32 research outputs found
Trees and Markov convexity
We show that an infinite weighted tree admits a bi-Lipschitz embedding into
Hilbert space if and only if it does not contain arbitrarily large complete
binary trees with uniformly bounded distortion. We also introduce a new metric
invariant called Markov convexity, and show how it can be used to compute the
Euclidean distortion of any metric tree up to universal factors
Metric spaces nonembeddable into Banach spaces with the Radon-Nikod\'ym property and thick families of geodesics
We show that a geodesic metric space which does not admit bilipschitz
embeddings into Banach spaces with the Radon-Nikod\'ym property does not
necessarily contain a bilipschitz image of a thick family of geodesics. This is
done by showing that any thick family of geodesics is not Markov convex, and
comparing this result with results of Cheeger-Kleiner, Lee-Naor, and Li. The
result contrasts with the earlier result of the author that any Banach space
without the Radon-Nikod\'ym property contains a bilipschitz image of a thick
family of geodesics
Metric trees of generalized roundness one
Every finite metric tree has generalized roundness strictly greater than one.
On the other hand, some countable metric trees have generalized roundness
precisely one. The purpose of this paper is to identify some large classes of
countable metric trees that have generalized roundness precisely one.
At the outset we consider spherically symmetric trees endowed with the usual
combinatorial metric (SSTs). Using a simple geometric argument we show how to
determine decent upper bounds on the generalized roundness of finite SSTs that
depend only on the downward degree sequence of the tree in question. By
considering limits it follows that if the downward degree sequence of a SST satisfies , then has generalized roundness one. Included among the
trees that satisfy this condition are all complete -ary trees of depth
(), all -regular trees () and inductive limits
of Cantor trees.
The remainder of the paper deals with two classes of countable metric trees
of generalized roundness one whose members are not, in general, spherically
symmetric. The first such class of trees are merely required to spread out at a
sufficient rate (with a restriction on the number of leaves) and the second
such class of trees resemble infinite combs.Comment: 14 pages, 2 figures, 2 table
Impossibility of dimension reduction in the nuclear norm
Let (the Schatten--von Neumann trace class) denote the Banach
space of all compact linear operators whose nuclear norm
is finite, where
are the singular values of . We prove that
for arbitrarily large there exists a subset
with that cannot be
embedded with bi-Lipschitz distortion into any -dimensional
linear subspace of . is not even a -Lipschitz
quotient of any subset of any -dimensional linear subspace of
. Thus, does not admit a dimension reduction
result \'a la Johnson and Lindenstrauss (1984), which complements the work of
Harrow, Montanaro and Short (2011) on the limitations of quantum dimension
reduction under the assumption that the embedding into low dimensions is a
quantum channel. Such a statement was previously known with
replaced by the Banach space of absolutely summable sequences via the
work of Brinkman and Charikar (2003). In fact, the above set can
be taken to be the same set as the one that Brinkman and Charikar considered,
viewed as a collection of diagonal matrices in . The challenge is
to demonstrate that cannot be faithfully realized in an arbitrary
low-dimensional subspace of , while Brinkman and Charikar
obtained such an assertion only for subspaces of that consist of
diagonal operators (i.e., subspaces of ). We establish this by proving
that the Markov 2-convexity constant of any finite dimensional linear subspace
of is at most a universal constant multiple of