posted on 2017-08-21, 09:52authored byA. N. Gorban, I. Y. Tyukin
The problem of non-iterative one-shot and non-destructive correction of unavoidable mistakes arises in all Artificial Intelligence applications in the real world. Its solution requires robust separation of samples with errors from samples where the system works properly. We demonstrate that in (moderately) high dimension this separation could be achieved with probability close to one by linear discriminants. Surprisingly, separation of a new image from a very large set of known images is almost always possible even in moderately high dimensions by linear functionals, and coefficients of these functionals can be found explicitly. Based on fundamental properties of measure concentration, we show that for $M1-\vartheta$, where $1>\vartheta>0$ is a given small constant. Exact values of $a,b>0$ depend on the probability distribution that determines how the random $M$-element sets are drawn, and on the constant $\vartheta$. These {\em stochastic separation theorems} provide a new instrument for the development, analysis, and assessment of machine learning methods and algorithms in high dimension. Theoretical statements are illustrated with numerical examples.
Funding
The work was partially supported by Innovate UK (KTP009890 and KTP010522).
History
Citation
Neural Networks, 2017, 94, pp. 255-259
Author affiliation
/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Mathematics
Version
AM (Accepted Manuscript)
Published in
Neural Networks
Publisher
Elsevier for European Neural Network Society (ENNS), International Neural Network Society (INNS), Japanese Neural Network Society (JNNS)
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