Near-Optimal Nonmyopic Value of Information in Graphical Models
Abstract
A fundamental issue in real-world systems, such as sensor networks, is the selection of observations which most effectively reduce uncertainty. More specifically, we address the long standing problem of nonmyopically selecting the most informative subset of variables in a graphical model. We present the first efficient randomized algorithm providing a constant factor (1 - 1/e – e) approximation guarantee for any e > 0 with high confidence. The algorithm leverages the theory of submodular functions, in combination with a polynomial bound on sample complexity. We furthermore prove that no polynomial time algorithm can provide a constant factor approximation better than (1 - 1/e) unless P = NP. Finally, we provide extensive evidence of the effectiveness of our method on two complex real-world datasets.
Cite
Text
Krause and Guestrin. "Near-Optimal Nonmyopic Value of Information in Graphical Models." Conference on Uncertainty in Artificial Intelligence, 2005.Markdown
[Krause and Guestrin. "Near-Optimal Nonmyopic Value of Information in Graphical Models." Conference on Uncertainty in Artificial Intelligence, 2005.](https://mlanthology.org/uai/2005/krause2005uai-near/)BibTeX
@inproceedings{krause2005uai-near,
title = {{Near-Optimal Nonmyopic Value of Information in Graphical Models}},
author = {Krause, Andreas and Guestrin, Carlos},
booktitle = {Conference on Uncertainty in Artificial Intelligence},
year = {2005},
pages = {324-331},
url = {https://mlanthology.org/uai/2005/krause2005uai-near/}
}