On the Behavior of Convolutional Nets for Feature Extraction
March 03, 2017 ยท Declared Dead ยท ๐ Journal of Artificial Intelligence Research
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Authors
Dario Garcia-Gasulla, Ferran Parรฉs, Armand Vilalta, Jonatan Moreno, Eduard Ayguadรฉ, Jesรบs Labarta, Ulises Cortรฉs, Toyotaro Suzumura
arXiv ID
1703.01127
Category
cs.NE: Neural & Evolutionary
Cross-listed
cs.AI,
cs.LG,
stat.ML
Citations
97
Venue
Journal of Artificial Intelligence Research
Last Checked
4 months ago
Abstract
Deep neural networks are representation learning techniques. During training, a deep net is capable of generating a descriptive language of unprecedented size and detail in machine learning. Extracting the descriptive language coded within a trained CNN model (in the case of image data), and reusing it for other purposes is a field of interest, as it provides access to the visual descriptors previously learnt by the CNN after processing millions of images, without requiring an expensive training phase. Contributions to this field (commonly known as feature representation transfer or transfer learning) have been purely empirical so far, extracting all CNN features from a single layer close to the output and testing their performance by feeding them to a classifier. This approach has provided consistent results, although its relevance is limited to classification tasks. In a completely different approach, in this paper we statistically measure the discriminative power of every single feature found within a deep CNN, when used for characterizing every class of 11 datasets. We seek to provide new insights into the behavior of CNN features, particularly the ones from convolutional layers, as this can be relevant for their application to knowledge representation and reasoning. Our results confirm that low and middle level features may behave differently to high level features, but only under certain conditions. We find that all CNN features can be used for knowledge representation purposes both by their presence or by their absence, doubling the information a single CNN feature may provide. We also study how much noise these features may include, and propose a thresholding approach to discard most of it. All these insights have a direct application to the generation of CNN embedding spaces.
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