Bessel Averaging, Fourier Decomposition, and the Value of the Borwein-Bailey-Girgensohn Series
Abstract
We study the Borwein--Bailey--Girgensohn sinusoidal series SBBG = sumn=1∞ (1/n) * ((2+sin n)/3)n, originally posed as an open problem by Borwein, Bailey, and Girgensohn, whose convergence was established by Boppana using the irrationality measure of pi. We present three unconditional results. First, applying the Weyl equidistribution theorem with a quantitative Erdos--Turan bound, we split SBBG = M + R, where M = sumn=1∞ In/n is a Bessel averaging series and |R| < infinity. Second, we evaluate M exactly via Fubini's theorem and the Fourier series of log(1-cos t): M = sumn=1∞ In/n = log 6. Third, we decompose the remainder R into a convergent series of Fourier harmonics: R = sumk=1∞ 2*Re[Gk((2/3)eik)], where each Gk(z) = sumn=1∞ ck(n) zn/n is a Dirichlet-type generating function built from the k-th Fourier coefficients of (theta -> (1 + (sin theta)/2)n). The series converges absolutely because |(2eik)/3| = 2/3 < 1. Numerical computation strongly suggests SBBG = Ei(log 3) = li(3) approx 2.16358...; we reduce this conjecture to a single Diophantine identity for R and indicate the Mellin-transform approach most likely to settle it.
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