English

Signed Generalized Stirling Polynomials, Nested Sums, and Hyperbolic Secant Integral Identities

Combinatorics 2026-05-29 v2

Abstract

We begin with the observation that the signed generalized Stirling polynomials Pk(m,x)P_k(m,x), which occur in a generalization of Malmsten's integral, reduce to the falling factorials when k=mk=m. The structure of these generalized Stirling polynomials is then used to obtain recurrence relations, gamma--polygamma formulas for the polynomials Pms(m,x)P_{m-s}(m,x), a more transparent proof of a vanishing identity used in earlier closed forms, and a finite approximation to coshπx\cosh \pi x with a corresponding limit formula for π\pi. We also observe that these polynomials occur naturally as signed residues of the equal-period Barnes multiple zeta function, namely Pk(m,x)=(1)km!Ress=m+1kζm+1(s,x)P_k(m,x)=(-1)^k m!\operatorname*{Res}_{s=m+1-k}\zeta_{m+1}(s,x). In addition, we derive the reflection formula Pk(m,m+1x)=(1)kPk(m,x)P_k(m,m+1-x)=(-1)^kP_k(m,x) and use these polynomial identities to obtain explicit identities for Stirling cycle numbers. We then turn to finite nested sums built from the hyperbolic-secant integral sequence χn\chi_n. After the lower bounds are fixed, the nested sums become coefficient-counting problems: the common-lower-bound case gives binomial coefficients, while the staircase case gives Catalan numbers. Combining these counts with the closed forms for the individual χj\chi_j's produces explicit evaluations involving Catalan's constant, zeta values, and polygamma values at one quarter. A Wolfram Language package accompanies the formulas.

Keywords

Cite

@article{arxiv.2605.26846,
  title  = {Signed Generalized Stirling Polynomials, Nested Sums, and Hyperbolic Secant Integral Identities},
  author = {Abdulhafeez A. Abdulsalam and Michael J. Schlosser},
  journal= {arXiv preprint arXiv:2605.26846},
  year   = {2026}
}

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21 pages