====== Computational Geometry ======

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====== Presentations ======
  * [[https://cent.felk.cvut.cz/courses/VGE/presentations/ | Submitted presentations]] directory. Names of authors of uploaded presentations are in bold. Do not forget to upload the sources (ppt, tex,...).
  * [[presentation_hints|Presentation hints]]

===== List of available topics =====
Thursday (12:45-14:15)


^ No. ^  Date  ^ Student   ^ Topic ^
|   1.|  4.10. | xxxxxxxx | | 
|   2.| 11.10. | xxxxxxxx | |
|   3.| 18.10. | xxxxxxxx | | 
|   4.| 25.10. | Pultar   | [9a] Convex Hull of a simple polygon: algorithm of [[http://cgm.cs.mcgill.ca/%7Eathens/cs601/Lee.html | Lee]] [PREPARATA 166-171]| 
| ::: | :::    | Čáp      | [9b] Convex Hull of a simple polygon: algorithm of [[http://softsurfer.com/Archive/algorithm_0203/algorithm_0203.htm | Melkman]] | 
|   5.|  1.11. | Vobecký  | [6] Triangular method for planar search (Kirkpatrick's Planar point location) [PREPARATA 57-60, Mount 116-120].| 
| ::: | :::    | Haluza   | [7] Overmars and van Leeuwen algorithm of dynamic convex hull. [PREPARATA 118-125]. Detailed example.| 
|   6.|  8.11. | | | 
|   7.| 15.11. | Tichá    | [8] Beneath-beyond method (horní-dolní) [PREPARATA 131-140]. | 
| ::: | :::    | Sedláček | [11] Diameter of a point set. [PREPARATA 178-183]. | 
|   8.| 22.11. | Tkáč     | [13] Largest empty circle [PREPARATA 248-254]| 
| ::: | :::    | Čajka    | [12] Smallest enclosing circle. [PREPARATA 248-254]   | 
|   9.| 29.11. |          |   | 
|  10.|  6.12. | Hrakova  | [21] Overlap of planar subdivisions. [Berg 33-40] | 
| ::: | :::    | Galajda  | [25] Algorithm for computation of the perimeter of a union of rectangles. [PREPARATA 340-347]| 
|  11.| 13.12. | Očenášek | [18] D&C Algorithm of Delaunay triangulation: DeWall algorithm. [ {{:courses:cg:dewall.pdf|Cignoni}}, [[courses:cg:links:start#papers_-_local | Maur '02, 15-17]]].| 
| ::: | :::    | Brachaczek | [23] (2) Kernel of a Polygon [{{:courses:cg:presentations:p415-lee.pdf|Lee}}]| 
|  12.| 20.12. | Novák    | [37] Partition trees and a simplex method [Berg 335-343]| 
| ::: | :::    | Šilhavý  | [38] Cutting trees [Berg 346-353]| 
|  13.|  3.1.  | Vomastek | [14] k-th order Voronoi diagram. [PREPARATA 242-246].  |
| ::: | :::    | Petrov   | [16] Algoritmy 3D Delaunayovy triangulace.  [MAUR '02].  | 
|  14.| 10.1.  | | | 

Task not chosen: Glomot
/*
<del>[1] 2D range tree construction and range tree search [PREPARATA 77-87, Mount (75-)79-81, Berg 99-120]. Focus on demonstration example or applet. Do not repeat Lecture 3. </del>
<del>[3]  BSP trees in 2D and 3D [Mulmuley 372-382, Berg 249-263]</del>

*/


[[..:start#literature|Literature]]

[Mulmuley] K. Mulmuley. Computational Geometry: An Introduction Through Randomized Algorithms. Prentice Hall, New York, 1993

[Maur] Maur, P: {{ :courses:cg:presentations:maur-dt-3d.zip |Delaunay Triangulation in 3D.}} State of the Art and Concept of Doctoral Thesis, ZCU 2002