We describe a new randomized data structure, the sparse partition, for solving the dynamic closest-pair problem. Using this data structure the closest pair of a set of n points in D-dimensional space, for any fixed D, can be found in constant time. If a frame containing all the points is known in advance, and if the floor function is available at unit cost, then the data structure supports insertions into and deletions from the set in expected O(log n) time and requires expected O(n) space. This method is more efficient than any deterministic algorithm for solving the problem in dimension D > 1. The data structure can be modified to run in O(log(2) n) expected time per update in the algebraic computation tree model. Even this version is mor...
AbstractWe present a linear time randomized sieve algorithm for the closest-pair problem. The algori...
One of the most challenging problems in computational geometry is closest pair of points given n poi...
Let $V$ be a set of $n$ points in $k$-dimensional space. It is shown how the closest pair in $V$ can...
We describe a new randomized data structure, the sparse partition, for solving the dynamic closest-p...
We describe a new randomized data structure, the {\em sparse partition}, for solving the dynamic clo...
We present a conceptually simple, randomized incremental algorithm for finding the closest pair in a...
Given a set S of n points in k-dimensional space, and an L t metric, the dynamic closest pair proble...
Given a set S of n points in k-dimensional space, and an Lt metric, the dynamic closest-pair problem...
We develop data structures for dynamic closest pair problems with arbitrary (not necessarily geometr...
We present simple fully dynamic and kinetic data structures, which are variants of a dynamic 2-dimen...
AbstractIn the k-dimensional rectangular point location problem, we have to store a set of n non-ove...
In the $k$-dimensional rectangular point location problem, we have to store a set of $n$ non-overlap...
. Let S be a set of n points in IR D . It is shown that a range tree can be used to find an L1-neare...
Let $S$ be a set of $n$ points in $D$-dimensional space, where $D$ is a constant, and let $k$ be an ...
We present a general technique for dynamizing certain problems posed on point sets in Euclidean spac...
AbstractWe present a linear time randomized sieve algorithm for the closest-pair problem. The algori...
One of the most challenging problems in computational geometry is closest pair of points given n poi...
Let $V$ be a set of $n$ points in $k$-dimensional space. It is shown how the closest pair in $V$ can...
We describe a new randomized data structure, the sparse partition, for solving the dynamic closest-p...
We describe a new randomized data structure, the {\em sparse partition}, for solving the dynamic clo...
We present a conceptually simple, randomized incremental algorithm for finding the closest pair in a...
Given a set S of n points in k-dimensional space, and an L t metric, the dynamic closest pair proble...
Given a set S of n points in k-dimensional space, and an Lt metric, the dynamic closest-pair problem...
We develop data structures for dynamic closest pair problems with arbitrary (not necessarily geometr...
We present simple fully dynamic and kinetic data structures, which are variants of a dynamic 2-dimen...
AbstractIn the k-dimensional rectangular point location problem, we have to store a set of n non-ove...
In the $k$-dimensional rectangular point location problem, we have to store a set of $n$ non-overlap...
. Let S be a set of n points in IR D . It is shown that a range tree can be used to find an L1-neare...
Let $S$ be a set of $n$ points in $D$-dimensional space, where $D$ is a constant, and let $k$ be an ...
We present a general technique for dynamizing certain problems posed on point sets in Euclidean spac...
AbstractWe present a linear time randomized sieve algorithm for the closest-pair problem. The algori...
One of the most challenging problems in computational geometry is closest pair of points given n poi...
Let $V$ be a set of $n$ points in $k$-dimensional space. It is shown how the closest pair in $V$ can...