Entrywise bounds for eigenvectors of random graphs
The electronic journal of combinatorics, Tome 16 (2009) no. 1
Let $G$ be a graph randomly selected from ${\bf G}_{n, p}$, the space of Erdős-Rényi Random graphs with parameters $n$ and $p$, where $p \geq {\log^6 n\over n}$. Also, let $A$ be the adjacency matrix of $G$, and $v_1$ be the first eigenvector of $A$. We provide two short proofs of the following statement: For all $i \in [n]$, for some constant $c>0$ $$\left|v_1(i) - {1\over\sqrt{n}}\right| \leq c {1\over\sqrt{n}} {\log n\over\log (np)} \sqrt{{\log n\over np}}$$ with probability $1 - o(1)$. This gives nearly optimal bounds on the entrywise stability of the first eigenvector of (Erdős-Rényi) Random graphs. This question about entrywise bounds was motivated by a problem in unsupervised spectral clustering. We make some progress towards solving that problem.
@article{10_37236_220,
author = {Pradipta Mitra},
title = {Entrywise bounds for eigenvectors of random graphs},
journal = {The electronic journal of combinatorics},
year = {2009},
volume = {16},
number = {1},
doi = {10.37236/220},
zbl = {1186.05109},
url = {http://geodesic.mathdoc.fr/articles/10.37236/220/}
}
Pradipta Mitra. Entrywise bounds for eigenvectors of random graphs. The electronic journal of combinatorics, Tome 16 (2009) no. 1. doi: 10.37236/220
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