Solvability of the Hankel determinant problem for real sequences

Abstract

To each nonzero sequence s:= \sn\n ≥ 0 of real numbers we associate the Hankel determinants Dn = Hn of the Hankel matrices Hn:= (si + j)i, j = 0n, n ≥ 0, and the nonempty set Ns:= \n ≥ 1 \, | \, Dn-1 ≠ 0 \. We also define the Hankel determinant polynomials P0:=1, and Pn, n≥ 1 as the determinant of the Hankel matrix Hn modified by replacing the last row by the monomials 1, x, …, xn. Clearly Pn is a polynomial of degree at most n and of degree n if and only if n∈ Ns . Kronecker established in 1881 that if Ns is finite then rank Hn = r for each n ≥ r-1, where r := Ns . By using an approach suggested by I.S.Iohvidov in 1969 we give a short proof of this result and a transparent proof of the conditions on a real sequence \tn\n≥ 0 to be of the form tn=Dn, n≥ 0 for a real sequence \sn\n≥ 0. This is the Hankel determinant problem. We derive from the Kronecker identities that each Hankel determinant polynomial Pn satisfying degPn = n≥ 1 is preceded by a nonzero polynomial Pn-1 whose degree can be strictly less than n-1 and which has no common zeros with Pn . As an application of our results we obtain a new proof of a recent theorem by Berg and Szwarc about positive semidefiniteness of all Hankel matrices provided that D0 > 0, …, Dr-1 > 0 and Dn=0 for all n≥ r.