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Spectral Graph Theory and Applications Advanced Course WS2011/2012. Thomas Sauerwald He Sun Max Planck Institute for Informatics. Course Information. Time: Wednesday 2:15PM – 4:00PM Location: Room 024, MPI Building
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Spectral Graph Theory and Applications Advanced Course WS2011/2012 Thomas Sauerwald He Sun Max Planck Institute for Informatics
Course Information • Time: Wednesday 2:15PM – 4:00PM • Location: Room 024, MPI Building • Credit: 5 credit points • Lecturers: Thomas Sauerwald, He Sun • Office Hour: Wednesday 10:00AM – 11:00AM • Prerequisites: Basic knowledge of discrete mathematics and linear algebra • Lecture notes: See homepage for weekly update • Homepage: http://www.mpi-inf.mpg.de/departments/d1/teaching/ws11/SGT/index.html
Course Information (contd.) • Grading • Homework (3 problem sets) • You need to collect at least 40% of the homework points to be eligible to take the exam. • The final exam will be based on the homework and lectures.
Topics Max Cut Approximation Algorithms Pseudorandomness Expanders The Unified Theory Random Walks Eigenvalues Cheeger Inequality Complexity
Why do you need this course? Provides a powerful tool for designing randomized algorithms. Gives the basics of Markov chain theory. Covers some of the most important results in the past decade, e.g. derandomization of log-space complexity class. Nicely combines classical graph theory with modern mathematics (geometry, algebra, etc).
Lecture 1 Introduction
Seven Bridges of Königsberg, 1736 L. Euler(1707-1783)
From then on... Connectivity Chromatic number Euler Path Hamiltonian Path Matching Graph homomorphism
Magic graphs: Expanders Combinatorically, expanders are highly connected graphs, i.e., to disconnect a large part of the graph, one has to remove many edges. Geometrically, every vertex set has a large boundary. Probabilistically, expanders are graphs whose behavior is “like” random graphs. Algebraically, expanders correspond to real-symmetric matrices whose first positive eigenvalue of the Laplacian matrix is bounded away from zero.
What is the graph spectrum? Adjacency Matrix Laplacian Matrix Consider a d-regular graph G:
What is the graph spectrum? (contd.) We call the spectrum of graph G. • If A is a real symmetric matrix, then all the eigenvalues are real. • Moreover, if G is a d-regular graph, then .
Applications of graph spectrum In Computer Science In Mathematics • Pseudorandomness • Circuit complexity • Network design • Approximation algorithms • Graph theory • Group theory • Number theory • Algebra
Example 1: Super concentrators There is a long and still ongoing search for super concentrators with n inputs and output vertices and Kn edges with K as small as possible. This “sport” has motivated quite a few important advances in this area. The current “world record” holders are Alon and Capalbo. S. Hoory et al. In: Bulletin of American Mathematical Society, 2006.
Finally, the super concentrators constructed by Valiant in the context of computational complexity established the fundamental role of expander graphs in computation. 2010 ACM Turing Award Citation
History Explicit constructions Only 7 pages for constructions and analysis Existence Proof Lower Bound [Valiant]: 5-o(1) Based on Kolmogorov Complexity
Example 2: Graph Partitioning • Applications • Community detection • Graph partitioning • Machine learning
Example 3: Ramanujan Graphs Ramanujan graphsare graphs having the best expansion ratio.
Ramanujan graphs Big Open Problem: Construct Ramanujan graphs with any degree.
Example 4: Random walks • Applications • Simulation of physical phenomenon • Information spreading on social networks • Approximation of counting problems • Hardness amplification G. Pólya (1887-1985)
Example 4: Random walks A drunk man will eventually return home but a drunk bird will lose its way in space. Theorem (Pólya, 1921) Consider a random walk on an infinite D-dimensional grid. If D = 2, then with probability 1, the walk returns to the starting point an infinite number of times. If D > 2, then with probability 1, the walk returns to the starting point only a finite number of times.
What a random walk! Interviewed on his 90th birthday Pólya stated,"I started studying law, but this I could stand just for one semester. I couldn't stand more. Then I studied languages and literature for two years. After two years I passed an examination with the result I have a teaching certificate for Latin and Hungarian for the lower classes of the gymnasium, for kids from 10 to 14. I never made use of this teaching certificate. And then I came to philosophy, physics, and mathematics. In fact, I came to mathematics indirectly. I was really more interested in physics and philosophy and thought about those. It is a little shortened but not quite wrong to say: I thought I am not good enough for physics and I am too good for philosophy. Mathematics is in between." (Alexanderson, 1979)
Example 5: Randomness Complexity From Art to Science 1415926535897932384626433832795028841971693993751058209749445923078164062862089986280348253421170679821480865132823066470938446095505822317253594081284811174502841027019385211055596446229489549303819644288109756659334461284756482337867831652712019091456485669234603486104543266482133936072602491412737245870066063155881748815209209628292540
Example 5: Randomness Complexity From Art to Science Andrew Yao (1946- ) A.N. Kolmogorov (1903-1987)
Example 5: Randomness Complexity From Art to Science Generate “almost random” sequences using modern computers.