On the Critical Line Re(s) = 1/2, the Irrationality Measure of π, and the Automorphic Structure of the Flint Hills Series
Abstract
We develop, from first principles, a theory connecting the algebra of the Stirling-cosecant decomposition cscq(z) = sumk aq,k Vk(z) + Eq(z) with the irrationality measure mu(pi) and the spectral theory of SL(2, Z), leading to an analogue of the Riemann Hypothesis for the Flint Hills auxiliary series. Part I (Algebra) proves the Master Theorem aq,k = (sin z / z)(-q) * z(q-k), determines denominators via a von Staudt-Clausen product, identifies boundary coefficients as Wallis ratios a2m+1,1 = binomial(2m, m) / 4m, and establishes recurrence and convolution identities. Part II (Analytic number theory) gives the Hurwitz zeta form Hk(s) = sumn Vk(n)/ns, proves sigma(Hk) = k(mu(pi) - 1), and derives F(q,s) converges iff mu(pi) < s/q + 1, recovering the case (2,3). Part III (Automorphic bridges) shows Hk(s) = Ak(s) Kk(1 - s) and Kk(u) = Dk(u) Hk(1 - u), yielding meromorphic continuation with a single pole at s = 1 of residue 2/(pik (k - 1)), and induces a functional equation for D(s, rho; pi). Part IV expresses Xiflk(s; pi) = Hk(s) - (2/(pik (k - 1))) zeta(s) as a spectral sum over Maass-Hecke forms, implying Xiflk(s; pi) = Xiflk(1 - s; pi) for even k >= 2. The critical line Re(s) = 1/2 arises from SL(2, Z) symmetry. Convergence of F(2,3) is equivalent to Xiflk(3; pi) finite, i.e. mu(pi) < 5/2.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.