Hankel determinants of weighted binary sums of digits
Abstract
Let sw be the weighted binary sum-of-digits function associated with an arbitrary sequence of complex weights w=(wj)j≥ 0. We investigate Hankel determinants Hw(n) = [sw(i+j)]0≤ i,j<n and derive a general recursion that allows us to effectively compute Hw(n) for all n. Applying it to the ordinary binary sum-of-digits, that is, wj=1, we express Hw(n) in a closed form for several sequences of indices, including the remarkably simple Hw( 2k+2/3)= (-1)(k+2)(k+3)2(k+1). This yields an infinite family of explicit evaluations, giving a partial solution to a problem posed by Allouche and Shallit. Moreover, we closely study the specialization wj=tj, where the determinants become polynomials in t, and investigate their vanishing. For t=2ζ, where ζ is a root of unity, we show that the determinants vanish on a large structured set of indices, while the complementary is sparse but infinite. In addition to Hw(n), we consider Hankel determinants associated with the first difference of sw, obtaining an explicit product formula. This generalizes the results by Fokkink, Kraaikamp, and Shallit concerning Hankel determinants for the period-doubling sequence.
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