• DocumentCode
    1353270
  • Title

    Distributed Covariance Estimation in Gaussian Graphical Models

  • Author

    Wiesel, Ami ; Hero, Alfred O., III

  • Author_Institution
    Sch. of Comput. Sci. & Eng., Hebrew Univ. of Jerusalem, Jerusalem, Israel
  • Volume
    60
  • Issue
    1
  • fYear
    2012
  • Firstpage
    211
  • Lastpage
    220
  • Abstract
    We consider distributed estimation of the inverse covariance matrix in Gaussian graphical models. These models factorize the multivariate distribution and allow for efficient distributed signal processing methods such as belief propagation (BP). The classical maximum likelihood approach to this covariance estimation problem, or potential function estimation in BP terminology, requires centralized computing and is computationally intensive. This motivates suboptimal distributed alternatives that tradeoff accuracy for communication cost. A natural solution is for each node to perform estimation of its local covariance with respect to its neighbors. The local maximum likelihood estimator is asymptotically consistent but suboptimal, i.e., it does not minimize mean squared estimation (MSE) error. We propose to improve the MSE performance by introducing additional symmetry constraints using averaging and pseudolikelihood estimation approaches. We compute the proposed estimates using message passing protocols, which can be efficiently implemented in large scale graphical models with many nodes. We illustrate the advantages of our proposed methods using numerical experiments with synthetic data as well as real world data from a wireless sensor network.
  • Keywords
    Gaussian processes; covariance matrices; graph theory; matrix inversion; maximum likelihood estimation; mean square error methods; message passing; protocols; signal processing; wireless sensor networks; Gaussian graphical models; MSE error; belief propagation; centralized computing; distributed covariance estimation; distributed signal processing method; function estimation; inverse covariance matrix; large scale graphical model; local maximum likelihood estimator; mean squared estimation error; message passing protocols; multivariate distribution; pseudolikelihood estimation approach; wireless sensor networks; Covariance matrix; Graphical models; Maximum likelihood estimation; Network topology; Nickel; Topology; Covariance estimation; distributed signal processing; graphical models;
  • fLanguage
    English
  • Journal_Title
    Signal Processing, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1053-587X
  • Type

    jour

  • DOI
    10.1109/TSP.2011.2172430
  • Filename
    6051525