Lund University Publications

From Art Galleries to Terrain Modelling --- A Meandering Path through Computational Geometry

• Mark

Abstract

We give approximation and online algorithms as well as data structures for some well studied problems in computational geometry. The thesis is divided into three parts.



In part one, we study problems related to guarding, exploring and searching geometric environments. We show inapproximability results for guarding lines and <i>2</i>-link polygons, question stated time bounds for computing shortest watchman routes and give a competitive strategy for exploring rectilinear polygons. We also give matching upper and lower bounds for two large classes of strategies for searching concurrent rays in parallel.



The second part considers generalisations of the travelling salesman problem. We give... (More)

We give approximation and online algorithms as well as data structures for some well studied problems in computational geometry. The thesis is divided into three parts.



In part one, we study problems related to guarding, exploring and searching geometric environments. We show inapproximability results for guarding lines and <i>2</i>-link polygons, question stated time bounds for computing shortest watchman routes and give a competitive strategy for exploring rectilinear polygons. We also give matching upper and lower bounds for two large classes of strategies for searching concurrent rays in parallel.



The second part considers generalisations of the travelling salesman problem. We give online strategies for the time dependent travelling salesman problem and approximation algorithms and inapproximability results for versions of the kinetic travelling salesman problem. A highlight of the thesis is the exponential lower bound on the approximation ratio for the kinetic travelling salesman problem restricted to expanding point sets.



The last part is devoted to data structures in geographic information systems. We give a pioneer algorithm for constructing R-trees optimised for point location queries. This data structure is used in databases for geometrical objects containing an exceptional amount of data. Finally, bringing the thesis to a close, we suggest a generalisation of the Delaunay triangulation that we call the <i>k</i>-order Delaunay triangulation. This geometric structure corresponds to a similar generalisation of the Voronoi diagram, and is predicted to be of value in automating the removal of artifacts in terrain modelling. (Less)