M_{r_{1},\dots ,r_{t}}^{(n)})}^{\widetilde {M}}\widetilde {\tau }$
, such that
$\widetilde {\pi }'$
contains
$\widetilde {\lambda }_{M}'$
, and moreover, there exists a character
$\chi $
of
$M/M_{r_{1},\dots ,r_{t}}^{(n)}$
such that
$\widetilde {\pi }\cong \widetilde {\pi }'\chi $
. Write
$\chi =\chi _{1}\boxtimes \dots \boxtimes \chi _{t}$
with
$\chi _{i}$
being a character of
$G_{r_{i}}/G_{r_{i}}^{(n)}$
for each i. Then
$\widetilde {\pi }$
contains
$\widetilde {\lambda }_M:=\widetilde {\lambda }_{M}'\cdot \chi \lvert _{J_{M}}=\widetilde {\lambda }_{1}\cdot \chi _{1}\lvert _{J_{1}}\boxtimes \dots \boxtimes \widetilde {\lambda }_{t}\cdot \chi _{t}\lvert _{J_{t}}$
, which is a maximal simple type of
$\widetilde {M}$
.
Now we may choose an irreducible representation
$\widetilde {\boldsymbol {\lambda }}_{M}$
of
$\widetilde {\boldsymbol {J}_{M}}$
containing
$\widetilde {\lambda }_{M}$
and contained in
$\widetilde {\pi }$
. Then
$(\widetilde {\boldsymbol {J}_{M}},\widetilde {\boldsymbol {\lambda }}_{M})$
is an EMST that compactly induces
$\widetilde {\pi }$
.
The proof of statement (3) is similar to that of Theorem 8.4.(3), which we briefly explain here. Let
$(\widetilde {\boldsymbol {J}_{M}},\widetilde {\boldsymbol {\lambda }}_{M})$
and
$(\widetilde {\boldsymbol {J}_{M}'},\widetilde {\boldsymbol {\lambda }}_{M}')$
be two intertwined EMSTs related to maximal simple types
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
and
$(\widetilde {J_{M}'},\widetilde {\lambda }_{M}')$
, respectively. Then
$\widetilde {\lambda }_{M}$
and
$\widetilde {\lambda }_{M}'$
are also intertwined.
We claim that
$\widetilde {\lambda }_{M}$
and
$\widetilde {\lambda }_{M}'$
are conjugate by M. Using Lemma 8.9, there exists a character
$\chi =\chi _{1}\boxtimes \dots \boxtimes \chi _{t}$
of
$J_{M}$
, such that
$\widetilde {\lambda }_{i}\chi _{i}$
and
$\widetilde {\lambda }_{i}'$
are intertwined for each i. Using Theorem 6.18,
$[\widetilde {\lambda }_{i}\chi _{i}]$
and
$[\widetilde {\lambda }_{i}']$
are conjugate by
$G_{r_{i}}$
for each i. So up to replacing
$\widetilde {\lambda }_{M}$
by its M-conjugation, we may assume that
$J_{M}=J_{M}'$
, and there exists a character
$\chi '=\chi _{1}'\boxtimes \dots \boxtimes \chi _{t}'$
of
$J_{M}=J_{1}\times \dots \times J_{t}$
of order dividing n, such that
$\widetilde {\lambda }_{M}'\cong \widetilde {\lambda }_{M}\chi '$
. Assume
$g=\operatorname {diag}(g_{1},\dots ,g_{t})\in M$
intertwines
$\widetilde {\lambda }_{M}$
and
$\widetilde {\lambda }_{M}'$
. Using Proposition 8.8, we have
$g\in \boldsymbol {J}_M$
and
$\widetilde {\lambda }_{M}'\cong \widetilde {\lambda }_{M}^g$
.
Finally, we show that
$(\widetilde {\boldsymbol {J}_{M}},\widetilde {\boldsymbol {\lambda }}_{M})$
and
$(\widetilde {\boldsymbol {J}_{M}'},\widetilde {\boldsymbol {\lambda }}_{M}')$
are also M-conjugate. Up to an M-conjugation, we may assume that
$\boldsymbol {J}_{M}=\boldsymbol {J}_{M}'$
,
$J_{M}=J_{M}'$
and
$\widetilde {\lambda }_{M}=\widetilde {\lambda }_{M}'$
. So if an element
$g\in M$
intertwines
$\widetilde {\boldsymbol {\lambda }}_{M}$
and
$\widetilde {\boldsymbol {\lambda }}_{M}'$
, then it intertwines
$\widetilde {\lambda }_{M}$
and
$\widetilde {\lambda }_{M}^{h}$
for a certain
$h\in \boldsymbol {J}_{M}$
. Thus, by Proposition 8.8, g lies in
$\boldsymbol {J}_{M}$
. This shows that
$\widetilde {\boldsymbol {\lambda }}_{M}^{g}$
and
$\widetilde {\boldsymbol {\lambda }}_{M}'$
are isomorphic.
9 Results for a KP-cover or the S-cover
In this section, we assume
$\widetilde {G}$
to be either a KP-cover or the S-cover.
Our main goal here is to prove Proposition 9.7, Proposition 9.10 and Proposition 9.12. These results are subject to our assumption on
$\widetilde {G}$
.
9.1 Metaplectic tensor product
One of the features that makes a KP-cover or the S-cover special is that, any genuine irreducible representation of a Levi subgroup of
$\widetilde {G}$
is ‘almost’ the tensor product of certain genuine irreducible representations of each block.
More precisely, let
$M=G_{r_{1}}\times \dots \times G_{r_{t}}$
be a Levi subgroup of
$G=\operatorname {GL}_{r}(F)$
, where
$r=r_{1}+\dots +r_{t}$
and each
$G_{r_{i}}$
is a subgroup of G isomorphic to
$\operatorname {GL}_{r_{i}}(F)$
. We write
$\widetilde {M}$
and
$\widetilde {G_{r_{i}}}$
for the preimage of M and
$G_{r_{i}}$
in
$\widetilde {G}$
.
If
$\widetilde {G}$
is the S-cover, then the above decomposition of M is block compatible. Thus, we may define the multi-multiplicative multi-exact tensor product functor
$$ \begin{align*}\boxtimes_{i=1}^{t}:\operatorname{Rep}_{\epsilon}(\widetilde{G_{r_{1}}})\times\dots\times\operatorname{Rep}_{\epsilon}(\widetilde{G_{r_{t}}})\rightarrow\operatorname{Rep}_{\epsilon}(\widetilde{M}),\end{align*} $$
which induces a bijection for irreducible representations
$$ \begin{align*}\boxtimes_{i=1}^{t}:\operatorname{Irr}_{\epsilon}(\widetilde{G_{r_{1}}})\times\dots\times\operatorname{Irr}_{\epsilon}(\widetilde{G_{r_{t}}})\rightarrow\operatorname{Irr}_{\epsilon}(\widetilde{M}).\end{align*} $$
To unify our terminology, we call the above functor
$\boxtimes _{i=1}^{t}$
the metaplectic tensor product functor.
If
$\widetilde {G}$
is a KP-cover, things become a bit trickier since M is not necessarily block compatible. Still, we are able to define the metaplectic tensor product as in [Reference Kaplan, Lapid and Zou46]. For each i, we choose a genuine character
$\widetilde {\omega }_{i}$
of
$Z(\widetilde {G_{r_{i}}})$
and a genuine character
$\widetilde {\omega }$
of
$Z(\widetilde {G})$
compatible with
$(\widetilde {\omega }_{1},\dots ,\widetilde {\omega }_{t})$
, saying that
$$ \begin{align*}(\widetilde{\omega}_{1}\lvert_{Z(\widetilde{G_{r_{1}}})\cap\widetilde{G_{r_{1}}^{(n)}}}\boxtimes\dots\boxtimes\widetilde{\omega}_{t}\lvert_{Z(\widetilde{G_{r_{t}}})\cap\widetilde{G_{r_{t}}^{(n)}}})\lvert_{Z(\widetilde{G})\cap\widetilde{G^{(n)}}}=\widetilde{\omega}\lvert_{Z(\widetilde{G})\cap\widetilde{G^{(n)}}}.\end{align*} $$
Let
$\operatorname {Rep}_{\widetilde {\omega }_{i}}(\widetilde {G_{r_{i}}})$
(resp.
$\operatorname {Rep}_{\widetilde {\omega }}(\widetilde {M})$
) denote the category of smooth locally-
$\widetilde {\omega }_{i}$
(resp. locally-
$\widetilde {\omega }$
) representations of
$\widetilde {G_{r_{i}}}$
(resp.
$\widetilde {M}$
). Then we may define a multi-multiplicative multi-exact metaplectic tensor product functor (depending on the choice of
$\widetilde {\omega }$
)
$$ \begin{align*}(\boxtimes_{i=1}^{t})_{\widetilde{\omega}}:\operatorname{Rep}_{\widetilde{\omega}_{1}}(\widetilde{G_{r_{1}}})\times\dots\times\operatorname{Rep}_{\widetilde{\omega}_{t}}(\widetilde{G_{r_{t}}})\rightarrow\operatorname{Rep}_{\widetilde{\omega}}(\widetilde{M}),\end{align*} $$
which induces a bijection for irreducible representations
$$ \begin{align*}(\boxtimes_{i=1}^{t})_{\widetilde{\omega}}:\operatorname{Irr}_{\widetilde{\omega}_{1}}(\widetilde{G_{r_{1}}})\times\dots\times\operatorname{Irr}_{\widetilde{\omega}_{t}}(\widetilde{G_{r_{t}}})\rightarrow\operatorname{Irr}_{\widetilde{\omega}}(\widetilde{M}).\end{align*} $$
The metaplectic tensor product for irreducible representations could be realized in a more concrete way. Let
$\widetilde {\pi }_{i}\in \operatorname {Irr}_{\widetilde {\omega }_{i}}(\widetilde {G_{r_{i}}})$
and
$\widetilde {\pi }_{i}^{(n)}:=\widetilde {\pi }_{i}\lvert _{\widetilde {G_{r_{i}}^{(n)}}}$
for each
$i=1,\dots ,t$
. Let
$M_{r_{1},\dots ,r_{t}}^{(n)}:=G_{r_{1}}^{(n)}\times \dots \times G_{r_{t}}^{(n)}$
which is block compatible. We may define the tensor product
$$ \begin{align*}\widetilde{\pi}_{1}^{(n)}\boxtimes\dots\boxtimes\widetilde{\pi}_{t}^{(n)}\end{align*} $$
as a genuine representation of
$\boldsymbol {p}^{-1}(M_{r_{1},\dots ,r_{t}}^{(n)})$
. Then, there exists a positive integer
$m_{n,\boldsymbol {c};r_{1},\dots ,r_{t}}$
depending only on
$n,\boldsymbol {c},r_{1},\dots ,r_{t}$
, such that
$$ \begin{align} \operatorname{Ind}_{\boldsymbol{p}^{-1}(M_{r_{1},\dots,r_{t}}^{(n)})}^{\widetilde{M}}(\widetilde{\pi}_{1}^{(n)}\boxtimes\dots\boxtimes\widetilde{\pi}_{t}^{(n)})\cong m_{n,\boldsymbol{c};r_{1},\dots,r_{t}}\cdot\bigoplus_{\widetilde{\omega}}(\widetilde{\pi}_{1}\boxtimes\dots\boxtimes\widetilde{\pi}_{t})_{\widetilde{\omega}}, \end{align} $$
where
$\widetilde {\omega }$
in the direct sum ranges over all the genuine characters of
$Z(\widetilde {G})$
that are compatible with
$(\widetilde {\omega }_{1},\dots ,\widetilde {\omega }_{t})$
.
We remark that any two different representations in the direct sum of the right-hand side of (9.1) are weakly equivalent. It means that they are isomorphic up to a twist by a character
$\chi \circ \operatorname {det}$
of M, where
$\chi $
is a character of
$F^{\times }/F^{\times n}$
.
9.2 Simple types related to the metaplectic tensor product
We come back to the setting of §6.3. Let
$r=r_{0}t$
. Let
$V=V^{1}\oplus \dots \oplus V^{t}$
be a decomposition of F-vector spaces, where
$V^{i}$
is a F-vector space of dimension
$r_{0}$
. Let
$A=\operatorname {End}_{F}(V)$
and
$G=\operatorname {Aut}_{F}(V)$
.
Up to a choice of an F-basis for each
$V^{i}$
, we identify
$A^{i}=\operatorname {End}_{F}(V^{i})$
with
$\operatorname {M}_{r_{0}}(F)$
,
$G^{i}=\operatorname {Aut}_{F}(V^{i})$
with
$G_{r_{0}}:=\operatorname {GL}_{r_{0}}(F)$
. Let P be a parabolic subgroup of G having
$M=\operatorname {Aut}_{F}(V^{1})\times \dots \times \operatorname {Aut}_{F}(V^{t})$
as a Levi factor.
As before, we consider a KP-cover or the S-cover
$\widetilde {G}$
of G. Then each
$\widetilde {G^{i}}$
is identified with
$\widetilde {G_{r_{0}}}$
, which is a KP-cover or the S-cover of the same type.
Let
$\widetilde {\pi }_{0}$
be a genuine cuspidal representation of
$\widetilde {G_{r_{0}}}$
. In the S-cover case, we consider the metaplectic tensor product
$$ \begin{align} \widetilde{\pi}=\widetilde{\pi}_{0}\boxtimes\dots\boxtimes\widetilde{\pi}_{0} \end{align} $$
as an irreducible cuspidal representation of
$\widetilde {M}$
. In the KP-cover case, we choose a compatible genuine character
$\widetilde {\omega }$
of
$Z(\widetilde {G})$
, and we take
$$ \begin{align} \widetilde{\pi}=(\widetilde{\pi}_{0}\boxtimes\dots\boxtimes\widetilde{\pi}_{0})_{\widetilde{\omega}} \end{align} $$
as an irreducible cuspidal representation of
$\widetilde {M}$
. In this case, we are allowed to replace
$\widetilde {\pi }_{0}$
by its twist of a character of order n. When we do so, the related
$\widetilde {\pi }$
remains unchanged.
Let
$\mathfrak {s}$
(resp.
$\mathfrak {s}_{M}$
) be the inertial equivalence class of
$\widetilde {G}$
(resp.
$\widetilde {M}$
) that contains
$(\widetilde {M},\widetilde {\pi })$
.
Our first goal is to construct a simple type
$(\widetilde {J},\widetilde {\lambda })$
of
$\widetilde {G}$
as an
$\mathfrak {s}$
-type.
Lemma 9.1. There exists a maximal simple type
$(\widetilde {J_{0}},\widetilde {\lambda }_{0})$
of
$\widetilde {G_{r_{0}}}$
contained in
$\widetilde {\pi }_{0}$
, such that
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
is a maximal simple type of
$\widetilde {M}$
contained in
$\widetilde {\pi }$
, where
$J_{M}=J_{0}\times \dots \times J_{0}$
and
$\widetilde {\lambda }_{M}:=\widetilde {\lambda }_{0}\boxtimes \dots \boxtimes \widetilde {\lambda }_{0}$
is a genuine irreducible representation of
$\widetilde {J_{M}}$
. Here, in the KP-cover case, we are allowed to replace
$\widetilde {\pi }_{0}$
by its twist of an order n character.
Proof. In the S-cover case, we construct
$(\widetilde {J_{0}},\widetilde {\lambda }_{0})$
via Theorem 8.4.(2). Then the related
$\widetilde {\lambda }_{M}:=\widetilde {\lambda }_{0}\boxtimes \dots \boxtimes \widetilde {\lambda }_{0}$
is contained in
$\widetilde {\pi }$
since M is block compatible.
In the KP-cover case, using the argument of Theorem 8.11.(2) and (9.1), there exists a maximal simple type
$(\widetilde {J_{0}},\widetilde {\lambda }_{0}')$
of
$\widetilde {G_{r_{0}}}$
contained in
$\widetilde {\pi }_{0}$
, such that the related maximal simple type
$(\widetilde {J_{M}},\widetilde {\lambda }_{M}')$
of
$\widetilde {M}$
is contained in
$(\widetilde {\pi }_{0}\boxtimes \dots \boxtimes \widetilde {\pi }_{0})_{\widetilde {\omega }'}$
for some compatible character
$\widetilde {\omega }'$
of
$Z(\widetilde {G})$
, where
$\widetilde {\lambda }_{M}':=\widetilde {\lambda }_{0}'\boxtimes \dots \boxtimes \widetilde {\lambda }_{0}'$
. Moreover, there exists a character
$\chi $
of
$F^{\times }/F^{\times n}$
, such that
$$ \begin{align*}\widetilde{\pi}=(\widetilde{\pi}_{0}\boxtimes\dots\boxtimes\widetilde{\pi}_{0})_{\widetilde{\omega}}\cong (\widetilde{\pi}_{0}\boxtimes\dots\boxtimes\widetilde{\pi}_{0})_{\widetilde{\omega}'}\cdot(\chi\circ\operatorname{det}).\end{align*} $$
We take
$\widetilde {\lambda }_{0}=\widetilde {\lambda }_0'\cdot (\chi \circ \operatorname {det})$
. Then,
$\widetilde {\pi }_{0}\cdot (\chi \circ \operatorname {det})$
contains
$\widetilde {\lambda }_{0}$
and
$\widetilde {\pi }$
contains
$\widetilde {\lambda }_{M}$
. So in this case, if we replace
$\widetilde {\pi }_{0}$
by
$\widetilde {\pi }_{0}\cdot (\chi \circ \operatorname {det})$
, the proof is finished.
From now on, we pick
$(\widetilde {J_{0}},\widetilde {\lambda }_{0})$
and
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
as in the above lemma.
We give more information on the construction of
$\widetilde {\lambda }_{0}$
. Let
$[\mathfrak {a}_{0},u,0,\beta _{0}]$
be a strict maximal simple stratum in
$\operatorname {M}_{r_{0}}(F)$
, such that
$J_{0}=J(\beta ,\mathfrak {a}_{0})$
. We fix a maximal compact subgroup
$K_{0}$
of
$G_{r_{0}}$
that contains
$U(\mathfrak {a}_{0})$
, and a splitting
$\boldsymbol {s}_{0}$
of
$K_{0}$
. Write
$E=F[\beta _{0}]$
, and
$\boldsymbol {l}$
for the residue field of E and
$r_{0}=[E:F]m_{0}$
.
Then, there exist a simple character
$\theta _{0}\in \mathcal {C}(\mathfrak {a}_{0},\beta )$
, its Heisenberg representation
$\eta _{0}$
, a
$\beta $
-extension
$\kappa _{0}$
of
$\eta _{0}$
, a cuspidal representation
$\varrho _{0}$
of
$\mathcal {G}_{0}=\operatorname {GL}_{m_{0}}(\boldsymbol {l})$
and
$\widetilde {\rho }_{0}=\operatorname {Inf}_{\widetilde {\mathcal {G}_{0}}}^{\widetilde {J_{0}}}(\epsilon \cdot \,_{s_{0}}\varrho _{0})$
, such that
$\widetilde {\lambda }_{0}=\widetilde {\kappa }_{0}\otimes \widetilde {\rho }_{0}$
.
Now we focus on the construction of the simple type
$(\widetilde {J},\widetilde {\lambda })$
. We identify
$\beta _{0}$
with an element in each
$G^{i}\cong \operatorname {GL}_{r_{0}}(F)$
. We let
$\beta =\operatorname {diag}(\beta _{0},\dots ,\beta _{0})$
be an element in M. By abuse of notation, we also write
$E=F[\beta ]$
as a subfield of
$\operatorname {End}_{F}(V)$
. Write
$B=\operatorname {End}_{E}(V_{E})$
. Let
$\mathfrak {a}$
be a hereditary order in A that is normalized by
$E^{\times }$
, such that the decomposition
$V=\bigoplus _{i=1}^{t}V^{i}$
is properly subordinate to
$\Lambda $
, the lattice chain corresponding to
$\mathfrak {a}$
.
Choose a maximal open compact subgroup K containing
$U(\mathfrak {a})$
, and a splitting
$\boldsymbol {s}$
of K. Indeed, our choice could be made such that via the isomorphism
$G^{i}\cong G_{r_{0}}$
, the group
$K\cap G^{i}$
is identified with
$K_{0}$
and the restriction of
$\boldsymbol {s}$
to each
$K\cap G^{i}$
is identified with
$\boldsymbol {s}_{0}$
.
Then
$[\mathfrak {a},u,0,\beta ]$
is a strict simple stratum in A. Write
$H^{1}=H^{1}(\beta ,\mathfrak {a})$
,
$J^{1}=J^{1}(\beta ,\mathfrak {a})$
and
$J=J(\beta ,\mathfrak {a})$
as before.
Let
$\theta \in \mathcal {C}(\mathfrak {a},\beta )$
be the transfer of
$\theta _{0}$
and let
$\eta $
be the Heisenberg representation of
$\theta $
. Let
$\kappa $
be a
$\beta $
-extension of
$\eta $
, such that the corresponding
$\kappa _{M}$
, as a representation of
$J_{M}=J\cap M$
, equals
$\kappa _{0}\boxtimes \dots \boxtimes \kappa _{0}$
. Write
$\mathcal {M}=U(\mathfrak {b})/U^{1}(\mathfrak {b})=\mathcal {G}_{0}\times \dots \times \mathcal {G}_{0}$
and let
$\varrho =\varrho _{0}\boxtimes \dots \boxtimes \varrho _{0}$
be a cuspidal representation of
$\mathcal {M}$
. Let
$\widetilde {\rho }=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s}\varrho )$
and
$\widetilde {\lambda }=\widetilde {\kappa }\otimes \widetilde {\rho }$
.
Then
$(\widetilde {J},\widetilde {\lambda })$
is a simple type of
$\widetilde {G}$
. Moreover, two related pairs
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
and
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
are constructed as in §6.1. Indeed, from our construction, the pair
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
is exactly the maximal simple type of
$\widetilde {M}$
we considered above. By Theorem 6.15 and Theorem 6.16,
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
is a
$\mathfrak {s}_{M}$
-type,
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
is a covering pair of
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
, and both
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
and
$(\widetilde {J},\widetilde {\lambda })$
are
$\mathfrak {s}$
-types.
9.3 A deeper study of Hecke algebras
We also study the corresponding Hecke algebras. Let
$l_{0}$
,
$d_{0}=d_{r,l_{0}}$
,
$n_{0}=n_{r_{0},l_{0}}$
and
$s_{0}=s_{r_{0},l_{0}}$
be defined as in §6.3. Using Theorem 7.5 and Remark 7.6, we have an isomorphism
$$ \begin{align*}\Psi:\widetilde{\mathcal{H}}(t,s_{0},\boldsymbol{q}_{0})\rightarrow\mathcal{H}(\widetilde{G},\widetilde{\lambda}_{P}).\end{align*} $$
Moreover, we choose
$\Psi $
to satisfy the result of Corollary 7.13. Recall that we have an embedding of algebras
$$ \begin{align*}t_{P}:\mathcal{H}(\widetilde{M},\widetilde{\lambda}_{M})\rightarrow\mathcal{H}(\widetilde{G},\widetilde{\lambda}_{P}).\end{align*} $$
So the restriction of
$\Psi $
gives an isomorphism
$$ \begin{align*}\Psi:\widetilde{\mathcal{A}}(t,s_{0})\rightarrow t_{P}(\mathcal{H}(\widetilde{M},\widetilde{\lambda}_{M})).\end{align*} $$
Let
$\Psi _{M}:=t_{P}^{-1}\circ \Psi \lvert _{\widetilde {\mathcal {A}}(t,s_{0})}$
be the isomorphism between
$\widetilde {\mathcal {A}}(t,s_{0})$
and
$\mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M})$
.
By definition, we have equivalence of categories
$$ \begin{align*}\boldsymbol{\mathrm{M}}_{\widetilde{\lambda}_{P}}:\operatorname{Rep}_{\mathfrak{s}}(\widetilde{G})\rightarrow\operatorname{Mod}(\mathcal{H}(\widetilde{G},\widetilde{\lambda}_{P}))\quad\text{and}\quad\boldsymbol{\mathrm{M}}_{\widetilde{\lambda}_{M}}:\operatorname{Rep}_{\mathfrak{s}_{M}}(\widetilde{M})\rightarrow\operatorname{Mod}(\mathcal{H}(\widetilde{M},\widetilde{\lambda}_{M})).\end{align*} $$
Composing with equivalence of categories
$$ \begin{align*}\Psi^{*}:\operatorname{Mod}(\mathcal{H}(\widetilde{G},\widetilde{\lambda}_{P}))\rightarrow\operatorname{Mod}(\widetilde{\mathcal{H}}(t,s_{0},\boldsymbol{q}_{0}))\quad\text{and}\quad\Psi_{M}^{*}:\operatorname{Mod}(\mathcal{H}(\widetilde{M},\widetilde{\lambda}_{M}))\rightarrow\operatorname{Mod}(\widetilde{\mathcal{A}}(t,s_{0}))\end{align*} $$
induced by
$\Psi $
and
$\Psi _{M}$
, we get equivalence of categories
$$ \begin{align*}\widetilde{\mathcal{T}}_{G}:\operatorname{Rep}_{\mathfrak{s}}(\widetilde{G})\rightarrow\operatorname{Mod}(\widetilde{\mathcal{H}}(t,s_{0},\boldsymbol{q}_{0}))\quad\text{and}\quad\widetilde{\mathcal{T}}_{M}:\operatorname{Rep}_{\mathfrak{s}_{M}}(\widetilde{M})\rightarrow\operatorname{Mod}(\widetilde{\mathcal{A}}(t,s_{0})).\end{align*} $$
We study the compatibility of these functors with parabolic induction. First, we need the following lemma:
Lemma 9.2. The following diagram is commutative:
where we write
$\operatorname {Ind}_{\widetilde {\mathcal {A}}}^{\widetilde {\mathcal {H}}}=\operatorname {Ind}_{\widetilde {\mathcal {A}}(t,s_{0})}^{\widetilde {\mathcal {H}}(t,s_{0},\boldsymbol {q}_{0})}$
for short.
Proof. It follows from the commutative diagram
Combining this lemma with Theorem 3.4, we have a commutative diagram
Composing with the diagram (7.2), we get another commutative diagram
where we write
$\operatorname {Ind}_{\mathcal {A}}^{\mathcal {H}}=\operatorname {Ind}_{\mathcal {A}(t)}^{\mathcal {H}(t,\boldsymbol {q}_{0})}$
for short.
We consider the
$\mathfrak {S}_{t}$
-action on those categories, and the
$\mathfrak {S}_{t}$
-equivariance of the above functors. First,
$\mathfrak {S}_{t}$
acts on
$\mathcal {A}(t)$
and
$\widetilde {\mathcal {A}}(t,s_{0})$
by interchanging
$X_{i}$
and fixing Z. Also, using (6.7), we identify
$\mathfrak {S}_{t}$
with
$W_{0}(\mathfrak {b})$
, which is a group of representatives of the Weyl group
$W(G,M)$
. Since
$\mathfrak {S}_{t}$
stabilizes
$\widetilde {M}$
,
$\widetilde {\lambda }_{M}=\widetilde {\lambda }_{0}\boxtimes \dots \boxtimes \widetilde {\lambda }_{0}$
and
$\mathfrak {s}_{M}$
, we have
$\mathfrak {S}_{t}$
-actions on
$\widetilde {M}$
and
$\mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M})$
. This induces
$\mathfrak {S}_{t}$
-action on
$\operatorname {Rep}_{\mathfrak {s}_{M}}(\widetilde {M})$
,
$\operatorname {Mod}(\mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M}))$
,
$\operatorname {Mod}(\widetilde {\mathcal {A}}(t,s_{0}))$
and
$\operatorname {Mod}(\mathcal {A}(t))$
.
Lemma 9.3. The morphisms
$\boldsymbol {\mathrm {M}}_{\widetilde {\lambda }_{M}}$
,
$\Psi _{M}^{*}$
,
$\widetilde {\mathcal {T}}_{M}$
and
$\mathcal {T}_{M}$
are
$\mathfrak {S}_{t}$
-equivariant.
We will prove this lemma in the next subsection.
Finally, for
$\boldsymbol {x}=(x_{1},\dots ,x_{t})\in \mathbb {C}^{t}$
, we define a character
$\mathbb {C}_{\boldsymbol {x}}$
of
$\mathcal {A}(t)=\mathbb {C}[X_{1},X_{1}^{-1},\dots, X_{t},X_{t}^{-1}]$
, such that each
$X_{i}$
acts on
$\mathbb {C}_{\boldsymbol {x}}$
by multiplying with
$x_{i}$
.
Lemma 9.4. Let
$\chi =\nu ^{a_{1}}\boxtimes \dots \boxtimes \nu ^{a_{t}}$
be a character of M for
$a_{1},\dots ,a_{t}\in \mathbb {R}$
, let
$n_{0}=n_{r_{0},l_{0}}$
be defined as in (6.10), and let
$\boldsymbol {x}_{\chi }=(\boldsymbol {q}_{0}^{-a_{1}n_{0}},\dots ,\boldsymbol {q}_{0}^{-a_{t}n_{0}})$
. Let
$$ \begin{align*}\mathcal{T}_{M}:\operatorname{Rep}_{\mathfrak{s}_{M}}(\widetilde{M})\rightarrow\operatorname{Mod}(\mathcal{A}(t))\end{align*} $$
be the map in (9.5). Then
-
• the image of
$\widetilde {\pi }$
under this map is a character of
$\mathcal {A}(t)$
of the form
$\mathbb {C}_{\boldsymbol {z}}$
for a certain
$0\neq z\in \mathbb {C}$
and
$\boldsymbol {z}=(z,z,\dots ,z)\in \mathbb {C}^{t}$
. -
• the image of
$\widetilde {\pi }\cdot \chi $
under this map is the character
$\mathbb {C}_{\boldsymbol {z}}\cdot \mathbb {C}_{\boldsymbol {x}_{\chi }}$
of
$\mathcal {A}(t)$
.
Proof. For the first statement, using Lemma 9.3,
$\mathcal {T}_{M}:\operatorname {Rep}_{\mathfrak {s}_{M}}(\widetilde {M})\rightarrow \operatorname {Mod}(\mathcal {A}(t))$
is
$\mathfrak {S}_{t}$
-equivariant. Since
$\widetilde {\pi }$
is
$\mathfrak {S}_{t}$
-stable, so is its image in
$\operatorname {Mod}(\mathcal {A}(t))$
, which turns out to be a character of the form
$\mathbb {C}_{\boldsymbol {z}}$
.
Now we prove the second statement. Let g be any element in
$T_{0}$
(cf. §6.3) and let
$\phi _{g}\in \mathcal {H}(\widetilde {M},\widetilde {\lambda }_{M})$
be a nonzero function that is supported on
$\widetilde {J_{M}}g\widetilde {J_{M}}$
. We identify the underlying vector space of the modules
$\boldsymbol {M}_{\widetilde {\lambda }_{M}}(\widetilde {\pi }\cdot \chi )$
and
$\boldsymbol {M}_{\widetilde {\lambda }_{M}}(\widetilde {\pi })$
. Then the action of
$\phi _{g}$
on both modules differs exactly by multiplying by
$\chi (g)$
. In particular, let
$$ \begin{align*}g_{i}=\operatorname{diag}(I_{m_{0}},\dots,I_{m_{0}},\varpi_{E}^{n_{0}}I_{m_{0}},I_{m_{0}},\dots, I_{m_{0}})\in T_{0},\end{align*} $$
with
$\varpi _{E}^{n_{0}}I_{m_{0}}$
occurring in the i-th block. Then from our construction, there exist nonzero elements
$\phi _{g_{i}}$
supported on
$\widetilde {J_{M}}g_{i}\widetilde {J_{M}}$
,
$i=1,\dots ,t$
, such that their images under the composition map
are exactly
$X_{i}$
,
$i=1,\dots ,t$
. As a result, if we identify the underlying vector space of the image of
$\mathcal {T}_{M}(\widetilde {\pi }\cdot \chi )$
and
$\mathcal {T}_{M}(\widetilde {\pi })$
as
$\mathcal {A}(t)$
-modules, then the
$X_{i}$
-action on both modules differs by
$$ \begin{align*}\chi(g_{i})=\nu(\varpi_{F})^{a_{i}n_{0}m_{0}f}=\boldsymbol{q}_{0}^{-a_{i}n_{0}}.\end{align*} $$
So we finish the proof of the second statement.
9.4 Proof of Lemma 9.3
In this part, we give a proof of Lemma 9.3, which already contains some ideas of the previous and the next subsections.
By definition,
$\boldsymbol {\mathrm {M}}_{\widetilde {\lambda }_{M}}$
is
$\mathfrak {S}_{t}$
-equivariant. Also,
$\widetilde {\mathcal {T}}_{M}$
and
$\mathcal {T}_{M}$
are
$\mathfrak {S}_{t}$
-equivariant once we know that
$\Psi _{M}^{*}$
is
$\mathfrak {S}_{t}$
-equivariant.
Now we prove the statement for
$\Psi _{M}^{*}$
. Let
$X_{1},\dots ,X_{t}$
be elements in both
$\widetilde {\mathcal {A}}(t,s_{0})$
and
$\widetilde {\mathcal {H}}(t,s_{0},\boldsymbol {q}_{0})$
. Let
$\varphi _{1}=\Psi _{M}(X_{1})$
. Let
$\varsigma _{1i}$
be the transposition of
$1$
and i in
$\mathfrak {S}_{t}$
, let
$\varphi _{i}=\varphi _{1}^{\varsigma _{1i}}$
for each
$i=1,\dots ,t$
. By definition, both
$\varphi _{i}$
and
$\Psi _M(X_{i})$
are supported on
$\widetilde {J_{M}}g_{i}\widetilde {J_{M}}$
for each
$i=1,\dots ,t$
, where
$$ \begin{align*}g_{i}:=\operatorname{diag}(I_{m_{0}},\dots,I_{m_{0}},\varpi_{E}^{n_{0}}I_{m_{0}},I_{m_{0}},\dots, I_{m_{0}})\in T_{0}\end{align*} $$
with
$\varpi _{E}^{n_{0}}I_{m_{0}}$
occurring in the i-th block. Thus, for each
$i=1,\dots ,t$
, there exists a nonzero complex number
$c_{i}$
, such that
$\varphi _{i}=c_{i}\cdot \Psi _{M}(X_{i})$
. In particular
$c_{1}=1$
.
Let
$\boldsymbol {c}=(c_{1},\dots ,c_{t})$
. Our goal is to prove that
$c_{1}=\dots =c_{t}=1$
. Then by definition,
$\mathfrak {S}_{t}$
permutes
$\Psi _{M}(X_{i})$
,
$i=1,\dots ,t$
, which shows that
$\Psi _{M}^{*}$
is
$\mathfrak {S}_{t}$
-equivariant.
We first show that
$\boldsymbol {c}$
is unitary, saying that each
$c_{i}$
has absolute value
$1$
. Note that
$\Psi _{M}$
is an isometry since both
$\Psi $
and
$t_{P}$
are isometries. Since
$\langle X_{1},X_{1}\rangle =\dots =\langle X_{t},X_{t}\rangle $
, we have
$h_{M}(\Psi _{M}(X_{1}),\Psi _{M}(X_{1}))=\dots =h_{M}(\Psi _{M}(X_{t}),\Psi _{M}(X_{t}))$
. By definition, we also have
$h_{M}(\varphi _{1},\varphi _{1})=\dots =h_{M}(\varphi _{t},\varphi _{t})$
. So
$1=\left |c_{1}\right |{}^{2}=\dots =\left |c_{t}\right |{}^{2}$
.
We define an isomorphism of algebras
$T_{\boldsymbol {c}}:\mathcal {A}(t)\rightarrow \mathcal {A}(t)$
that maps
$X_{i}$
to
$c_{i}^{-1}X_{i}$
for each i, and the induced map
$T_{\boldsymbol {c}}^{*}:\operatorname {Mod}(\mathcal {A}(t))\rightarrow \operatorname {Mod}(\mathcal {A}(t))$
via pull-back. We define
$\mathcal {T}_{M,\boldsymbol {c}}=T_{\boldsymbol {c}}^{*}\circ \mathcal {T}_{M}$
as a functor from
$\operatorname {Rep}_{\mathfrak {s}_{M}}(\widetilde {M})$
to
$\operatorname {Mod}(\mathcal {A}(t))$
. Thus, by definition, it is
$\mathfrak {S}_{t}$
-equivariant. As in Lemma 9.4.(1),
$\mathcal {T}_{M,\boldsymbol {c}}(\widetilde {\pi })$
equals
$\mathbb {C}_{\boldsymbol {z}}$
for a certain
$\boldsymbol {z}=(z,\dots ,z)\in \mathbb {C}^{t}$
. Thus,
$\mathcal {T}_{M}(\widetilde {\pi })$
equals
$\mathbb {C}_{\boldsymbol {z}}\cdot \mathbb {C}_{\boldsymbol {c}}$
. By Lemma 9.4.(2) (and more precisely its argument),
$\mathcal {T}_{M}(\widetilde {\pi }\cdot \chi )=\mathbb {C}_{\boldsymbol {z}}\cdot \mathbb {C}_{\boldsymbol {c}}\cdot \mathbb {C}_{\boldsymbol {x}_{\chi }}$
.
Using the diagram (9.5) and Remark 7.2, the parabolic induction
$i_{\widetilde {P}}^{\widetilde {G}}(\widetilde {\pi }\cdot \chi )$
is irreducible if and only if
$\operatorname {ind}_{\mathcal {A}}^{\mathcal {H}}(\mathbb {C}_{\boldsymbol {z}}\cdot \mathbb {C}_{\boldsymbol {c}}\cdot \mathbb {C}_{\boldsymbol {x}_{\chi }})$
is irreducible. If
$\boldsymbol {c}\neq (1,\dots ,1)$
, up to
$\mathfrak {S}_{t}$
-conjugacy, without loss of generality, we may assume that
$c_{1}=\dots =c_{t'}=1$
and
$c_{t'+1},\dots ,c_{t}\neq 1$
for a certain
$t'=1,\dots ,t-1$
. Consider
$$ \begin{align*}\chi=\underbrace{1\boxtimes\dots\boxtimes1}_{t'\text{-copies}}\boxtimes\underbrace{\nu^{s}\boxtimes\dots\boxtimes\nu^{s}}_{(t-t')\text{-copies}}.\end{align*} $$
Then using [Reference Kaplan, Lapid and Zou46, Proposition 6.10], which in parallel can be stated and proved for the S-cover, there exists
$s>0$
such that
$i_{\widetilde {P}}^{\widetilde {G}}(\widetilde {\pi }\cdot \chi )$
is not irreducible (in the next subsection, s is shown to be
$1/n_{0}$
). On the other hand,
$$ \begin{align*}\operatorname{ind}_{\mathcal{A}}^{\mathcal{H}}(\mathbb{C}_{\boldsymbol{z}}\cdot\mathbb{C}_{\boldsymbol{c}}\cdot\mathbb{C}_{\boldsymbol{x}_{\chi}})=\operatorname{ind}_{\mathcal{A}}^{\mathcal{H}}(\mathbb{C}_{\boldsymbol{x}}),\end{align*} $$
where
$\boldsymbol {x}=(z,\dots ,z,z\boldsymbol {q}_{0}^{-sn_{0}}c_{t'+1},\dots ,z\boldsymbol {q}_{0}^{-sn_{0}}c_{t})$
. The following lemma can be easily deduced from the classification of irreducible representations of
$\mathcal {H}(t,\boldsymbol {q}_{0})$
; see, for instance, [Reference Solleveld68, §2.3].
Lemma 9.5. For
$\boldsymbol {x}=(x_{1},\dots ,x_{t})$
such that
$x_{j}\neq x_{i}\boldsymbol {q}_{0}^{\pm 1}$
for any
$1\leq i\neq j\leq t$
, the induced representation
$\operatorname {ind}_{\mathcal {A}}^{\mathcal {H}}(\mathbb {C}_{\boldsymbol {x}})$
is irreducible.
As a result,
$\operatorname {ind}_{\mathcal {A}}^{\mathcal {H}}(\mathbb {C}_{\boldsymbol {z}}\cdot \mathbb {C}_{\boldsymbol {c}}\cdot \mathbb {C}_{\boldsymbol {x}_{\chi }})$
is an irreducible representation of
$\mathcal {H}(t,\boldsymbol {q}_{0})$
, contradictory! So
$\boldsymbol {c}=(1,\dots ,1)$
and Lemma 9.3 is proved.
Remark 9.6. Our proof here is not so direct, which uses representation theory of
$\widetilde {G}$
and
$\mathcal {H}(t,\boldsymbol {q}_{0})$
. We wonder if a proof on the level of generators and relations of Hecke algebras could be given, like what has been done in [Reference Bushnell and Kutzko19, §7.6].
9.5 Reducible parabolic induction of the metaplectic tensor product of two cuspidal representations
Keep the notation as above. We further assume that
$t=2$
,
$r=2r_{0}$
and
$M=G_{r_{0}}\times G_{r_{0}}$
. The goal is to prove the following proposition.
Proposition 9.7. Let
$\widetilde {\pi }_{s}$
be the cuspidal representation
$\widetilde {\pi }\cdot (\nu ^{-s}\boxtimes \nu ^{s})$
of
$\widetilde {M}$
for
$s\in \mathbb {R}$
. Then the parabolic induction
$i_{\widetilde {P}}^{\widetilde {G}}(\widetilde {\pi }_{s})$
is reducible if and only if
$s=\pm 1/2n_{0}$
.
Proof. Using the commutative diagram (9.5) and Remark 7.2,
$i_{\widetilde {P}}^{\widetilde {G}}(\widetilde {\pi }_{s})$
is irreducible if and only if
$\operatorname {ind}_{\mathcal {A}}^{\mathcal {H}}(\mathcal {T}_{M}(\widetilde {\pi }_{s}))$
is irreducible. Using Lemma 9.4, we get
$\mathcal {T}_{M}(\widetilde {\pi }_{s})=\mathbb {C}_{\boldsymbol {z}}\cdot \mathbb {C}_{(\boldsymbol {q}_{0}^{sn_{0}},\boldsymbol {q}_{0}^{-sn_{0}})}$
. From the study of irreducible representations of
$\mathcal {H}(2,\boldsymbol {q}_{0})$
(cf. [Reference Solleveld68, Theorem 2.5]), the induction
$\operatorname {ind}_{\mathcal {A}}^{\mathcal {H}}(\mathbb {C}_{\boldsymbol {z}}\cdot \mathbb {C}_{(\boldsymbol {q}_{0}^{sn_{0}},\boldsymbol {q}_{0}^{-sn_{0}})})$
is reducible if and only if
$sn_{0}=\pm 1/2$
, or equivalently,
$s=\pm 1/2n_{0}$
.
Remark 9.8. This proposition complements [Reference Kaplan, Lapid and Zou46, Proposition 6.10] by giving an explicit description of
$s_{\rho }$
in loc. cit. for KP-covers. A similar calculation has also been done in [Reference Zou80, Proposition 3.13]. A natural and interesting question is to verify that the two calculations give the same value, which in turn will lead us to a study of ‘explicit’ metaplectic correspondence (i.e., describing the image of the metaplectic lift of a genuine cuspidal representation using the simple type theory).
9.6 The image of Zelevinsky standard modules under
$\mathcal {T}_{G}$
Keep the notation as above. We consider the parabolic induction
$$ \begin{align*}i_{\widetilde{P}}^{\widetilde{G}}(\widetilde{\pi}\cdot(\nu^{-(t-1)/2n_{0}}\boxtimes\nu^{-(t-3)/2n_{0}}\boxtimes\dots\boxtimes\nu^{(t-1)/2n_{0}})),\end{align*} $$
which, by Proposition 9.7 and [Reference Kaplan, Lapid and Zou46, §7], admits a unique irreducible subrepresentation denoted by
$Z(\widetilde {\pi },t)$
and a unique irreducible quotient denoted by
$L(\widetilde {\pi },t)$
.
Remark 9.9. Although only KP-covers are considered in [Reference Kaplan, Lapid and Zou46, §7], the corresponding results for the S-cover are also true, whose proofs are similar and simpler.
Let
$\boldsymbol {1}_{t,z,\boldsymbol {q}_{0}}$
(resp.
$\mathrm {St}_{t,z,\boldsymbol {q}_{0}}$
) be the unique irreducible subrepresentation (resp. quotient) of
$$ \begin{align*}\operatorname{ind}_{\mathcal{A}}^{\mathcal{H}}(\mathbb{C}_{(z\boldsymbol{q}_{0}^{(t-1)/2},z\boldsymbol{q}_{0}^{(t-3)/2},\dots,z\boldsymbol{q}_{0}^{(1-t)/2})}).\end{align*} $$
They are one-dimensional representations of
$\mathcal {H}(t,\boldsymbol {q}_{0})$
. See, for instance, [Reference Solleveld68, §2.3]. The following proposition follows from Remark 7.2, (9.5) and Lemma 9.4.
Proposition 9.10. We have
$\mathcal {T}_{G}(Z(\widetilde {\pi },t))=\boldsymbol {1}_{t,z,\boldsymbol {q}_{0}}$
and
$\mathcal {T}_{G}(L(\widetilde {\pi },t))=\mathrm {St}_{t,z,\boldsymbol {q}_{0}}$
.
9.7 Inertial equivalence classes of discrete series
An inertial equivalence class
$\mathfrak {s}$
of
$\widetilde {G}$
is called discrete if
$\operatorname {Rep}_{\mathfrak {s}}(\widetilde {G})$
contains a (genuine) discrete series representation (i.e., an essentially square integrable representation) of
$\widetilde {G}$
.
First, we recall that discrete series representations of
$\widetilde {G}$
could be classified, which was originally a statement of Bernstein in the linear case [Reference Zelevinsky79, Theorem 9.3].
Lemma 9.11. For
$r=r_{0}t$
and a genuine cuspidal representation
$\widetilde {\pi }_{0}$
of
$\widetilde {G_{r_{0}}}$
, the corresponding
$L(\widetilde {\pi },t)$
defined in §9.6 is a discrete series representation. Conversely, every genuine discrete series representation of
$\widetilde {G}$
is of such form.
It follows from a similar argument as Jantzen [Reference Jantzen44, §2.3]. Note that all the required ingredients in the proof could be found in [Reference Kaplan, Lapid and Zou46] for a KP-cover and could also be modified for the S-cover with minor changes.
Now we may state the main result of this subsection, generalizing Corollary 8.5 for a KP-cover or the S-cover.
Proposition 9.12. We have a bijection between the set of G-conjugacy classes of weak equivalence classes of simple types
$(\widetilde {J},\widetilde {\lambda })$
and the set of discrete inertial equivalence classes
$\mathfrak {s}$
of
$\widetilde {G}$
, such that
$(\widetilde {J},\widetilde {\lambda })$
is an
$\mathfrak {s}$
-type.
Proof. First, given a simple type
$(\widetilde {J},\widetilde {\lambda })$
of
$\widetilde {G}$
, we show that it is a type of a discrete inertial equivalence class
$\mathfrak {s}$
. Indeed, let
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
be the corresponding maximal simple type of
$\widetilde {M}$
. In particular, we have
$\widetilde {\lambda }_{M}=\widetilde {\lambda }_{0}\boxtimes \dots \boxtimes \widetilde {\lambda }_{0}$
, where
$\widetilde {\lambda }_{0}$
is a maximal simple type of
$\widetilde {G_{r_{0}}}$
. Then we may choose a genuine cuspidal representation
$\widetilde {\pi }_{0}$
of
$\widetilde {G_{r_{0}}}$
containing
$\widetilde {\lambda }_{0}$
and a compatible genuine character
$\widetilde {\omega }$
of
$Z(\widetilde {G})$
in the KP-case, such that the corresponding genuine cuspidal representation
$\widetilde {\pi }$
of
$\widetilde {M}$
, defined as in (9.2) or (9.3), contains
$\widetilde {\lambda }_{M}$
. Let
$\mathfrak {s}_{M}$
be the inertial equivalence class of
$\widetilde {M}$
containing
$\widetilde {\pi }$
, and let
$\mathfrak {s}$
be the corresponding inertial equivalence class of
$\widetilde {G}$
. Then
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
is an
$\mathfrak {s}_{M}$
-type and
$(\widetilde {J},\widetilde {\lambda })$
is an
$\mathfrak {s}$
-type. Moreover, by definition,
$L(\widetilde {\pi },t)\in \operatorname {Rep}_{\mathfrak {s}}(\widetilde {G})$
.
A by-product of the above argument is that two simple types having the same G-conjugacy class of the weak equivalence class correspond to the same
$\mathfrak {s}$
.
Conversely, given
$\widetilde {\pi }_{0}$
,
$\widetilde {\pi }$
and a discrete inertial equivalence class
$\mathfrak {s}$
of
$\widetilde {G}$
such that
$\operatorname {Rep}_{\mathfrak {s}}(\widetilde {G})$
contains
$L(\widetilde {\pi },t)$
, the simple type
$(\widetilde {J},\widetilde {\lambda })$
of
$\widetilde {G}$
constructed as in §9.2 is an
$\mathfrak {s}$
-type.
If two simple types correspond to the same discrete inertial equivalence class, then they are intertwined. Thus, by Theorem 6.18, their weakly equivalence classes are G-conjugate. This shows the injectivity. The surjectivity follows from Lemma 9.11.
10 Exhaustion of constructing cuspidal representations
In this section, we prove Theorem 8.4.(2) to finish this article. Let
$\widetilde {\pi }$
be a genuine irreducible representation of
$\widetilde {G}$
. We would like to show that if
$\widetilde {\pi }$
is cuspidal, then it contains an EMST, or equivalently, it contains a maximal simple type of
$\widetilde {G}$
. Our argument largely follows from [Reference Bushnell and Kutzko19, §8] and [Reference Sécherre and Stevens66].
10.1 The depth 0 case
First of all, we recall the known result in the depth 0 case as a warm-up (cf. [Reference Howard and Weissman39]).
Assume that
$\widetilde {\pi }$
is cuspidal and of depth 0, where the latter condition means that for the maximal pro-p-subgroup
$K^{1}$
of a maximal compact subgroup K of G,
$$ \begin{align*}\widetilde{\pi}^{\,_{s}K^{1}}=\operatorname{Hom}_{\,_{s}K^{1}}(1,\widetilde{\pi})\neq 0.\end{align*} $$
Note that all such maximal compact subgroups K are G-conjugate to each other, so the above definition does not depend on the choice of K. In particular, we choose
$K=\operatorname {GL}_{r}(\mathfrak {o}_{F})$
and
$K^{1}=I_{r}+\operatorname {M}_{r}(\mathfrak {p}_{F})$
in this subsection. We fix a splitting
$\boldsymbol {s}:K\rightarrow \widetilde {G}$
.
We consider the null stratum
$[\mathfrak {a},0,0,\beta ]$
, where
$\mathfrak {a}=\operatorname {M}_{r}(\mathfrak {o}_{F})$
. So by convention, we have
$H^{1}(\beta ,\mathfrak {a})=J^{1}(\beta ,\mathfrak {a})=K^{1}$
and
$J(\beta ,\mathfrak {a})=K$
. Also, the only possible simple character and the Heisenberg representation is the identity character of
$K^{1}$
. Also, we consider the identity character of K as a
$\beta $
-extension, extending trivially to
$\widetilde {K}$
.
By [Reference Howard and Weissman39, Theorem 3.10], there exists a cuspidal representation
$\varrho $
of
$\mathcal {G}=\operatorname {GL}_{r}(\boldsymbol {k})\cong K/K^{1}$
, such that
$\widetilde {\pi }\lvert _{\widetilde {K}}$
contains the inflation
$\widetilde {\rho }=\operatorname {Inf}_{\widetilde {\mathcal {G}}}^{\widetilde {K}}(\epsilon \cdot \,_{s}\widetilde {\varrho })$
.
Since the pair
$(\widetilde {K},\widetilde {\rho })$
is a maximal simple type with respect to the null stratum
$[\mathfrak {a},0,0,\beta ]$
, our proof for depth 0 cuspidal representations is finished.
10.2 A reduction procedure
From now on, we assume that our representation
$\widetilde {\pi }$
is not of depth 0. Also, all the strata we will consider are not null.
Definition 10.1. We say that
$\widetilde {\pi }$
contains a
-
(1) split stratum if there exists a strict split stratum
$[\mathfrak {a},u,u-1,b]$
in A, such that
$\widetilde {\pi }$
contains the character
$\,_{s}\psi _{b}$
of
$\,_{s}U^{u}(\mathfrak {a})$
. -
(2) simple character if there exist a strict simple stratum
$[\mathfrak {a},u,0,\beta ]$
in A and a simple character
$\theta \in \mathcal {C}(\mathfrak {a},0,\beta )$
, such that
$\widetilde {\pi }$
contains
$\,_{s}\theta $
of
$\,_{s}H^{1}(\beta ,\mathfrak {a})$
. -
(3) split character if there exist a strict simple stratum
$[\mathfrak {a},u,l,\beta ]$
in A with
$l\geq 1$
, a simple character
$\theta '\in \mathcal {C}(\mathfrak {a},l-1,\beta )$
and
$c\in \mathfrak {p}_{\mathfrak {a}}^{-l}$
such that-
•
$\widetilde {\pi }$
contains the character
$\,_{s}\vartheta =\,_{s}\theta '\,_{s}\psi _{c}$
of
$\,_{s}H^{l}(\beta ,\mathfrak {a})$
. -
• The derived stratum
$[\mathfrak {b},l,l-1,s(c)]$
in B is split, where
$E=F[\beta ]$
,
$B=\operatorname {End}_{E}(V_{E})$
,
$\mathfrak {b}=\mathfrak {a}\cap B$
and
$s:A\rightarrow B$
is any tame corestriction.
-
The main result of this part is the following theorem, whose proof will be sketched below.
Theorem 10.2. Let
$\widetilde {\pi }$
be a genuine irreducible positive depth representation of
$\widetilde {G}$
. Then one of the three cases in Definition 10.1 happens.
The following lemma follows from [Reference Bushnell15, Theorem
$2'$
], whose proof can be modified here without change.
Lemma 10.3. There exists a strict fundamental stratum
$[\mathfrak {a}',u',u'-1,b]$
in A, such that the restriction of
$\widetilde {\pi }$
to
$\,_{s}U^{u'}(\mathfrak {a}')$
contains
$\,_{s}\psi _{b}$
.
Starting from this lemma, if the fundamental stratum
$[\mathfrak {a}',u',u'-1,b]$
is split, then by definition,
$\widetilde {\pi }$
contains a split stratum, meaning that we are in case (1) of Definition 10.1.
Otherwise, using [Reference Broussous12, Theorem 1.2.5], there exists a simple stratum
$[\mathfrak {a},u,u-1,\beta ]$
in A, such that the restriction of
$\widetilde {\pi }$
to
$\,_{s}U^{u}(\mathfrak {a})$
contains
$\,_{s}\psi _{\beta }$
. Since
$\mathcal {C}(\mathfrak {a},u-1,\beta )=\{\psi _{\beta }\}$
(cf. [Reference Bushnell and Kutzko19, Proposition 3.2.2]), we have indeed proved that (see also [Reference Sécherre and Stevens66, Proposition 3.19])
Proposition 10.4. Let
$\widetilde {\pi }$
be defined as before. Then either
$\widetilde {\pi }$
contains a split stratum or there exist a simple stratum
$[\mathfrak {a},u,l,\beta ]$
in A and a simple character
$\theta \in \mathcal {C}(\mathfrak {a},l,\beta )$
, such that
$\widetilde {\pi }$
contains
$\,_{s}\theta $
.
Assume that we are in the second case of Proposition 10.4. We also choose
$[\mathfrak {a},u,l,\beta ]$
and
$\theta $
such that the rational number
$l/e(\mathfrak {a}|\mathfrak {o}_{F})$
is minimal.
If
$l=0$
, then we are in case (2) of Definition 10.1.
Now assume that
$l\geq 1$
. We fix a character
$\vartheta $
of
$H^{l}(\beta ,\mathfrak {a})$
extending
$\theta $
, such that
$\widetilde {\pi }$
contains
$\,_{s}\vartheta $
. By the construction of simple characters, there exist
$\theta '\in \mathcal {C}(\mathfrak {a},l-1,\beta )$
and
$c\in \mathfrak {p}_{\mathfrak {a}}^{-l}$
such that
$\vartheta =\theta '\psi _{c}$
. We fix a tame corestriction
$s:A\rightarrow B$
, and we get a derived stratum
$[\mathfrak {b},l,l-1,s(c)]$
in B.
Proposition 10.5.
$[\mathfrak {b},l,l-1,s(c)]$
is a split stratum in B.
The proposition follows from [Reference Bushnell and Kutzko19, §8.1] or [Reference Sécherre and Stevens66, §3]. Indeed, the corresponding argument in loc. cit. essentially concerns only open compact pro-p-groups and their representations. In this case, we have unique splittings for corresponding groups and representations, so the same argument could be modified verbatim to our case without any difficulty.
Thus, in this case,
$\widetilde {\pi }$
contains the split character
$\,_{s}\vartheta =\,_{s}\theta '\,_{s}\psi _{c}$
, saying that we are in case (3) of Definition 10.1.
10.3 Containment of a simple character I, elimination of split strata
The main goal of the following two subsections is to prove the following theorem.
Theorem 10.6. Let
$\widetilde {\pi }$
be a genuine cuspidal positive depth representation of
$\widetilde {G}$
. Then it contains a simple character.
Using Theorem 10.2, the strategy is to show that case (1) and (3) in Definition 10.1 cannot happen.
In this subsection, we sketch the proof in [Reference Broussous12, §2] to eliminate case (1). Assume that
$\widetilde {\pi }$
contains a split stratum, saying that there exists a split stratum
$[\mathfrak {a},u,u-1,b]$
in A, such that
$\widetilde {\pi }$
contains the character
$\,_{s}\psi _{b}\lvert _{\,_{s}U^{u}(\mathfrak {a})}$
. Let
$\Lambda $
be the lattice chain related to
$\mathfrak {a}$
.
By definition, the characteristic polynomial
$\varphi _{b}$
can be written as the product of two relatively prime polynomials
$\varphi _{1}$
and
$\varphi _{2}$
in
$\boldsymbol {k}[X]$
. Write
$y=\varpi _{F}^{u/\operatorname {gcd}(u,e)}b^{e/\operatorname {gcd}(u,e)}\in \mathfrak {a}$
with
$e=e(\mathfrak {a}|\mathfrak {o}_{F})$
. Then using Hensel’s lemma, there exist
$\Phi _{i}\in \mathfrak {o}_{F}[X]$
whose modulo
$\mathfrak {p}_{F}$
reduction is
$\phi _{i}$
for
$i=1,2$
, such that the characteristic polynomial of y in
$A=\operatorname {End}_{F}(V)$
is the product of
$\Phi _{1}$
and
$\Phi _{2}$
.
Write
$V^{i}=\operatorname {Ker}(\Phi _{i}(y))$
for
$i=1,2$
. Then by construction,
$V=V^{1}\oplus V^{2}$
is an E-decomposition with
$E=F[b]$
. Let
$\Lambda ^{i}=\Lambda \cap V^{i}$
be a lattice sequence of
$V^{i}$
for
$i=1,2$
. Then both
$\Lambda $
,
$\Lambda ^{1}$
,
$\Lambda ^{2}$
are E-pure, and we have
$\Lambda =\Lambda ^{1}\oplus \Lambda ^{2}$
(cf. [Reference Broussous12, Proposition 2.2.1]) Let
$A^{ij}=\operatorname {Hom}_{F}(V^{i},V^{j})$
be defined as F-subalgebra of A, let
$M=\operatorname {Aut}_{F}(V^{1})\times \operatorname {Aut}_{F}(V^{2})$
be a Levi subgroup of G.
In [Reference Broussous12, §2.3], an
$\mathfrak {o}_{F}$
-orders
$\mathfrak {h}$
in A is constructed, satisfying
$\mathfrak {h}\cap A^{ii}=\mathfrak {p}_{\mathfrak {a}}^{u}\cap A^{ii}$
,
$\mathfrak {h}\cap A^{12}=\mathfrak {a}\cap A^{12}$
and
$\mathfrak {h}\cap A^{21}=\mathfrak {p}_{\mathfrak {a}}^{u+1}\cap A^{21}$
. Let
$H=1+\mathfrak {h}$
, which is an open compact pro-p-subgroup of G. By definition,
$\psi _{b}$
is a character of H. Extend the character
$\,_{s}\psi _{b}$
of
$\,_{s}H$
to a genuine representation of
$\widetilde {H}$
, which we denote by
$\widetilde {\psi }_{b}$
.
We have the following proposition, which follows directly from [Reference Broussous12, Proposition 2.3.1].
Proposition 10.7. The intertwining set
$I_{G}(\widetilde {\psi }_{b})$
is contained in
$HMH$
.
Then by verifying condition (1)(2)(4),
$(\widetilde {H},\widetilde {\psi }_{b})$
is a covering pair of
$(\widetilde {H}\cap \widetilde {M},\widetilde {\psi }_{b}\lvert _{\widetilde {H}\cap \widetilde {M}})$
.
Using [Reference Broussous12, Proposition 2.4.4], whose statement and proof can be easily adapted to our case,
$\widetilde {\pi }$
contains
$\,_{s}\psi _{b}\lvert _{\,_{s}H}$
and
$\widetilde {\psi }_{b}$
. Let
$P=MN$
be a parabolic of G having a Levi factor M and the unipotent radical N. Then using Theorem 3.4 we have
$$ \begin{align*}0\neq\operatorname{Hom}_{\widetilde{H}}(\widetilde{\pi},\widetilde{\psi}_{b})=\operatorname{Hom}_{\widetilde{H}\cap\widetilde{M}}(r_{N}(\widetilde{\pi}),\widetilde{\psi}_{b}),\end{align*} $$
implying that
$r_{N}(\widetilde {\pi })\neq 0$
and contradicting the fact that
$\widetilde {\pi }$
is cuspidal. So
$\widetilde {\pi }$
cannot contain a split stratum.
10.4 Containment of a simple character II, elimination of split characters
In this subsection, we sketch the proof in [Reference Sécherre and Stevens66, §4] to eliminate case (3). Thus,
$\widetilde {\pi }$
must contain a simple character.
Assume that
$\widetilde {\pi }$
contains a split character, saying that there exist a strict simple stratum
$[\mathfrak {a},u,l,\beta ]$
in A with
$l\geq 1$
, a simple character
$\theta '\in \mathcal {C}(\mathfrak {a},l-1,\beta )$
and
$c\in \mathfrak {p}_{\mathfrak {a}}^{-l}$
such that
-
•
$\widetilde {\pi }$
contains the character
$\,_{s}\vartheta =\,_{s}\theta '\,_{s}\psi _{c}$
of
$\,_{s}H^{l}(\beta ,\mathfrak {a})$
. -
• The derived stratum
$[\mathfrak {b},l,l-1,s(c)]$
in B is split, where
$E=F[\beta ]$
,
$B=\operatorname {End}_{E}(V_{E})$
,
$\mathfrak {b}=\mathfrak {a}\cap B$
and
$s:A\rightarrow B$
is any tame corestriction.
Let
$\Lambda $
be the lattice chain related to
$\mathfrak {a}$
. Being regarded as an
$\mathfrak {o}_E$
-lattice chain and denoted by
$\Lambda _{E}$
, it is the lattice chain related to
$\mathfrak {b}$
.
Following the procedure in §10.3 with
$[\mathfrak {a},u,u-1,b]$
replaced by
$[\mathfrak {b},l,l-1,s(c)]$
, or more precisely using [Reference Sécherre and Stevens66, Proposition 4.9], we may construct a decomposition of E-vector spaces
$V_{E}=V_{E}^{1}\oplus V_{E}^{2}$
that conforms with
$\Lambda _{E}$
. Let
$V=V^{1}\oplus V^{2}$
be the corresponding decomposition of F-vector spaces that conforms with
$\Lambda $
with the same underlying space. Define
$A^{ij}$
and M, and
$P=MN$
as in §10.3. In particular, we choose
$N=I_{r}+A^{12}$
. Let
$\Omega =U^{1}(\mathfrak {b})\Omega _{v-l+1}(\beta ,\mathfrak {a})$
be a pro-p-subgroup of G, where v and
$\Omega _{i}(\beta ,\mathfrak {a})$
are defined as in §5.3. Up to changing c if necessary, we may also assume that
$c=c_{1}+c_{2}$
with
$c_{i}\in A^{ii}$
for
$i=1,2$
.
We extend
$\,_{s}\vartheta $
to a genuine character
$\widetilde {\vartheta }$
of
$\widetilde {H^{l}(\beta ,\mathfrak {a})}$
. So
$\widetilde {\pi }$
contains
$\widetilde {\vartheta }$
. Also
$\Omega $
normalizes
$\widetilde {\vartheta }$
. The following proposition follows from [Reference Sécherre and Stevens66, Théorème 4.3].
Proposition 10.8. The intertwining set
$I_{G}(\widetilde {\vartheta })$
is contained in
$\Omega M\Omega $
.
Let
$K'=H^{l}(\beta ,\mathfrak {a})(\Omega \cap N)$
, which is a pro-p-subgroup of G. By construction, the character
$\vartheta $
is trivial on
$H^{l}(\beta ,\mathfrak {a})\cap N$
. So we extend
$\vartheta $
to a character
$\xi $
of
$K'$
that is trivial on
$\Omega \cap N$
. Let
$\widetilde {\xi }$
be the extension of
$\,_{s}\xi $
to
$\widetilde {K'}$
as a genuine character. Using the argument in [Reference Sécherre and Stevens66, §4.3], which can be modified here directly,
$\widetilde {\pi }$
contains the character
$\widetilde {\xi }$
as well.
We claim that
$(\widetilde {K'},\widetilde {\xi })$
is a covering pair of
$(\widetilde {K'}\cap \widetilde {M},\widetilde {\xi }\lvert _{\widetilde {K'}\cap \widetilde {M}})$
. Condition (1) follows from the Iwahori decomposition of
$H^{i}(\beta ,\mathfrak {a})$
and
$\Omega _{i}(\beta ,\mathfrak {a})$
and condition (2) is direct. We verify condition (3) for the parabolic subgroup
$P=MN$
. Choose an element
$\zeta =\operatorname {diag}(\varpi _{F}^{n}I_{r_{1}},I_{r_{2}})$
with respect to the decomposition
$V=V^{1}\oplus V^{2}$
, where
$r_{i}=\operatorname {dim}_{F}(V^{i})$
for
$i=1,2$
. Then
$\boldsymbol {s}(\zeta )$
is in the center
$Z(\widetilde {M})$
and is strongly
$(\widetilde {P},\widetilde {K'})$
-positive. We need to find an element
$\phi _{\zeta }$
supported on
$\widetilde {K'}\zeta \widetilde {K'}$
that is invertible. This follows from a similar argument of [Reference Bushnell and Kutzko23, Corollary 6.6] as well as [Reference Sécherre and Stevens66, Corollaire 4.6] using Proposition 10.8. For the opposite parabolic subgroup
$P^{-}=MN^{-}$
, we just need to use
$\zeta ^{-1}$
in place of
$\zeta $
.
Using Theorem 3.4 we have
$$ \begin{align*}0\neq\operatorname{Hom}_{\widetilde{K'}}(\widetilde{\pi},\widetilde{\xi})=\operatorname{Hom}_{\widetilde{K'}\cap\widetilde{M}}(r_{N}(\widetilde{\pi}),\widetilde{\xi}),\end{align*} $$
implying that
$r_{N}(\widetilde {\pi })\neq 0$
and contradicting the fact that
$\widetilde {\pi }$
is cuspidal. So
$\widetilde {\pi }$
cannot contain a split character. Thus, Theorem 10.6 is proved.
10.5 From simple characters to simple types
Still, let
$\widetilde {\pi }$
be a genuine cuspidal positive depth representation of
$\widetilde {G}$
. Using Theorem 10.6, we choose a strict simple stratum
$[\mathfrak {a},u,0,\beta ]$
in A and
$\theta \in \mathcal {C}(\mathfrak {a},0,\beta )$
, such that
$\,_{s}\theta $
is contained in
$\widetilde {\pi }$
. In particular, we assume
$\mathfrak {a}$
to be minimal among all the hereditary orders in A that we may choose. We use the abbreviations
$H^{1}$
,
$J^{1}$
, J,
$\boldsymbol {J}$
etc. as in Section 6. We fix a maximal open compact subgroup K that contains
$U(\mathfrak {a})$
, and a splitting
$\boldsymbol {s}$
of K.
Let
$\eta $
be the Heisenberg representation of
$\theta $
and let
$\kappa $
be a
$\beta $
-extension of
$\eta $
. By construction,
$\widetilde {\pi }$
contains
$\,_{s}\eta $
. Moreover, using Frobenius reciprocity,
$\widetilde {\pi }$
contains an irreducible subrepresentation of the induction
$$ \begin{align*}\operatorname{ind}_{\widetilde{J^{1}}}^{\widetilde{J}}(\epsilon\cdot\,_{s}\eta)=\widetilde{\kappa}\otimes\operatorname{ind}_{\widetilde{J^{1}}}^{\widetilde{J}}(\epsilon\cdot\,_{s}1),\end{align*} $$
where
$\,_{s}1$
denotes the identity character of
$\,_{s}J^{1}$
. Then there exist an irreducible representation
$\varrho $
of
$\mathcal {M}=J/J^{1}=U(\mathfrak {b})/U^{1}(\mathfrak {b})$
and the corresponding inflation
$\widetilde {\rho }=\operatorname {Inf}_{\widetilde {\mathcal {M}}}^{\widetilde {J}}(\epsilon \cdot \,_{s}\varrho )$
as a genuine irreducible representation of
$\widetilde {J}$
, such that
$\widetilde {\lambda }:=\widetilde {\kappa }\otimes \widetilde {\rho }$
is contained in
$\widetilde {\pi }$
. Here, we recall that
$\mathcal {M}$
is a Levi subgroup of the finite general linear group
$\operatorname {GL}_{m}(\boldsymbol {l})$
, where
$\boldsymbol {l}$
is the residue field of
$E=F[\beta ]$
,
$d=[E:F]$
and
$m=r/d$
.
Proposition 10.9. The pair
$(\widetilde {J},\widetilde {\lambda })$
is a homogeneous type in
$\widetilde {G}$
, or in other words,
$\varrho $
is a cuspidal representation of
$\mathcal {M}$
.
Proof. The proof follows from [Reference Sécherre and Stevens66, Proposition 5.15]. Assume that
$\varrho $
is not cuspidal. Then, there exist a proper parabolic subgroup
$\mathcal {P}'$
of
$\mathcal {M}$
with
$\mathcal {M}'$
a Levi factor and
$\mathcal {U}'$
its unipotent radical, and a representation
$\varrho '$
of
$\mathcal {M}'$
, such that
$\varrho $
is an irreducible subrepresentation of the parabolic induction
$i_{\mathcal {P}'}^{\mathcal {M}}(\varrho ')$
. We may take an E-pure hereditary order
$\mathfrak {a}'$
in A contained in
$\mathfrak {a}$
and the corresponding hereditary order
$\mathfrak {b}'=\mathfrak {a}'\cap B$
in B, such that the image of
$U(\mathfrak {b}')$
(resp.
$U^{1}(\mathfrak {b}')$
) in the quotient
$\mathcal {M}=U(\mathfrak {b})/U^{1}(\mathfrak {b})$
is
$\mathcal {P}'$
(resp.
$\mathcal {U}'$
). So
$[\mathfrak {a}',u,0,\beta ]$
is also a strict simple stratum in A, and we write
$J^{\prime 1}=J^{1}(\beta ,\mathfrak {a}')$
and
$J'=J(\beta ,\mathfrak {a}')$
for short.
Let
$\theta '\in \mathcal {C}(\mathfrak {a}',0,\beta )$
be the transfer of
$\theta $
and let
$\eta '$
be the Heisenberg representation of
$\theta '$
. Let
$\kappa '$
be the
$\beta $
-extension of
$\eta '$
related to
$\kappa $
and let
$\widetilde {\kappa }'$
be its non-genuine pull-back to
$\widetilde {J'}$
. Let
$\widetilde {\rho }'=\operatorname {Inf}_{\widetilde {\mathcal {M}'}}^{\widetilde {U(\mathfrak {b}')}}(\epsilon \cdot \,_{s}\varrho ')$
be an irreducible representation of
$\widetilde {U(\mathfrak {b}')}$
, which can be extended to representations of
$\widetilde {J}'$
,
$\widetilde {U(\mathfrak {b}')}\widetilde {J^{1}}$
and
$\widetilde {U(\mathfrak {b}')}\widetilde {U^{1}(\mathfrak {a}')}$
(still denoted by
$\widetilde {\rho }'$
), whose restrictions to
$\,_{s}J^{\prime 1}$
,
$\,_{s}J^{1}$
and
$\,_{s}U^{1}(\mathfrak {a}')$
, respectively, are trivial.
The restriction
$\widetilde {\kappa }\lvert _{\widetilde {U(\mathfrak {b}')}\widetilde {J^{1}}}$
is an irreducible representation of
$\widetilde {U(\mathfrak {b}')}\widetilde {J^{1}}$
. Also,
$\widetilde {\rho }'$
is an irreducible subrepresentation of the restriction
$\widetilde {\rho }\lvert _{\widetilde {U(\mathfrak {b}')}\widetilde {J^{1}}}$
, which is because by Frobenius reciprocity,
$\varrho '$
is an irreducible subrepresentation of
$\varrho \lvert _{\mathcal {P}}$
. Since
$\widetilde {\pi }$
contains
$\widetilde {\lambda }$
, it contains
$\widetilde {\kappa }\lvert _{\widetilde {U(\mathfrak {b}')}\widetilde {J^{1}}}\otimes \widetilde {\rho }'$
as well. Let
$\widetilde {\lambda }'=\widetilde {\kappa }'\otimes \widetilde {\rho }'$
be a genuine irreducible representation of
$\widetilde {J'}$
. Then using (5.6), we have
$$ \begin{align*} \operatorname{ind}_{\widetilde{U(\mathfrak{b}')}\widetilde{J^{1}}}^{\widetilde{U(\mathfrak{b}')}\widetilde{U^{1}(\mathfrak{a}')}}(\widetilde{\kappa}\lvert_{\widetilde{U(\mathfrak{b}')}\widetilde{J^{1}}}\otimes\widetilde{\rho}')&\cong\operatorname{ind}_{\widetilde{U(\mathfrak{b}')}\widetilde{J^{1}}}^{\widetilde{U(\mathfrak{b}')}\widetilde{U^{1}(\mathfrak{a}')}}(\widetilde{\kappa}\lvert_{\widetilde{U(\mathfrak{b}')}\widetilde{J^{1}}})\otimes\widetilde{\rho}'\\&\cong\operatorname{ind}_{\widetilde{J'}}^{\widetilde{U(\mathfrak{b}')}\widetilde{U^{1}(\mathfrak{a}')}}(\widetilde{\kappa}')\otimes\widetilde{\rho}'\cong\operatorname{ind}_{\widetilde{J'}}^{\widetilde{U(\mathfrak{b}')}\widetilde{U^{1}(\mathfrak{a}')}}\widetilde{\lambda}'. \end{align*} $$
By Frobenius reciprocity,
$\widetilde {\pi }$
contains
$\widetilde {\lambda }'$
. In particular, it contains
$\,_{s}\theta '$
, which contradicts the minimality of
$\mathfrak {a}$
. So
$\varrho $
is cuspidal.
From now on, we adopt the notation in §6.1. More precisely,
-
• Fix a containment of E-pure hereditary orders
$\mathfrak {a}_{\text {min}}\subset \mathfrak {a}\subset \mathfrak {a}_{\text {max}}$
, such that
$\mathfrak {b}_{\text {min}}=B\cap \mathfrak {a}_{\text {min}}$
is a minimal hereditary order, and
$\mathfrak {b}_{\text {max}}=B\cap \mathfrak {a}_{\text {max}}$
is a maximal hereditary order in B. Let
$\Lambda _{\text {min}}$
and
$\Lambda _{\text {max}}$
be the corresponding lattice chains related to
$\mathfrak {a}_{\text {min}}$
and
$\mathfrak {a}_{\text {max}}$
, respectively. Assume that K contains
$U(\mathfrak {a}_{\text {max}})$
. -
• Fix an E-decomposition
$V=\bigoplus _{i=1}^{t}V^{i}$
that conforms with
$\Lambda $
,
$\Lambda _{\text {max}}$
,
$\Lambda _{\text {min}}$
and is properly subordinate to
$\Lambda $
. Let
$P=MN$
be a corresponding parabolic subgroup with
$M=\prod _{i=1}^{t}\operatorname {Aut}_{F}(V^{i})$
. -
• Write
$r_{i}=\operatorname {dim}_{F}(V^{i})$
and
$m_{i}=\operatorname {dim}_{E}(V^{i}_{E})=\operatorname {dim}_{F}(V^{i})/d$
for each i. Then
$m_{1}+\dots +m_{t}=m$
and
$r_{1}+\dots +r_{t}=r$
. -
• Fix a certain E-basis of
$V_{E}$
to identify B with
$\operatorname {M}_{m}(E)$
, such that
$\mathfrak {b}_{\text {max}}$
is identified with
$\operatorname {M}_{m}(\mathfrak {o}_{E})$
, and
$\mathfrak {b}$
is identified with the standard hereditary order in B with respect to the composition
$m_{1}+\dots +m_{t}=m$
, and
$\mathfrak {b}_{\text {min}}$
is identified with the standard minimal hereditary order in B. -
• For
$i=1,\dots ,t$
, let
$A^{i}=\operatorname {End}_{F}(V^{i})$
(resp.
$B^{i}=\operatorname {End}_{E}(V_{E}^{i})$
) which is identified with a subalgebra of A (resp. B) via the i-th block diagonal embedding. Let
$\mathfrak {a}^{i}=A^{i}\cap \mathfrak {a}$
and
$\mathfrak {b}^{i}=B^{i}\cap \mathfrak {b}$
. -
• Let
$\mathcal {G}^{i}=\operatorname {GL}_{m_{i}}(\boldsymbol {l})\cong U(\mathfrak {b}^{i})/U^{1}(\mathfrak {b}^{i})$
. Then
$$ \begin{align*}\mathcal{P}\cong U(\mathfrak{b})/U^{1}(\mathfrak{b}_{\text{max}})\quad\text{and}\quad\mathcal{M}=\mathcal{G}^{1}\times\dots\times\mathcal{G}^{t}\cong U(\mathfrak{b})/U^{1}(\mathfrak{b})\cong J/J^{1}.\end{align*} $$
-
• Write
$\varrho =\varrho _{1}\boxtimes \dots \boxtimes \varrho _{t}$
, where each
$\varrho _{i}$
is a cuspidal representation of
$\mathcal {G}^{i}$
for
$i=1,\dots ,t$
. -
• Define
$(\widetilde {J_{M}},\widetilde {\lambda }_{M})$
and
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
as in §6.1.
Our next goal is to show that
$(\widetilde {J},\widetilde {\lambda })$
is a twisted simple type. Notice that conjugating by an element in
$W_{0}(B)\subset U(\mathfrak {b}_{\text {min}})$
, we may interchange the position of
$V^{i}$
and
$V^{j}$
in the decomposition
$V=V^{1}\oplus \dots \oplus V^{t}$
for
$1\leq i< j\leq t$
. The related
$(A^{i},B^{i},\mathfrak {a}^{i},\mathfrak {b}^{i},\mathcal {G}^{i},\varrho _{i})$
and
$(A^{j},B^{j},\mathfrak {a}^{j},\mathfrak {b}^{j},\mathcal {G}^{j},\varrho _{j})$
are also interchanged. Then, without loss of generality, we may assume that there exist
$1\leq t'\leq t$
and a cuspidal representation
$\varrho _{0}$
of
$\operatorname {GL}_{m_{1}}(\boldsymbol {l})$
, such that
-
•
$m_{1}=\dots =m_{t'}$
, and for each
$i=1,\cdots ,t'$
, there exists
$s_{i}\in \mathbb {Z}$
such that
$\varrho _{i}\cong \varrho _{0}\cdot (\chi _{\varpi _{E}}\circ \operatorname {det}_{\boldsymbol {l}})^{s_{i}\boldsymbol {d}}$
, where
$\chi _{\varpi _{E}}=\epsilon ((\varpi _{E},\cdot )_{n,E})$
is a character of
$\boldsymbol {l}^{\times }\cong \mathfrak {o}_{E}^{\times }/(1+\mathfrak {p}_{E})$
; -
• For every
$i=t'+1,\dots ,t$
, the representation
$\varrho _{i}$
is not isomorphic to
$\varrho _{0}\cdot (\chi _{\varpi _{E}}\circ \operatorname {det}_{\boldsymbol {l}})^{s_{i}\boldsymbol {d}}$
for any
$s_{i}\in \mathbb {Z}$
.
We want to show that
$t=t'$
. Otherwise, we consider
$W=V^{1}\oplus \dots \oplus V^{t'}$
and
$W'=V^{t'+1}\oplus \dots \oplus V^{t}$
as nonzero F-subspaces of V. Let
$M'=\operatorname {Aut}_{F}(W)\times \operatorname {Aut}_{F}(W')$
be a Levi subgroup of G. Let
$J_{M'}=J_{P}\cap M'$
and let
$\widetilde {\lambda }_{M'}=\widetilde {\lambda }_{P}\lvert _{\widetilde {J_{P}}\cap \widetilde {M'}}$
be a genuine irreducible representation of
$\widetilde {J_{M'}}$
.
Lemma 10.10.
$(\widetilde {J_{P}},\widetilde {\lambda }_{P})$
is a covering pair of
$(\widetilde {J_{M'}},\widetilde {\lambda }_{M'})$
.
Proof. We follow the proof of [Reference Sécherre and Stevens66, Proposition 5.17]. The condition (1)(2) of being a covering pair is easily verified as in loc. cit. We verify condition (4) by estimating
$I_{G}(\widetilde {\lambda }_{P})$
. Using
$\operatorname {ind}_{\widetilde {J_{P}}}^{\widetilde {J}}\widetilde {\lambda }_{P}\cong \widetilde {\lambda }$
, Proposition 6.3 and the Bruhat decomposition
$B^{\times }=U(\mathfrak {b}_{\text {min}})W(B)U(\mathfrak {b}_{\text {min}})$
, we have
$$ \begin{align*}I_{G}(\widetilde{\lambda}_{P})=J_{P}I_{W(B)}(\widetilde{\rho})J_{P}.\end{align*} $$
Using Proposition 6.4,
$w\in I_{W(B)}(\widetilde {\rho })$
implies that
$w\in W(\mathfrak {b})$
and w normalizes
$\widetilde {\rho }\lvert _{\widetilde {M^{0}(\mathfrak {b})}}$
. Write
$w=w_{0}h$
for
$w_{0}\in W_{0}(\mathfrak {b})$
and
$h\in T(\mathfrak {b})$
. Then w normalizes
$\widetilde {\rho }\lvert _{\widetilde {M^{0}(\mathfrak {b})}}$
if and only if
$$ \begin{align} (\varrho_{1}\boxtimes\dots\boxtimes\varrho_{t})^{w_{0}}\cdot\chi_{h}\cong\varrho_{1}\boxtimes\dots\boxtimes\varrho_{t}, \end{align} $$
where
$\chi _{h}:=\epsilon ([h,\cdot ]_{\sim })$
is a character of
$\mathcal {M}=M^{0}(\mathfrak {b})/M^{1}(\mathfrak {b})$
. From our assumption on
$V^{1},\dots ,V^{t}$
and
$\varrho _{1},\dots ,\varrho _{t}$
and formula (6.6), the condition (10.1) happens only if
$w_{0}\in M'$
. As a result, we have
$I_{G}(\widetilde {\lambda }_{P})\subset J_{P}M'J_{P}$
, verifying the condition (4) of being a covering pair.
Let
$P'=M'N'$
be a parabolic subgroup of G having a Levi factor
$M'$
and the unipotent radical
$N'$
, such that
$P'$
contains P. Using Theorem 3.4, we have
$$ \begin{align*}0\neq\operatorname{Hom}_{\widetilde{J}}(\widetilde{\pi},\widetilde{\lambda})=\operatorname{Hom}_{\widetilde{J_{P}}}(\widetilde{\pi},\widetilde{\lambda}_{P})=\operatorname{Hom}_{\widetilde{J_{M'}}}(r_{N'}(\widetilde{\pi}),\widetilde{\lambda}_{M'}),\end{align*} $$
contradicting the fact that
$\widetilde {\pi }$
is cuspidal.
So we must have
$t'=t$
. We let
$m_{0}=m_{1}=\dots =m_{t}$
and
$r_{0}=r_{1}=\dots =r_{t}$
. For each
$i=1,\dots ,t$
, we write
$\varrho _{i}\cong \varrho _{0}\cdot (\chi _{\varpi _{E}}\circ \operatorname {det}_{\boldsymbol {l}})^{s_{i}\boldsymbol {d}}$
for a certain
$s_{i}\in \mathbb {Z}$
. Let
$$ \begin{align*}\varrho_{0}'=\varrho_{0}\cdot(\chi_{\varpi_{E}}\circ\operatorname{det}_{\boldsymbol{l}})^{(s_{1}r_{1}+\dots+s_{t}r_{t})(2\boldsymbol{c}+\boldsymbol{d})}\end{align*} $$
be a cuspidal representation of
$\operatorname {GL}_{m_{0}}(\boldsymbol {l})$
. Using formula (6.6) for
$g_{0}=\operatorname {diag}(\varpi _{E}^{-s_{1}}I_{m_{1}},\ldots \varpi _{E}^{-s_{t}}I_{m_{t}})$
, we have
$$ \begin{align*}\varrho=\varrho_{1}\boxtimes\dots\boxtimes\varrho_{t}\cong(\varrho_{0}'\boxtimes\dots\boxtimes\varrho_{0}')\cdot\chi_{g_{0}}.\end{align*} $$
This implies that
$(\widetilde {J},\widetilde {\lambda })$
is indeed a twisted simple type that is contained in
$\widetilde {\pi }$
.
We have the following proposition, which is interesting in its own right.
Proposition 10.11. For a genuine irreducible representation
$\widetilde {\pi }$
of
$\widetilde {G}$
, if it contains a twisted simple type, then it contains all the related weakly equivalent simple types as well.
Proof. We follow the proof of [Reference Bushnell and Kutzko19, Proposition 8.3.4, 8.3.5] or [Reference Sécherre and Stevens66, Proposition 5.19]. Let
$(\widetilde {J},\widetilde {\lambda })$
be a twisted simple type contained in
$\widetilde {\pi }$
with the notation as above. We claim that
-
• Let
$\Pi (\mathfrak {b})=\begin {pmatrix} & I_{(t-1)m_{0}} \\ \varpi _{E}I_{m_{0}} & \end {pmatrix}\in B^{\times }\cong \operatorname {GL}_{m}(E)$
. Then
$\widetilde {\pi }$
contains
$\widetilde {\lambda }^{\Pi (\mathfrak {b})}\cong \widetilde {\kappa }\otimes \widetilde {\rho }^{\Pi (\mathfrak {b})}$
. -
• If
$\varrho _{i}\ncong \varrho _{i+1}$
for some i, then
$\widetilde {\pi }$
contains
$\widetilde {\lambda }^{\circ }:=\widetilde {\kappa }\otimes \widetilde {\rho }^{\circ }$
, where
$\widetilde {\rho }^{\circ }$
is the inflation of
$$ \begin{align*}\varrho^{\circ}:=\varrho_{1}\boxtimes\dots\boxtimes\varrho_{i-1}\boxtimes\varrho_{i+1}\boxtimes\varrho_{i}\boxtimes\varrho_{i+2}\boxtimes\dots\boxtimes\varrho_{t}.\end{align*} $$
Since
$\Pi (\mathfrak {b})$
and
$W_{0}(\mathfrak {b})$
generate
$W(\mathfrak {b})$
, it is clear that we may use these two claims to finish the proof.
The first claim is direct. We only remark that the statement itself makes sense since
$\Pi (\mathfrak {b})$
normalizes
$\widetilde {\kappa }$
. In particular, we have
$\operatorname {ind}_{\widetilde {J}}^{\widetilde {G}}(\widetilde {\lambda })\cong \operatorname {ind}_{\widetilde {J}}^{\widetilde {G}}(\widetilde {\lambda }^{\Pi (\mathfrak {b})})$
.
For the second claim, we consider the lattice chain
$\Lambda ^{\prime }_{E}$
of
$V_{E}$
of period
$t-1$
, such that
$(\Lambda ^{\prime }_{E})_{j}=(\Lambda _{E})_{j}$
for
$j=1,2,\dots , i-1$
and
$(\Lambda ^{\prime }_{E})_{j}=(\Lambda _{E})_{j+1}$
for
$j=i,\dots ,t-1$
. Then, it relates to a hereditary order
$\mathfrak {a}'$
in A and the standard hereditary order
$\mathfrak {b}'$
in B with respect to the composition
$(m_{0},\dots ,m_{0},2m_{0},m_{0},\dots ,m_{0})$
of m, where
$2m_{0}$
occurs in the i-th coordinate. In particular,
$\mathfrak {b}'$
contains
$\mathfrak {b}$
. Let
$J'=J(\beta ,\mathfrak {a}')$
and
$J^{\prime 1}=J^{1}(\beta ,\mathfrak {a}')$
. Let
$\mathcal {M}'= U(\mathfrak {b}')/U^{1}(\mathfrak {b}')\cong J'/J^{\prime 1}$
, which contains
$\mathcal {P}= U(\mathfrak {b})/U^{1}(\mathfrak {b}')$
as a parabolic subgroup with a Levi factor
$\mathcal {M}=U(\mathfrak {b})/U^{1}(\mathfrak {b})$
.
Let
$\widetilde {\kappa }'$
be the
$\beta $
-extension of
$\widetilde {J'}$
related to
$\widetilde {\kappa }$
, let
$\varrho '=\operatorname {Ind}_{\mathcal {P}}^{\mathcal {M}'}(\varrho )\cong \operatorname {Ind}_{\mathcal {P}}^{\mathcal {M}'}(\varrho ^{\circ })$
be the related parabolic induction, which is irreducible since
$\varrho _{i}\ncong \varrho _{i+1}$
, let
$\widetilde {\rho }'=\operatorname {Inf}_{\widetilde {\mathcal {M}'}}^{\widetilde {J'}}(\epsilon \cdot \,_{s}\varrho ')$
, and let
$\widetilde {\lambda }'=\widetilde {\kappa }'\otimes \widetilde {\rho }'$
be an irreducible representation of
$\widetilde {J'}$
.
We may regard
$\widetilde {\rho }'$
as a representation of
$\widetilde {U(\mathfrak {b}')}\widetilde {U^{1}(\mathfrak {a})}$
that is trivial on
$\,_{s}U^{1}(\mathfrak {a})$
, and
$\widetilde {\rho }$
(resp.
$\widetilde {\rho }^{\circ }$
) as a representation of
$\widetilde {U(\mathfrak {b})}\widetilde {U^{1}(\mathfrak {a})}$
that is trivial on
$\,_{s}U^{1}(\mathfrak {a})$
. Then by definition, we have
$$ \begin{align*}\operatorname{Ind}_{\widetilde{U(\mathfrak{b})}\widetilde{U^{1}(\mathfrak{a})}}^{\widetilde{U(\mathfrak{b}')}\widetilde{U^{1}(\mathfrak{a})}}(\widetilde{\rho})\cong\widetilde{\rho}'\cong\operatorname{Ind}_{\widetilde{U(\mathfrak{b})}\widetilde{U^{1}(\mathfrak{a})}}^{\widetilde{U(\mathfrak{b}')}\widetilde{U^{1}(\mathfrak{a})}}(\widetilde{\rho}^{\circ}).\end{align*} $$
Combining with (5.6), we have
$$ \begin{align*}\operatorname{Ind}_{\widetilde{J}}^{\widetilde{U(\mathfrak{b}')}\widetilde{U^{1}(\mathfrak{a})}}\widetilde{\lambda}\cong\operatorname{Ind}_{\widetilde{U(\mathfrak{b})}\widetilde{J^{\prime 1}}}^{\widetilde{U(\mathfrak{b}')}\widetilde{U^{1}(\mathfrak{a})}}(\widetilde{\lambda}'\lvert_{\widetilde{U(\mathfrak{b})}\widetilde{J^{\prime 1}}})\cong\operatorname{Ind}_{\widetilde{J}}^{\widetilde{U(\mathfrak{b}')}\widetilde{U^{1}(\mathfrak{a})}}\widetilde{\lambda}^{\circ}.\end{align*} $$
Thus, by Frobenius reciprocity,
$\widetilde {\pi }$
contains
$\widetilde {\lambda }$
if and only if it contains
$\widetilde {\lambda }^{\circ }$
, which finishes the proof of the second claim.
Extracting from the above argument, we also have the following interesting corollary.
Corollary 10.12. For two weakly equivalent twisted simple types
$(\widetilde {J},\widetilde {\lambda })$
and
$(\widetilde {J},\widetilde {\lambda }')$
of
$\widetilde {G}$
, we have
$\operatorname {ind}_{\widetilde {J}}^{\widetilde {G}}\widetilde {\lambda }\cong \operatorname {ind}_{\widetilde {J}}^{\widetilde {G}}\widetilde {\lambda }'$
. As a result, we have an isomorphism of Hecke algebras
$\mathcal {H}(\widetilde {G},\widetilde {\lambda })\cong \mathcal {H}(\widetilde {G},\widetilde {\lambda '})$
.
Using Proposition 10.11, we may assume that
$(\widetilde {J},\widetilde {\lambda })$
is indeed a simple type that is contained in
$\widetilde {\pi }$
. We claim that
$(\widetilde {J},\widetilde {\lambda })$
must be a maximal simple type. Otherwise,
$P=MN$
is a proper parabolic subgroup of G. Using Theorem 3.4 and Theorem 6.16, we have
$$ \begin{align*}0\neq\operatorname{Hom}_{\widetilde{J}}(\widetilde{\pi},\widetilde{\lambda})=\operatorname{Hom}_{\widetilde{J_{P}}}(\widetilde{\pi},\widetilde{\lambda}_{P})=\operatorname{Hom}_{\widetilde{J_{M}}}(r_{N}(\widetilde{\pi}),\widetilde{\lambda}_{M}),\end{align*} $$
contradicting the fact that
$\widetilde {\pi }$
is cuspidal. So
$(\widetilde {J},\widetilde {\lambda })$
is indeed a maximal simple type.
At last, the proof of Theorem 8.4.(2) is accomplished.
Acknowledgements
I would like to thank Corinne Blondel, Fan Gao, Max Gurevich, Vincent Sécherre and Chuijia Wang for useful discussions or correspondences. This research was supported by the Israel Science Foundation (grant No. 737/20). Moreover, I would like to thank an anonymous referee for his/her detailed report and pertinent advice.
I would like to express my gratitude to Colin J. Bushnell for his generous encouragement, without which this work would never be able to appear. I hope that it is proper to dedicate it to his memory.
Competing interest
None.
Data availability statement
Data sharing is not applicable to this article as no new data were created or analyzed in this study.
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