Efficient Learning by Directed Acyclic Graph For Resource Constrained Prediction
Abstract
We study the problem of reducing test-time acquisition costs in classification systems. Our goal is to learn decision rules that adaptively select sensors for each example as necessary to make a confident prediction. We model our system as a directed acyclic graph (DAG) where internal nodes correspond to sensor subsets and decision functions at each node choose whether to acquire a new sensor or classify using the available measurements. This problem can be naturally posed as an empirical risk minimization over training data. Rather than jointly optimizing such a highly coupled and non-convex problem over all decision nodes, we propose an efficient algorithm motivated by dynamic programming. We learn node policies in the DAG by reducing the global objective to a series of cost sensitive learning problems. Our approach is computationally efficient and has proven guarantees of convergence to the optimal system for a fixed architecture. In addition, we present an extension to map other budgeted learning problems with large number of sensors to our DAG architecture and demonstrate empirical performance exceeding state-of-the-art algorithms for data composed of both few and many sensors.
Keywords
Cite
@article{arxiv.1510.07609,
title = {Efficient Learning by Directed Acyclic Graph For Resource Constrained Prediction},
author = {Joseph Wang and Kirill Trapeznikov and Venkatesh Saligrama},
journal= {arXiv preprint arXiv:1510.07609},
year = {2015}
}
Comments
To appear in NIPS 2015