Attention-Based Semantic Segmentation Networks for Forest Applications

Deforestation remains one of the key concerning activities around the world due to commodity-driven extraction, agricultural land expansion, and urbanization. The effective and efficient monitoring of national forests using remote sensing technology is important for the early detection and mitigatio...

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Published in:FORESTS
Main Authors: Lim, See Ven; Zulkifley, Mohd Asyraf; Saleh, Azlan; Saputro, Adhi Harmoko; Abdani, Siti Raihanah
Format: Article
Language:English
Published: MDPI 2023
Subjects:
Online Access:https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001131189000001
author Lim
See Ven; Zulkifley
Mohd Asyraf; Saleh
Azlan; Saputro
Adhi Harmoko; Abdani
Siti Raihanah
spellingShingle Lim
See Ven; Zulkifley
Mohd Asyraf; Saleh
Azlan; Saputro
Adhi Harmoko; Abdani
Siti Raihanah
Attention-Based Semantic Segmentation Networks for Forest Applications
Forestry
author_facet Lim
See Ven; Zulkifley
Mohd Asyraf; Saleh
Azlan; Saputro
Adhi Harmoko; Abdani
Siti Raihanah
author_sort Lim
spelling Lim, See Ven; Zulkifley, Mohd Asyraf; Saleh, Azlan; Saputro, Adhi Harmoko; Abdani, Siti Raihanah
Attention-Based Semantic Segmentation Networks for Forest Applications
FORESTS
English
Article
Deforestation remains one of the key concerning activities around the world due to commodity-driven extraction, agricultural land expansion, and urbanization. The effective and efficient monitoring of national forests using remote sensing technology is important for the early detection and mitigation of deforestation activities. Deep learning techniques have been vastly researched and applied to various remote sensing tasks, whereby fully convolutional neural networks have been commonly studied with various input band combinations for satellite imagery applications, but very little research has focused on deep networks with high-resolution representations, such as HRNet. In this study, an optimal semantic segmentation architecture based on high-resolution feature maps and an attention mechanism is proposed to label each pixel of the satellite imagery input for forest identification. The selected study areas are located in Malaysian rainforests, sampled from 2016, 2018, and 2020, downloaded using Google Earth Pro. Only a two-class problem is considered for this study, which is to classify each pixel either as forest or non-forest. HRNet is chosen as the baseline architecture, in which the hyperparameters are optimized before being embedded with an attention mechanism to help the model to focus on more critical features that are related to the forest. Several variants of the proposed methods are validated on 6120 sliced images, whereby the best performance reaches 85.58% for the mean intersection over union and 92.24% for accuracy. The benchmarking analysis also reveals that the attention-embedded high-resolution architecture outperforms U-Net, SegNet, and FC-DenseNet for both performance metrics. A qualitative analysis between the baseline and attention-based models also shows that fewer false classifications and cleaner prediction outputs can be observed in identifying the forest areas.
MDPI

1999-4907
2023
14
12
10.3390/f14122437
Forestry
gold
WOS:001131189000001
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001131189000001
title Attention-Based Semantic Segmentation Networks for Forest Applications
title_short Attention-Based Semantic Segmentation Networks for Forest Applications
title_full Attention-Based Semantic Segmentation Networks for Forest Applications
title_fullStr Attention-Based Semantic Segmentation Networks for Forest Applications
title_full_unstemmed Attention-Based Semantic Segmentation Networks for Forest Applications
title_sort Attention-Based Semantic Segmentation Networks for Forest Applications
container_title FORESTS
language English
format Article
description Deforestation remains one of the key concerning activities around the world due to commodity-driven extraction, agricultural land expansion, and urbanization. The effective and efficient monitoring of national forests using remote sensing technology is important for the early detection and mitigation of deforestation activities. Deep learning techniques have been vastly researched and applied to various remote sensing tasks, whereby fully convolutional neural networks have been commonly studied with various input band combinations for satellite imagery applications, but very little research has focused on deep networks with high-resolution representations, such as HRNet. In this study, an optimal semantic segmentation architecture based on high-resolution feature maps and an attention mechanism is proposed to label each pixel of the satellite imagery input for forest identification. The selected study areas are located in Malaysian rainforests, sampled from 2016, 2018, and 2020, downloaded using Google Earth Pro. Only a two-class problem is considered for this study, which is to classify each pixel either as forest or non-forest. HRNet is chosen as the baseline architecture, in which the hyperparameters are optimized before being embedded with an attention mechanism to help the model to focus on more critical features that are related to the forest. Several variants of the proposed methods are validated on 6120 sliced images, whereby the best performance reaches 85.58% for the mean intersection over union and 92.24% for accuracy. The benchmarking analysis also reveals that the attention-embedded high-resolution architecture outperforms U-Net, SegNet, and FC-DenseNet for both performance metrics. A qualitative analysis between the baseline and attention-based models also shows that fewer false classifications and cleaner prediction outputs can be observed in identifying the forest areas.
publisher MDPI
issn
1999-4907
publishDate 2023
container_volume 14
container_issue 12
doi_str_mv 10.3390/f14122437
topic Forestry
topic_facet Forestry
accesstype gold
id WOS:001131189000001
url https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001131189000001
record_format wos
collection Web of Science (WoS)
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