Deep pruned nets for efficient image-based plants disease classification

Deep learning is a field of Artificial Intelligence that has recently drawn a lot of attention with the desire to build up a quick, automatic and accurate system for image identification and classification. Deep learning serves as a fundamental part of modern computer vision solutions. However, as t...

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Veröffentlicht in:	Journal of intelligent & fuzzy systems 2019-01, Vol.37 (3), p.4003-4019
Hauptverfasser:	Too, Edna C., Li, Yujian, Kwao, Pius, Njuki, Sam, Mosomi, Mugendi E., Kibet, Julius
Format:	Artikel
Sprache:	eng
Schlagworte:	Artificial intelligence Artificial neural networks Computer vision Datasets Deep learning Feature maps Identification methods Image classification Machine learning Mathematical models Medical imaging Model accuracy Neural networks Parameters Plant diseases Pruning Reduction Species classification State-of-the-art reviews Training
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container_title	Journal of intelligent & fuzzy systems
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creator	Too, Edna C. Li, Yujian Kwao, Pius Njuki, Sam Mosomi, Mugendi E. Kibet, Julius
description	Deep learning is a field of Artificial Intelligence that has recently drawn a lot of attention with the desire to build up a quick, automatic and accurate system for image identification and classification. Deep learning serves as a fundamental part of modern computer vision solutions. However, as the architectures become deep and powerful new challenges in the process of training emerge. This includes the computational cost associated with training deep and large networks. In this work, the focus is on pruning and evaluation of state-of-the-art deep convolutional neural network for image-based plant disease and plants species classification. Pruning filters allow the reduction of parameters by removing unimportant filters and its feature maps. In this paper, the performance of pruned networks is evaluated across three datasets. It is observed that pruned DenseNet with Self-Normalization Neural Network (SNN) approach learns 2x faster compared to the initial DenseNet architecture. Additionally, pruning filters allow the reduction of the number of parameters and FLOPs by approximately 14% and 25% respectively. The aim is to create a fast and efficient model for the purpose of identification of plant diseases. Fast methods are desired for early identifications of diseases before damages occur. The proposed method achieves a satisfactory accuracy performance on PlantVillage, LeafSnap and Swedish-leaf dataset using held-out dataset. Our best pruned model gives an accuracy of 99.24%, 86.64%, and 97.5% on PlantVillage, LeafSnap, and Swedish-leaf datasets respectively.
doi_str_mv	10.3233/JIFS-190184
format	Article
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subjects	Artificial intelligence Artificial neural networks Computer vision Datasets Deep learning Feature maps Identification methods Image classification Machine learning Mathematical models Medical imaging Model accuracy Neural networks Parameters Plant diseases Pruning Reduction Species classification State-of-the-art reviews Training
title	Deep pruned nets for efficient image-based plants disease classification
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