A short proof of Mathar's 2020 recurrence conjecture for the generalized-Stirling sequence A001711

Abstract

For the OEIS sequence A001711, contributed by N. J. A. Sloane long before the on-line era and identified there as the diagonal T(n+4, 4) of a generalized-Stirling triangle, R. J. Mathar contributed in February 2020 the conjectured order-2 P-recursive recurrence \[ a(n) - (2n+5)\,a(n-1) + (n+2)2\,a(n-2) \;=\; 0, n 2. \] We give a one-page proof. Detlefs's harmonic-number closed form a(n) = 14(n+3)!\,(2 Hn+3 - 3) collapses the left-hand side, after dividing through by (n+1)!/4, to a polynomial identity of n with coefficient Hn+2. The harmonic-number coefficient simplifies to (n+3) - (2n+5) + (n+2) = 0 (using Hn+3 = Hn+2 + 1n+3 and Hn+1 = Hn+2 - 1n+2); the constant remainder is -3 · 0 = 0 for the same reason. The supplementary archive contains a SymPy script verifying both pieces symbolically, the e.g.f.\ expansion against the harmonic closed form, and Mathar's recurrence numerically for n = 2, …, 5000.