Computational geometry: an introduction
Computational geometry: an introduction
Computing
Combinatorial optimization: algorithms and complexity
Combinatorial optimization: algorithms and complexity
Discrete Mathematics - Topics on domination
Algorithmic Aspects of Constrained Unit Disk Graphs
Algorithmic Aspects of Constrained Unit Disk Graphs
Towards in-place geometric algorithms and data structures
SCG '04 Proceedings of the twentieth annual symposium on Computational geometry
Optimal in-place and cache-oblivious algorithms for 3-d convex hulls and 2-d segment intersection
Computational Geometry: Theory and Applications
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In this paper, we study the problem of designing in-place algorithms for finding the maximum clique in the intersection graphs of axis-parallel rectangles and disks in 2D. We first propose O (n 2logn ) time in-place algorithms for finding the maximum clique of the intersection graphs of a set of axis-parallel rectangles of arbitrary sizes. For the rectangle intersection graph of fixed height rectangles, the time complexity can be slightly improved to O (n logn +nK ), where K is the size of the maximum clique. For disk graphs, we consider two variations of the maximum clique problem, namely geometric clique and graphical clique. The time complexity of our algorithm for finding the largest geometric clique is O (n 2logn ), and it works for disks of arbitrary radii. For graphical clique, our proposed algorithm works for unit disks (i.e., of same radii) and the worst case time complexity is O (n 2+mK 4); m is the number of edges in the unit disk intersection graph, and K is the size of the largest clique in that graph. It uses O (n 4) time in-place computation of maximum matching in a bipartite graph, which is of independent interest. All these algorithms need O (1) work space in addition to the input array $\cal R$ .