Summary.Considered are Hankel, Vandermonde, and Krylov basis matrices.
It is proved that for any real positive definite Hankel matrix
of order
$n$, its spectral condition number is bounded from below
by
$3 \cdot 2^{n-6}$
. Also proved is that the spectral condition
number of a Krylov basis matrix is bounded from below by
$3^{\frac{1}{2}} \cdot 2^{\frac{n}{2}-3}$
. For
$V = V(x_1,
\ldots, x_n)$, a Vandermonde matrix with arbitrary but pairwise
distinct nodes
$x_1, \ldots, x_n$, we show that
$\mbox{\rm
cond}_2\,V
\geq 2^{n-2}/n^{\frac{1}{2}}$; if either
$|x_j| \leq 1$ or
$|x_j| \geq 1$
for all
$j$, then
$\mbox{\rm cond}_2\,V
\geq
2^{n-2}$.
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