Visualising Basins of Attraction for the Cross-Entropy and the Squared Error Neural Network Loss Functions
January 08, 2019 ยท Declared Dead ยท ๐ Neurocomputing
"No code URL or promise found in abstract"
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Authors
Anna Sergeevna Bosman, Andries Engelbrecht, Mardรฉ Helbig
arXiv ID
1901.02302
Category
cs.LG: Machine Learning
Cross-listed
cs.NE,
stat.ML
Citations
83
Venue
Neurocomputing
Last Checked
4 months ago
Abstract
Quantification of the stationary points and the associated basins of attraction of neural network loss surfaces is an important step towards a better understanding of neural network loss surfaces at large. This work proposes a novel method to visualise basins of attraction together with the associated stationary points via gradient-based random sampling. The proposed technique is used to perform an empirical study of the loss surfaces generated by two different error metrics: quadratic loss and entropic loss. The empirical observations confirm the theoretical hypothesis regarding the nature of neural network attraction basins. Entropic loss is shown to exhibit stronger gradients and fewer stationary points than quadratic loss, indicating that entropic loss has a more searchable landscape. Quadratic loss is shown to be more resilient to overfitting than entropic loss. Both losses are shown to exhibit local minima, but the number of local minima is shown to decrease with an increase in dimensionality. Thus, the proposed visualisation technique successfully captures the local minima properties exhibited by the neural network loss surfaces, and can be used for the purpose of fitness landscape analysis of neural networks.
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