Quantifying and Reducing Bias in Maximum Likelihood Estimation of Structured Anomalies
July 15, 2020 ยท Declared Dead ยท ๐ International Conference on Machine Learning
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Authors
Uthsav Chitra, Kimberly Ding, Jasper C. H. Lee, Benjamin J. Raphael
arXiv ID
2007.07878
Category
cs.LG: Machine Learning
Cross-listed
cs.IT,
math.ST,
stat.ML
Citations
5
Venue
International Conference on Machine Learning
Last Checked
4 months ago
Abstract
Anomaly estimation, or the problem of finding a subset of a dataset that differs from the rest of the dataset, is a classic problem in machine learning and data mining. In both theoretical work and in applications, the anomaly is assumed to have a specific structure defined by membership in an $\textit{anomaly family}$. For example, in temporal data the anomaly family may be time intervals, while in network data the anomaly family may be connected subgraphs. The most prominent approach for anomaly estimation is to compute the Maximum Likelihood Estimator (MLE) of the anomaly; however, it was recently observed that for normally distributed data, the MLE is a $\textit{biased}$ estimator for some anomaly families. In this work, we demonstrate that in the normal means setting, the bias of the MLE depends on the size of the anomaly family. We prove that if the number of sets in the anomaly family that contain the anomaly is sub-exponential, then the MLE is asymptotically unbiased. We also provide empirical evidence that the converse is true: if the number of such sets is exponential, then the MLE is asymptotically biased. Our analysis unifies a number of earlier results on the bias of the MLE for specific anomaly families. Next, we derive a new anomaly estimator using a mixture model, and we prove that our anomaly estimator is asymptotically unbiased regardless of the size of the anomaly family. We illustrate the advantages of our estimator versus the MLE on disease outbreak and highway traffic data.
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