35 research outputs found
On Strong Diameter Padded Decompositions
Given a weighted graph G=(V,E,w), a partition of V is Delta-bounded if the diameter of each cluster is bounded by Delta. A distribution over Delta-bounded partitions is a beta-padded decomposition if every ball of radius gamma Delta is contained in a single cluster with probability at least e^{-beta * gamma}. The weak diameter of a cluster C is measured w.r.t. distances in G, while the strong diameter is measured w.r.t. distances in the induced graph G[C]. The decomposition is weak/strong according to the diameter guarantee.
Formerly, it was proven that K_r free graphs admit weak decompositions with padding parameter O(r), while for strong decompositions only O(r^2) padding parameter was known. Furthermore, for the case of a graph G, for which the induced shortest path metric d_G has doubling dimension ddim, a weak O(ddim)-padded decomposition was constructed, which is also known to be tight. For the case of strong diameter, nothing was known.
We construct strong O(r)-padded decompositions for K_r free graphs, matching the state of the art for weak decompositions. Similarly, for graphs with doubling dimension ddim we construct a strong O(ddim)-padded decomposition, which is also tight. We use this decomposition to construct (O(ddim),O~(ddim))-sparse cover scheme for such graphs. Our new decompositions and cover have implications to approximating unique games, the construction of light and sparse spanners, and for path reporting distance oracles
Steiner Point Removal with Distortion
In the Steiner point removal (SPR) problem, we are given a weighted graph
and a set of terminals of size . The objective is to
find a minor of with only the terminals as its vertex set, such that
the distance between the terminals will be preserved up to a small
multiplicative distortion. Kamma, Krauthgamer and Nguyen [KKN15] used a
ball-growing algorithm with exponential distributions to show that the
distortion is at most . Cheung [Che17] improved the analysis of
the same algorithm, bounding the distortion by . We improve the
analysis of this ball-growing algorithm even further, bounding the distortion
by
On Strong Diameter Padded Decompositions
Given a weighted graph , a partition of is -bounded if
the diameter of each cluster is bounded by . A distribution over
-bounded partitions is a -padded decomposition if every ball of
radius is contained in a single cluster with probability at
least . The weak diameter of a cluster is measured
w.r.t. distances in , while the strong diameter is measured w.r.t. distances
in the induced graph . The decomposition is weak/strong according to the
diameter guarantee.
Formerly, it was proven that free graphs admit weak decompositions with
padding parameter , while for strong decompositions only padding
parameter was known. Furthermore, for the case of a graph , for which the
induced shortest path metric has doubling dimension , a weak
-padded decomposition was constructed, which is also known to be tight.
For the case of strong diameter, nothing was known.
We construct strong -padded decompositions for free graphs,
matching the state of the art for weak decompositions. Similarly, for graphs
with doubling dimension we construct a strong -padded decomposition,
which is also tight. We use this decomposition to construct
-sparse cover scheme for such graphs. Our new
decompositions and cover have implications to approximating unique games, the
construction of light and sparse spanners, and for path reporting distance
oracles
Labeled Nearest Neighbor Search and Metric Spanners via Locality Sensitive Orderings
Chan, Har-Peled, and Jones [SICOMP 2020] developed locality-sensitive
orderings (LSO) for Euclidean space. A -LSO is a collection
of orderings such that for every there is an
ordering , where all the points between and w.r.t.
are in the -neighborhood of either or . In essence, LSO
allow one to reduce problems to the -dimensional line. Later, Filtser and Le
[STOC 2022] developed LSO's for doubling metrics, general metric spaces, and
minor free graphs.
For Euclidean and doubling spaces, the number of orderings in the LSO is
exponential in the dimension, which made them mainly useful for the low
dimensional regime. In this paper, we develop new LSO's for Euclidean,
, and doubling spaces that allow us to trade larger stretch for a much
smaller number of orderings. We then use our new LSO's (as well as the previous
ones) to construct path reporting low hop spanners, fault tolerant spanners,
reliable spanners, and light spanners for different metric spaces.
While many nearest neighbor search (NNS) data structures were constructed for
metric spaces with implicit distance representations (where the distance
between two metric points can be computed using their names, e.g. Euclidean
space), for other spaces almost nothing is known. In this paper we initiate the
study of the labeled NNS problem, where one is allowed to artificially assign
labels (short names) to metric points. We use LSO's to construct efficient
labeled NNS data structures in this model