The general problem of reconstructing an unknown function from a finite collection of samples is considered, in case the position of each input vector in the training set is not fixed beforehand, but is part of the learning process. In particular, the consistency of the Empirical Risk Minimization (ERM) principle is analyzed, when the points in the input space are generated by employing a purely deterministic algorithm (deterministic learning). When the output generation is not subject to noise, classical number-theoretic results, involving discrepancy and variation, allow to establish a sufficient condition for the consistency of the ERM principle. In addition, the adoption of low-discrepancy sequences permits to achieve a learning rate of O(1/L), being L the size of the training set. An extension to the noisy case is discussed.
A deterministic learning approach based on discrepancy
C Cervellera;M Muselli
2003
Abstract
The general problem of reconstructing an unknown function from a finite collection of samples is considered, in case the position of each input vector in the training set is not fixed beforehand, but is part of the learning process. In particular, the consistency of the Empirical Risk Minimization (ERM) principle is analyzed, when the points in the input space are generated by employing a purely deterministic algorithm (deterministic learning). When the output generation is not subject to noise, classical number-theoretic results, involving discrepancy and variation, allow to establish a sufficient condition for the consistency of the ERM principle. In addition, the adoption of low-discrepancy sequences permits to achieve a learning rate of O(1/L), being L the size of the training set. An extension to the noisy case is discussed.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
