Analysis of the Effects of Microscopy Techniques on the Performances of Convolutional Neural Network Architectures in Microscopic Fusarium Microconidia Detection

Analysis of the Effects of Microscopy Techniques on the Performances of Convolutional Neural Network Architectures in Microscopic Fusarium Microconidia Detection

Fusarium wilt, a disease afflicting banana plants, is caused by the soilborne fungus Fusarium oxysporum f. sp. cubense or Foc. Upon entering a plant, Foc attacks the vascular system of the host. Infected plants show symptoms late, when Foc may already be widespread both in the plant and in the plant...

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Main Authors: Abigan, Erinn Giannice T, Cajucom, Luis Gabriel A, Ong, Josh Daniel L, Abu, Patricia Angela R, Estuar, Ma. Regina Justina E
Format: text
Published: Archīum Ateneo 2021
Subjects:
Meters
Fungi
Mechatronics
Infectious diseases
Microscopy
Crops
Computer architecture
microscopy image analysis
microconidia detection
convolutional neural networks
Fusarium oxysporum f. sp. cubense
Computer Sciences
Diseases
Microbiology
Online Access:https://archium.ateneo.edu/discs-faculty-pubs/239
https://ieeexplore.ieee.org/abstract/document/9591055
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Institution: Ateneo De Manila University
id ph-ateneo-arc.discs-faculty-pubs-1225
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spelling ph-ateneo-arc.discs-faculty-pubs-12252022-01-31T06:22:07Z Analysis of the Effects of Microscopy Techniques on the Performances of Convolutional Neural Network Architectures in Microscopic Fusarium Microconidia Detection Abigan, Erinn Giannice T Cajucom, Luis Gabriel A Ong, Josh Daniel L Abu, Patricia Angela R Estuar, Ma. Regina Justina E Fusarium wilt, a disease afflicting banana plants, is caused by the soilborne fungus Fusarium oxysporum f. sp. cubense or Foc. Upon entering a plant, Foc attacks the vascular system of the host. Infected plants show symptoms late, when Foc may already be widespread both in the plant and in the plantation, and often do not recover. The recommended way to deal with Foc, once detected, is to quarantine and burn plants and soil within a 7.5 meter radius, resulting in the loss of a few crops at best and whole plantations at worst. One way to prevent Foc from wreaking havoc is to detect it early on. The goal of the study is to develop and compare convolutional neural networks (CNNs) identifying microconidia, a fungal structure, in microscopy images with three microscopy techniques. Four CNN architectures classified images into either Clean or Foc (microconidia present). In terms of accuracy, by microscopy technique, CNNs classifying bright field (BF) images consistently yielded the highest, followed by those classifying fluorescent (FL) images, then All images, and lastly, dark field (DF) images. By architecture, the ResNet-50 CNNs consistently performed the best, followed by ResNet-101, then VGG-19 with batch normalization, and AlexNet. In terms of prediction time, by microscopy technique, the All images networks took 3–4 times longer than the BF, DF, and FL networks. By architecture, AlexNet consistently took the least time, followed by VGG-19 with batch normalization, then ResNet-50, and ResNet-101. 2021-01-01T08:00:00Z text https://archium.ateneo.edu/discs-faculty-pubs/239 https://ieeexplore.ieee.org/abstract/document/9591055 Department of Information Systems & Computer Science Faculty Publications Archīum Ateneo Meters Fungi Mechatronics Infectious diseases Microscopy Crops Computer architecture microscopy image analysis microconidia detection convolutional neural networks Fusarium oxysporum f. sp. cubense Computer Sciences Diseases Fungi Microbiology
institution Ateneo De Manila University
building Ateneo De Manila University Library
continent Asia
country Philippines
Philippines
content_provider Ateneo De Manila University Library
collection archium.Ateneo Institutional Repository
topic Meters
Fungi
Mechatronics
Infectious diseases
Microscopy
Crops
Computer architecture
microscopy image analysis
microconidia detection
convolutional neural networks
Fusarium oxysporum f. sp. cubense
Computer Sciences
Diseases
Fungi
Microbiology
spellingShingle Meters
Fungi
Mechatronics
Infectious diseases
Microscopy
Crops
Computer architecture
microscopy image analysis
microconidia detection
convolutional neural networks
Fusarium oxysporum f. sp. cubense
Computer Sciences
Diseases
Fungi
Microbiology
Abigan, Erinn Giannice T
Cajucom, Luis Gabriel A
Ong, Josh Daniel L
Abu, Patricia Angela R
Estuar, Ma. Regina Justina E
Analysis of the Effects of Microscopy Techniques on the Performances of Convolutional Neural Network Architectures in Microscopic Fusarium Microconidia Detection
description Fusarium wilt, a disease afflicting banana plants, is caused by the soilborne fungus Fusarium oxysporum f. sp. cubense or Foc. Upon entering a plant, Foc attacks the vascular system of the host. Infected plants show symptoms late, when Foc may already be widespread both in the plant and in the plantation, and often do not recover. The recommended way to deal with Foc, once detected, is to quarantine and burn plants and soil within a 7.5 meter radius, resulting in the loss of a few crops at best and whole plantations at worst. One way to prevent Foc from wreaking havoc is to detect it early on. The goal of the study is to develop and compare convolutional neural networks (CNNs) identifying microconidia, a fungal structure, in microscopy images with three microscopy techniques. Four CNN architectures classified images into either Clean or Foc (microconidia present). In terms of accuracy, by microscopy technique, CNNs classifying bright field (BF) images consistently yielded the highest, followed by those classifying fluorescent (FL) images, then All images, and lastly, dark field (DF) images. By architecture, the ResNet-50 CNNs consistently performed the best, followed by ResNet-101, then VGG-19 with batch normalization, and AlexNet. In terms of prediction time, by microscopy technique, the All images networks took 3–4 times longer than the BF, DF, and FL networks. By architecture, AlexNet consistently took the least time, followed by VGG-19 with batch normalization, then ResNet-50, and ResNet-101.
format text
author Abigan, Erinn Giannice T
Cajucom, Luis Gabriel A
Ong, Josh Daniel L
Abu, Patricia Angela R
Estuar, Ma. Regina Justina E
author_facet Abigan, Erinn Giannice T
Cajucom, Luis Gabriel A
Ong, Josh Daniel L
Abu, Patricia Angela R
Estuar, Ma. Regina Justina E
author_sort Abigan, Erinn Giannice T
title Analysis of the Effects of Microscopy Techniques on the Performances of Convolutional Neural Network Architectures in Microscopic Fusarium Microconidia Detection
title_short Analysis of the Effects of Microscopy Techniques on the Performances of Convolutional Neural Network Architectures in Microscopic Fusarium Microconidia Detection
title_full Analysis of the Effects of Microscopy Techniques on the Performances of Convolutional Neural Network Architectures in Microscopic Fusarium Microconidia Detection
title_fullStr Analysis of the Effects of Microscopy Techniques on the Performances of Convolutional Neural Network Architectures in Microscopic Fusarium Microconidia Detection
title_full_unstemmed Analysis of the Effects of Microscopy Techniques on the Performances of Convolutional Neural Network Architectures in Microscopic Fusarium Microconidia Detection
title_sort analysis of the effects of microscopy techniques on the performances of convolutional neural network architectures in microscopic fusarium microconidia detection
publisher Archīum Ateneo
publishDate 2021
url https://archium.ateneo.edu/discs-faculty-pubs/239
https://ieeexplore.ieee.org/abstract/document/9591055
_version_ 1724079140878942208

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