K-spherical horospherical averages on the Nagao quotient: tree combinatorics and exact discrepancy

Abstract

Let \[ F=Fq(\!(t-1)\!), G=SL2(F), Γ=SL2(Fq[t]), X=Γ G, \] and let K=SL2(O), where O=Fq[\![t-1]\!]. We study right K-spherical averages along the upper unipotent subgroup, the horospherical subgroup associated with the standard cusp, on the Nagao lattice quotient. The basic observation is that the K-spherical projection converts two natural dynamical families - expanding translates of compact unipotent orbits and cusp-adapted truncations of dense unipotent orbits - into the same rooted descendant problem on the Bruhat--Tits tree. In the even bipartite sector the limiting height law is the explicit probability measure \[ ρev(0)=q-1q, ρev(2m)=(q2-1)q-2m-1 (m 1). \] We prove an exact discrepancy formula: in the backward state the error is a pure top-shell term minus a missing tail, while in the forward state the error is a first-turn weighted sum of backward errors. These formulas give quantitative K-spherical equidistribution for expanding translates of compact U-orbits and for dense-orbit truncations. For compactly supported K-spherical observables in the expanding translates of compact orbits, the discrepancy is eventually exactly zero. In the dense case the rate is controlled by the continued-fraction expansion of the boundary point attached to the orbit.

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