On the local Bump-Friedberg L-function
arXiv:1301.0350
Abstract
Let $F$ be a $p$-adic field. If $Ï$ be an irreducible representation of $GL(n,F)$, Bump and Friedberg associated to $Ï$ an Euler fator $L(Ï,BF,s_1,s_2)$ in \cite{BF}, that should be equal to $L(Ï(Ï),s_1)L(Ï(Ï),Î^2,s_2)$, where $Ï(Ï)$ is the Langlands' parameter of $Ï$. The main result of this paper is to show that this equality is true when $(s_1,s_2)=(s+1/2,2s)$, for $s$ in $\C$. To prove this, we classify in terms of distinguished discrete series, generic representations of $GL(n,F)$ which are $Ï_α$-distinguished by the Levi subgroup $GL([(n+1)/2],F) \times GL([n/2],F)$, for $Ï_α(g_1,g_2)=α(det(g_1)/det(g_2))$, where $α$ is a character of $F^*$ of real part between -1/2 and 1/2. We then adapt the technique of \cite{CP} to reduce the proof of the equality to the case of discrete series. The equality for discrete series is a consequence of the relation between linear periods and Shalika periods for discrete series, and the main result of \cite{KR}.
We fixed a problem in the proof of Theorem 3.1, at the cost of making the assumption that $Re(α)$ belongs to $[0,1/2]$ in the statement. This does not affect any other result