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(Untitled, Till Rickert,
Shift 2005
Calendar.)
CS 274
Computational Geometry
Jonathan Shewchuk and
Marc Khoury
Spring 2015
Mondays and Wednesdays, 5:30-7:00 pm
320 Soda Hall
Jonathan's office hours:
Mondays, 2:10-3 pm, 510 Soda Hall, and by appointment
(I'm usually free after the lectures too.)
Marc's office hours:
Tuesdays, 2:10-3 pm, 510 Soda Hall
Combinatorial geometry:
Polygons, polytopes, triangulations and simplicial complexes,
planar and spatial subdivisions.
Constructions: triangulations of polygons and point sets,
convex hulls, intersections of halfspaces,
Voronoi diagrams, Delaunay triangulations,
arrangements of lines and hyperplanes, Minkowski sums,
Reeb graphs and contour trees;
relationships among them.
Geometric duality and polarity.
Numerical predicates and constructors.
Upper Bound Theorem, Zone Theorem.
Algorithms and analyses:
Sweep algorithms, incremental construction, divide-and-conquer algorithms,
randomized algorithms, backward analysis,
geometric robustness.
Construction of triangulations, convex hulls, halfspace intersections,
Voronoi diagrams, Delaunay triangulations, arrangements, Minkowski sums, and
Reeb graphs.
Geometric data structures: Doubly-connected edge lists, quad-edges,
face lattices, trapezoidal maps, conflict graphs, history DAGs,
spatial search trees (a.k.a. range search),
binary space partitions, quadtrees and octrees, visibility graphs.
Applications:
Line segment intersection and overlay of subdivisions for
cartography and solid modeling.
Triangulation for graphics, interpolation, and terrain modeling.
Nearest neighbor search, small-dimensional linear programming,
database queries, point location queries, windowing queries,
discrepancy and sampling in ray tracing,
robot motion planning.
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Here are
Homework 1,
Homework 2,
Homework 3,
Homework 4, and
Homework 5.
The best related sites:
Resources for dealing with robustness problems
(in increasing order of difficulty):
Textbook
Mark de Berg,
Otfried Cheong,
Marc van Kreveld, and
Mark Overmars,
Computational Geometry: Algorithms and Applications,
third edition, Springer-Verlag, 2008.
ISBN # 978-3-540-77973-5.
Known throughout the community as the Dutch Book.
Highly recommended; it's one of the best-written textbooks I've ever read.
Note that one lecture will cover material available only in the third edition
(BSP trees for low-density scenes; Section 12.5);
earlier editions of the Dutch Book will probably suffice for everything else.
Lectures
The following schedule is tentative; changes are possible.
Chapter headings refer to the third edition.
Homeworks will be irregularly assigned,
and are due at the start of class.
Homeworks are mostly to be done alone,
without help from or discussion with other humans;
but each homework has one or two group problems,
which you may do with one or two other students.
(See Homework 1 for detailed rules.)
|
Topic |
Readings |
Assignment Due |
| 1: January 21 |
Two-dimensional convex hulls |
Chapter 1, Erickson notes |
. |
|
| 2: January 26 |
Line segment intersection |
Sections 2, 2.1 |
. |
| 3: January 28 |
Overlay of planar subdivisions |
Sections 2.2, 2.3, 2.5 |
. |
|
| 4: February 2 |
Polygon triangulation |
Sections 3.2–3.4 |
. |
| 5: February 4 |
Delaunay triangulations |
Sections 9–9.2;
my
Chapter 2 |
. |
|
| 6: February 9 |
Delaunay triangulations |
Sections 9.3, 9.4, 9.6 |
. |
| 7: February 11 |
Voronoi diagrams |
Sections 7, 7.1, 7.5 |
. |
|
| February 16 |
Presidents' Day |
. |
. |
| 8: February 18 |
Planar point location |
Chapter 6 |
Homework 1 |
|
| 9: February 23 |
Duality; line arrangements |
Sections 8.2, 8.3 |
. |
| 10: February 25 |
Zone Theorem; discrepancy |
Sections 8.1, 8.4 |
. |
|
| 11: March 2 |
Polytopes |
Matoušek Chapter 5 |
. |
| 12: March 4 |
Polytopes and triangulations |
Seidel
Upper
Bound Theorem |
Homework 2 |
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| 13: March 9 |
Small-dimensional linear programming |
Seidel T.R.;
Sections 4.3, 4.6 |
. |
| 14: March 11 |
Small-dimensional linear programming |
Section 4.4; Seidel appendix |
. |
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| 15: March 16 |
Higher-dimensional convex hulls |
Seidel T.R.; Secs. 11.2 and 11.3 |
. |
| 16: March 18 |
Higher-dimensional Voronoi; point in polygon |
Secs. 11.4, 11.5 |
. |
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| March 23–27 |
Spring Recess |
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| 17: March 30 |
k-d trees |
Sections 5–5.2 |
. |
| 18: April 1 |
Range trees |
Sections 5.3–5.6 |
Homework 3 |
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| 19: April 6 |
Interval trees; closest pair in point set |
Sections 10–10.1;
Smid Sec. 2.4.3 |
. |
| 20: April 8 |
Segment trees |
Section 10.3 |
. |
|
| 21: April 13 |
Geometric robustness |
Lecture notes |
. |
| 22: April 15 |
Binary space partitions |
Sections 12–12.3 |
Homework 4 |
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| 23: April 20 |
Binary space partitions |
Section 12.5 |
. |
| 24: April 22 |
BSP applications; nearest neighbors |
Section 2.4;
BSP FAQ;
Arya et al.
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. |
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| 25: April 27 |
Motion planning; Minkowski sums |
Sections 13–13.4 |
Project |
| 26: April 29 |
Visibility graphs |
Chapter 15; Khuller notes |
. |
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| 27: May 4 |
Reeb graphs (and contour trees) |
Harvey et al. |
Homework 5 |
For January 21, here are
Jeff Erickson's
lecture notes on two-dimensional convex hulls.
For February 4, you might (optionally) also be interested in
Chapter
2 from my book:
Siu-Wing Cheng, Tamal Krishna Dey, and Jonathan Richard Shewchuk,
Delaunay Mesh Generation,
CRC Press (Boca Raton, Florida), December 2012.
For March 2 and 4, if you want to supplement my lectures,
most of the material comes from Chapter 5 of
Jirí Matoušek,
Lectures on Discrete Geometry, Springer (New York), 2002,
ISBN # 0387953744.
He has several chapters online; unfortunately Chapter 5 isn't one of them.
For March 4, I will hand out
Raimund Seidel,
The Upper Bound Theorem for Polytopes: An Easy Proof of
Its Asymptotic Version,
Computational Geometry: Theory and Applications 5:115–116, 1985.
Don't skip the abstract: the main theorem and its proof are both given in
their entirety in the abstract, and are not reprised in the body at all.
Seidel's linear programming algorithm (March 9 & 11),
the Clarkson–Shor convex hull construction algorithm (March 16), and
Chew's linear-time algorithm for Delaunay triangulation of convex polygons
are surveyed in
Raimund Seidel,
Backwards Analysis of Randomized Geometric Algorithms,
Technical Report TR-92-014, International Computer Science Institute,
University of California at Berkeley, February 1992.
Warning: online paper is missing the figures.
I'll hand out a version with figures in class.
For March 11, I will hand out the appendix from
Raimund Seidel,
Small-Dimensional Linear Programming and Convex Hulls Made Easy,
Discrete & Computational Geometry 6(5):423–434, 1991.
For anyone who wants to implement the linear programming algorithm,
I think this appendix is a better guide than the Dutch Book.
On April 6, I will teach a randomized closest pair algorithm from
Section 2.4.3 of Michiel Smid,
Closest-Point Problems in Computational Geometry,
Chapter 20,
Handbook on Computational Geometry, J. R. Sack and J. Urrutia (editors),
Elsevier, pp. 877–935, 2000.
Note that this is a long paper, and you only need pages 12–13.
For April 13, here are my
Lecture Notes on
Geometric Robustness.
For April 22, here is the
BSP FAQ, and
here is
Sunil Arya,
David M. Mount, Nathan S. Netanyahu, Ruth Silverman, and Angela Y. Wu,
An Optimal Algorithm for Approximate Nearest Neighbor Searching in
Fixed Dimensions,
Journal of the ACM 45(6):891–923, November 1998.
For April 29, here are
Samir Khuller's notes on visibility graphs.
For May 4, I will hand out
William Harvey,
Yusu Wang, and Rephael Wenger,
A Randomized O(m log m) Time Algorithm for Computing
Reeb Graphs of Arbitrary Simplicial Complexes,
Proceedings of the Twenty-Sixth Annual Symposium on Computational Geometry,
pages 267–276.
For the Project, read
Leonidas J. Guibas and Jorge Stolfi,
Primitives for the Manipulation of General Subdivisions and
the Computation of Voronoi Diagrams,
ACM Transactions on Graphics 4(2):74–123, April 1985.
Feel free to skip Section 3, but read the rest of the paper.
See also
this list of errors in the Guibas and Stolfi paper, and
Paul Heckbert,
Very Brief Note on Point Location in Triangulations,
December 1994.
(The problem Paul points out can't happen in a Delaunay triangulation,
but it's a warning in case you're ever tempted
to use the Guibas and Stolfi walking-search subroutine
in a non-Delaunay triangulation.)
Geometry Applets
These applets can be quite helpful in establishing your geometric intuition
for several basic geometric structures and concepts.
Prerequisites
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CS 170 (Advanced Algorithms) or the equivalent.
In particular, you should know and understand
amortized analysis;
how to solve recurrences;
sorting algorithms;
graph algorithms like Dijkstra's shortest path algorithm,
connected components, and topological sorting;
and basic data structures like binary heaps, hash tables,
and balanced binary search trees
(splay trees or AVL trees or red-black trees or 2-3-4 trees or B-trees).
Every one of these will make an appearance at least once.
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A basic course in probability.
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Experience doing mathematical proofs.
If you've never taken a class where you did lots of proofs,
consider working your way through
Bruce
Ikenaga's notes and
Larry
Cusick's notes and exercises.
Grading
Supported in part by the National Science Foundation
under Awards ACI-9875170, CMS-9980063, CCR-0204377, CCF-0430065, CCF-0635381,
IIS-0915462, CCF-1423560, and EIA-9802069,
in part by a gift from the Okawa Foundation, and
in part by an Alfred P. Sloan Research Fellowship.
(Radiolarian Color Painting.
Ernst
Haeckel, zoologist, 1834–1919.)
