284 research outputs found
Total Curvature of Graphs after Milnor and Euler
We define a new notion of total curvature, called net total curvature, for
finite graphs embedded in Rn, and investigate its properties. Two guiding
principles are given by Milnor's way of measuring the local crookedness of a
Jordan curve via a Crofton-type formula, and by considering the double cover of
a given graph as an Eulerian circuit. The strength of combining these ideas in
defining the curvature functional is (1) it allows us to interpret the
singular/non-eulidean behavior at the vertices of the graph as a superposition
of vertices of a 1-dimensional manifold, and thus (2) one can compute the total
curvature for a wide range of graphs by contrasting local and global properties
of the graph utilizing the integral geometric representation of the curvature.
A collection of results on upper/lower bounds of the total curvature on
isotopy/homeomorphism classes of embeddings is presented, which in turn
demonstrates the effectiveness of net total curvature as a new functional
measuring complexity of spatial graphs in differential-geometric terms.Comment: Most of the results contained in "Total curvature and isotopy of
graphs in ."(arXiv:0806.0406) have been incorporated into the current
articl
On Geometric Spanners of Euclidean and Unit Disk Graphs
We consider the problem of constructing bounded-degree planar geometric
spanners of Euclidean and unit-disk graphs. It is well known that the Delaunay
subgraph is a planar geometric spanner with stretch factor C_{del\approx
2.42; however, its degree may not be bounded. Our first result is a very
simple linear time algorithm for constructing a subgraph of the Delaunay graph
with stretch factor \rho =1+2\pi(k\cos{\frac{\pi{k)^{-1 and degree bounded by
, for any integer parameter . This result immediately implies an
algorithm for constructing a planar geometric spanner of a Euclidean graph with
stretch factor \rho \cdot C_{del and degree bounded by , for any integer
parameter . Moreover, the resulting spanner contains a Euclidean
Minimum Spanning Tree (EMST) as a subgraph. Our second contribution lies in
developing the structural results necessary to transfer our analysis and
algorithm from Euclidean graphs to unit disk graphs, the usual model for
wireless ad-hoc networks. We obtain a very simple distributed, {\em
strictly-localized algorithm that, given a unit disk graph embedded in the
plane, constructs a geometric spanner with the above stretch factor and degree
bound, and also containing an EMST as a subgraph. The obtained results
dramatically improve the previous results in all aspects, as shown in the
paper
Distributed Construction of Lightweight Spanners for Unit Ball Graphs
Resolving an open question from 2006 [Damian et al., 2006], we prove the existence of light-weight bounded-degree spanners for unit ball graphs in the metrics of bounded doubling dimension, and we design a simple ?(log^*n)-round distributed algorithm in the LOCAL model of computation, that given a unit ball graph G with n vertices and a positive constant ? < 1 finds a (1+?)-spanner with constant bounds on its maximum degree and its lightness using only 2-hop neighborhood information. This immediately improves the best prior lightness bound, the algorithm of Damian, Pandit, and Pemmaraju [Damian et al., 2006], which runs in ?(log^*n) rounds in the LOCAL model, but has a ?(log ?) bound on its lightness, where ? is the ratio of the length of the longest edge to the length of the shortest edge in the unit ball graph. Next, we adjust our algorithm to work in the CONGEST model, without changing its round complexity, hence proposing the first spanner construction for unit ball graphs in the CONGEST model of computation. We further study the problem in the two dimensional Euclidean plane and we provide a construction with similar properties that has a constant average number of edge intersections per node. Lastly, we provide experimental results that confirm our theoretical bounds, and show an efficient performance from our distributed algorithm compared to the best known centralized construction
The Traveling Salesman Problem Under Squared Euclidean Distances
Let be a set of points in , and let be a
real number. We define the distance between two points as
, where denotes the standard Euclidean distance between
and . We denote the traveling salesman problem under this distance
function by TSP(). We design a 5-approximation algorithm for TSP(2,2)
and generalize this result to obtain an approximation factor of
for and all .
We also study the variant Rev-TSP of the problem where the traveling salesman
is allowed to revisit points. We present a polynomial-time approximation scheme
for Rev-TSP with , and we show that Rev-TSP is APX-hard if and . The APX-hardness proof carries
over to TSP for the same parameter ranges.Comment: 12 pages, 4 figures. (v2) Minor linguistic change
On boundedness of zeros of the independence polynomial of tor
We study boundedness of zeros of the independence polynomial of tori for
sequences of tori converging to the integer lattice. We prove that zeros are
bounded for sequences of balanced tori, but unbounded for sequences of highly
unbalanced tori. Here balanced means that the size of the torus is at most
exponential in the shortest side length, while highly unbalanced means that the
longest side length of the torus is super exponential in the product over the
other side lengths cubed. We discuss implications of our results to the
existence of efficient algorithms for approximating the independence polynomial
on tori.Comment: 45 pages, 5 figure
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