A Linear Round Lower Bound for Lovasz-Schrijver SDP Relaxations of Vertex Cover

San Diego, California June 13-March 16

DOI Bookmark:

http://doi.ieeecomputersociety.org/10.1109/CCC.2007.2

Twenty-Second Annual IEEE Conference ...

	This Article
	PURCHASE ARTICLE: $19 PDF HTML IEEE Xplore Subscribers
	Share
	Email this Article to a friend
	Bibliographic References
	ASCII Text BibTex RefWorks Procite/RefMan/Endnote
	Add to:
	Digg Furl Spurl Blink Simpy Google Del.icio.us Y!MyWeb
	Search
	Similar Articles Articles by Grant Schoenebeck Articles by Luca Trevisan Articles by Madhur Tulsiani

	ASCII Text	x
	Grant Schoenebeck, Luca Trevisan, Madhur Tulsiani, "A Linear Round Lower Bound for Lovasz-Schrijver SDP Relaxations of Vertex Cover," Computational Complexity, Annual IEEE Conference on, pp. 205-216, Twenty-Second Annual IEEE Conference on Computational Complexity (CCC'07), 2007.

	BibTex	x
	@article{ 10.1109/CCC.2007.2, author = {Grant Schoenebeck and Luca Trevisan and Madhur Tulsiani}, title = {A Linear Round Lower Bound for Lovasz-Schrijver SDP Relaxations of Vertex Cover}, journal ={Computational Complexity, Annual IEEE Conference on}, volume = {0}, year = {2007}, issn = {1093-0159}, pages = {205-216}, doi = {http://doi.ieeecomputersociety.org/10.1109/CCC.2007.2}, publisher = {IEEE Computer Society}, address = {Los Alamitos, CA, USA}, }

	RefWorks Procite/RefMan/Endnote	x
	TY - CONF JO - Computational Complexity, Annual IEEE Conference on TI - A Linear Round Lower Bound for Lovasz-Schrijver SDP Relaxations of Vertex Cover SN - 1093-0159 SP205 EP216 A1 - Grant Schoenebeck, A1 - Luca Trevisan, A1 - Madhur Tulsiani, PY - 2007 KW - null VL - 0 JA - Computational Complexity, Annual IEEE Conference on ER -

Grant Schoenebeck, UC Berkeley, USA

Luca Trevisan, UC Berkeley, USA

Madhur Tulsiani, UC Berkeley, USA

We study semidefinite programming relaxations of Vertex Cover arising from repeated applications of the LS+ "lift-and-project" method of Lovasz and Schrijver starting from the standard linear programming relaxation.

Goemans and Kleinberg prove that after one round of LS+ the integrality gap remains arbitrarily close to 2. Charikar proves an integrality gap of 2, later strengthened by Hatami, Magen, and Markakis, for stronger relaxations that are, however, incomparable with two rounds of LS+. Subsequent work by Georgiou, Magen, Pitassi, and Tourlakis shows that the integrality gap remains 2 - \varepsilon after \Omega(\sqrt {\frac{{\log n}} {{\log \log n}}} ) rounds [?].

We prove that the integrality gap remains at least 7/6 - \varepsilon after c_{\varepsilon}n rounds, where n is the number of vertices and c_\varepsilon \ge 0 is a constant that depends only on \varepsilon.

Citation:

Grant Schoenebeck, Luca Trevisan, Madhur Tulsiani, "A Linear Round Lower Bound for Lovasz-Schrijver SDP Relaxations of Vertex Cover," ccc, pp.205-216, Twenty-Second Annual IEEE Conference on Computational Complexity (CCC'07), 2007

Peer Review Notice | Give Us Feedback

Usage of this product signifies your acceptance of the Terms of Use.