The Effect of Noise on a Class of Energy-Based Learning Rules
Abstract
We study the selectivity properties of neurons based on BCM and kurtosis energy functions in a general case of noisy high-dimensional input space. The proposed approach, which is used for characterization of the stable states, can be generalized to a whole class of energy functions. We characterize the critical noise levels beyond which the selectivity is destroyed. We also perform a quantitative analysis of such transitions, which shows interesting dependency on data set size. We observe that the robustness to noise of the BCM neuron (Bienenstock, Cooper, & Munro, 1982; Intrator & Cooper, 1992) increases as a function of dimensionality. We explicitly compute the separability limit of BCM and kurtosis learning rules in the case of a bimodal input distribution. Numerical simulations show a stronger robustness of the BCM rule for practical data set size when compared with kurtosis.
Cite
Text
Bazzani et al. "The Effect of Noise on a Class of Energy-Based Learning Rules." Neural Computation, 2003. doi:10.1162/089976603321891837Markdown
[Bazzani et al. "The Effect of Noise on a Class of Energy-Based Learning Rules." Neural Computation, 2003.](https://mlanthology.org/neco/2003/bazzani2003neco-effect/) doi:10.1162/089976603321891837BibTeX
@article{bazzani2003neco-effect,
title = {{The Effect of Noise on a Class of Energy-Based Learning Rules}},
author = {Bazzani, Armando and Remondini, Daniel and Intrator, Nathan and Castellani, Gastone C.},
journal = {Neural Computation},
year = {2003},
pages = {1621-1640},
doi = {10.1162/089976603321891837},
volume = {15},
url = {https://mlanthology.org/neco/2003/bazzani2003neco-effect/}
}