Integral and arithmetic structures of alternating (zigzag) numbers An

Abstract

The alternating (zigzag) numbers An, counting the ascending alternating permutations of \1,·s,n\ and defined by the exponential generating function x+ x, admit several classical combinatorial and analytic representations. In this work we unify and extend three complementary structures of An. First, starting from the Stirling number expansion of zigzag numbers, we derive a contour integral representation, as well as a positive Laplace-type integral representation An = 2n ∫0∞ e-y fn(y)\, dy, fn(y) := Σk=0n (-1)k S(n,k) (y2)k, where the kernel fn(y) is the polynomial generating function of Stirling numbers. A continuous interpolation of the discrete product (falling factorial) is introduced subsequently. This provides a direct analytic bridge between set partitions and Laplace asymptotics. Second, using the partial fraction expansion of , we obtain the well-known hyperbolic integral representation A2n+1=1π∫0∞y2n+1(y/2)\,dy, equivalently expressed in classical form for A2n. This representation interprets zigzag numbers as spectral moments associated with half-integer poles. The connection with Fourier analysis and Mellin transforms is also outlined. Finally, combining spectral expansions with Stirling identities, we derive congruence relations modulo primes for An. These results exhibit a dual analytic-combinatorial structure of zigzag numbers, linking partition expansions, trigonometric spectra, and arithmetic properties.