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Convergence Rates for Mixture-of-Experts

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arxiv 1110.2058 v2 pith:TUP6BK4N submitted 2011-10-10 math.ST stat.MEstat.MLstat.TH

Convergence Rates for Mixture-of-Experts

classification math.ST stat.MEstat.MLstat.TH
keywords convergenceexpertsproblemsratesbetterdensityfoundgiven
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In mixtures-of-experts (ME) model, where a number of submodels (experts) are combined, there have been two longstanding problems: (i) how many experts should be chosen, given the size of the training data? (ii) given the total number of parameters, is it better to use a few very complex experts, or is it better to combine many simple experts? In this paper, we try to provide some insights to these problems through a theoretic study on a ME structure where $m$ experts are mixed, with each expert being related to a polynomial regression model of order $k$. We study the convergence rate of the maximum likelihood estimator (MLE), in terms of how fast the Kullback-Leibler divergence of the estimated density converges to the true density, when the sample size $n$ increases. The convergence rate is found to be dependent on both $m$ and $k$, and certain choices of $m$ and $k$ are found to produce optimal convergence rates. Therefore, these results shed light on the two aforementioned important problems: on how to choose $m$, and on how $m$ and $k$ should be compromised, for achieving good convergence rates.

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