CSE 533: The PCP Theorem and Hardness of Approximation, Autumn 2005

University of Washington Computer Science & Engineering

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Contact Info

Instructor:

Venkatesan Guruswami and Ryan O'Donnell
Meeting times: MW 10:30-11:50 at Loew Hall, Room 222

Homework

Problem Set 1 -- due Wednesday, November 16. (Updated hard deadline: Wednesday, November 23.)
Solutions available on request

Lecture Notes

Proof of the PCP Theorem -- Lectures 1 through 9 below. This contains a complete proof of the PCP Theorem, except for the proof that the Margulis expander is an an expander.
History of the PCP Theorem -- An aside
Lecture 1 (tex, bib) -- Introduction; statement of PCP Theorem and some hardness of approximation results (scribe: Ryan O'Donnell)
Lecture 2 -- Equivalence of the PCP Theorem and hardness of gapped approximation problems; intro to expanders (scribe: Atri Rudra)
Lecture 3 -- Background on expanders; bird's eye view of PCP theorem proof (scribe: Matt Cary)
Lecture 4 -- Dinur's proof: Degree reduction and expanderizing (scribe: Vibhor Rastogi and Ryan O'Donnell)
Lecture 5 -- Dinur's proof: Powering (Part 1) (scribe: Chris Ré and Ryan O'Donnell)
Lecture 6 -- Dinur's proof: Powering (Part 2); Introduction to Composition/Alphabet reduction (scribe: Anand Ganesh)
Lecture 7 -- Alphabet reduction and Composition theorem (scribe: Anand Ganesh and Venkat Guruswami)
Lecture 8 -- Linearity testing and Assignment testing (scribe: Paul Pham and Venkat Guruswami)
Lecture 9 -- Hadamard code based assignment tester; End PCP theorem proof (scribe: Prasad Raghavendra)
Lecture 10 -- Hardness of approximating clique, FGLSS graph, overview of rest of course (scribe: Ioannis Giotis)
Lecture 11 -- Label Cover, 2P1R games, Parallel Repetition Theorem stated (scribe: Ning Chen)
Feige's NA game counterexample -- An aside
Lecture 12 -- Feige-Kilian "confuse/match" games (Part 1) (scribe: Ning Chen)
Lecture 13 -- Feige-Kilian "confuse/match" games (Part 2) (scribe: Sridhar Srinivasan and Ryan O'Donnell)
Lecture 14 -- Abstraction of Label Cover hardness, Hardness of Set Cover (Scribe: Prasad Raghavendra)
Lecture 15 -- Finish Set Cover hardness, Long Codes and their testing. (Scribe: Atri Rudra)
Lecture 16 -- Hardness of E3-LIN2: Hastad's 3-query PCP (Scribe: Chris Ré)
Lecture 17 -- Goemans-Williamson Max Cut algorithm, 2-query long code test (Scribe: Vibhor Rastogi)
Lecture 18 -- On the Majority Is Stablest theorem and the Unique Games Conjecture (Scribe: Ryan O'Donnell and Paul Pham)
Lecture 19 -- UGC-hardness of Max Cut (Scribe: Ryan O'Donnell and Sridhar Srinivasan)
Lecture 20 -- Course summary and open problems (Scribe: Ioannis Giotis and Ryan O'Donnell)

Scribe file we are using.

Supplementary Reading

Here are a few surveys on hardness of approximation results:
- Hardness of Approximations. An old but still highly useful survey by Sanjeev Arora and Carsten Lund. Good reference for set cover hardness and other early reductions from Label Cover.
- Inapproximability results via Long Code based PCPs by Subhash Khot.
- Inapproximability of Combinatorial Optimization Problems by Luca Trevisan.
The tight inapproximability factor of ln N for set cover (which we mentioned without proof) appears in A Threshold of ln n for Approximating Set Cover by Uri Feige.
The hardness of E3-LIN-2 we presented appears in Johan Hastad's classic Some optimal inapproximability results.
Slides for a survey talk Approximation algorithms based on Semidefinite programming by Uri Feige. Includes extensive discussion of Max CUT.

Course Description

The PCP Theorem states that there is a certain format for writing mathematical proofs, with the following property: a verifier can randomly spot-check only a *constant* number of bits of the proof and yet be convinced of its correctness or fallaciousness with extremely high probability. Further, proofs in this format need only be polynomially longer than they are in "classical" format, and can be produced in polynomial time from the classical proof.

The proof of this theorem in the early 1990's was a great triumph of theoretical computer science, and it became even more important in the mid-1990's when it was shown to be extremely powerful in proving NP-hardness results for *approximate* solutions to optimization problems.

Unfortunately, the known proof of the PCP theorem was extremely complex and also decentralized; even complete courses devoted to it rarely finished all of the proof details. However in April 2005, Irit Dinur completely changed the PCP landscape by giving a self-contained proof taking only a dozen or so pages. (See http://eccc.uni-trier.de/eccc-reports/2005/TR05-046/index.html)

In this course we will prove the PCP Theorem and also gives some of its consequences for hardness of approximation. Topics will be a mix of older work from the 1990's, as well as very recent results on the cutting edge of research, such as:

Dinur's proof
Expander graphs
Fourier analysis of boolean functions
Parallel repetition
Hardness of approximation for linear equations, maximum clique, maximum cut, set cover, and lattice problems
The Unique Games conjecture

Prerequisites: Mathematical maturity is the only prerequisite for this class; familiarity with the basics of probability and NP-completeness is helpful. Coursework will include taking scribe notes and doing one or two problem sets.

Mailing List

It is important to subscribe to the class mailing list immediately. Everyone is expected to be reading cse533 e-mail to keep up-to-date on the course.
To subscribe to the CSE 533 mailing list, visit http://mailman.cs.washington.edu/mailman/listinfo/cse533.


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