A reciprocal branching problem for automorphic representations and global Vogan packets

Abstract: Let G be a group and H be a subgroup of G. The classical branching rule (or symmetry breaking) asks: For an irreducible representation π of G, determine the occurrence of an irreducible representation σ of H in the restriction of π to H. The reciprocal branching problem of this classical branching problem is to ask: For an irreducible representation σ of H, find an irreducible representation π of G such that σ occurs in the restriction of π to H. For automorphic representations of classical groups, the branchi… Show more

“…Hence it is a desirable question to find the precise information about the global Arthur parameter of π that gives an answer the Cuspidal Reciprocal Branching Problem! In a recent work of Jiang-Liu-Xu ( [13]), a special situation when H m is SO(3) is explicitly studied. In this case, we are able to prove in some situation that the twisted automorphic descent method may still construct a cuspidal π with generic global Arthur parameter (Theorem 6.3 of [13]).…”

“…In a recent work of Jiang-Liu-Xu ( [13]), a special situation when H m is SO(3) is explicitly studied. In this case, we are able to prove in some situation that the twisted automorphic descent method may still construct a cuspidal π with generic global Arthur parameter (Theorem 6.3 of [13]). We will leave further details of discussion about this mysterious question to our future work.…”

“…(4) In [19], the idea and method of the twisted automorphic descents was used to prove the non-vanishing of certain tensor product L-functions for classical groups. (5) In [13], the twisted automorphic descents were used to test the Branching Problem and the Reciprocal Branching Problem for cuspidal automorphic representations of classical groups.…”

Bessel Descents and Branching Problems

“…Hence it is a desirable question to find the precise information about the global Arthur parameter of π that gives an answer the Cuspidal Reciprocal Branching Problem! In a recent work of Jiang-Liu-Xu ( [13]), a special situation when H m is SO(3) is explicitly studied. In this case, we are able to prove in some situation that the twisted automorphic descent method may still construct a cuspidal π with generic global Arthur parameter (Theorem 6.3 of [13]).…”

“…In a recent work of Jiang-Liu-Xu ( [13]), a special situation when H m is SO(3) is explicitly studied. In this case, we are able to prove in some situation that the twisted automorphic descent method may still construct a cuspidal π with generic global Arthur parameter (Theorem 6.3 of [13]). We will leave further details of discussion about this mysterious question to our future work.…”

“…(4) In [19], the idea and method of the twisted automorphic descents was used to prove the non-vanishing of certain tensor product L-functions for classical groups. (5) In [13], the twisted automorphic descents were used to test the Branching Problem and the Reciprocal Branching Problem for cuspidal automorphic representations of classical groups.…”

Bessel Descents and Branching Problems

Bessel Descents and Branching Problems

On top Fourier coefficients of certain automorphic representations of $${\mathrm {GL}}_n$$