Identification of Crop Type Based on C-AENN Using Time Series Sentinel-1A SAR Data

Guo, Zhengwei; Qi, Wenwen; Huang, Yabo; Zhao, Jianhui; Yang, Huige; Koo, Voon Chet; Li, Ning

doi:10.3390/rs14061379

Cited by 19 publications

(13 citation statements)

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“…The variation of the NDMI index in relation to time (t, days) was described by equation (10) under conditions of R 2 =0.934, p<0.001, F=47.18. The variation of the NDVI index in relation to time (t, days) was described by equation (11) under conditions of R 2 =0.941, p<0.001, F=53.92. The variation of the NBR index in relation to time (t, days) during the study period was described by equation (12), under conditions of R 2 =0.961, p<0.001, F=83.225.…”

Section: Resultsmentioning

confidence: 99%

“…In general, high levels of statistical accuracy were communicated in estimating production based on remote sensing techniques, due to the fact that the vegetation reflects well through the status of the plants, the chlorophyll content, or other representative physiological indices, the vegetation conditions, the technological level of the process of production, and these aspects are well and correctly captured in the satellite images, as data in the form of spectral information (Guo et al, 2022). For example, Amankulova et al ( 2023) have reported very high accuracy (RMSE with values between 121.9 and 284.5 kg ha -1 ) in the prediction of sunflower production, based on satellite images in the Sentinel-2 system.…”

Section: Resultsmentioning

confidence: 99%

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Characterization of Vegetation and Prediction of Biomass Production in Silage Corn Crop Based on Satellite Images

Herbei¹,

POPESCU²,

Sala³

2022

LSSD

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The study used methods based on remote sensing to analyze the dynamics of a silage corn crop and predict biomass production. The corn crop, the Micado hybrid, was organized within the Didactic and Experimental Station of the "King Mihai I" University of Life Sciences in Timisoara, under the specific conditions of the 2021-2022 agricultural year. The soil in the crop plot was of chernozem type, and the crop was in a non-irrigated system. To obtain the satellite data, the Sentinel 2 system was used. To characterize the plot and the crop of silage corn, 14 sets of images were taken, in the interval March - July 2022. From the analysis of the images, the spectral data were obtained, and based on the consecrated formulas MSAVI, NDMI, NDVI and NBR indexes were calculated. The ANOVA test confirmed the reliability of the data and the presence of variance in the data set (F>Fcrit, p<0.001, for Alpha=0.001). The level of correlations identified between the calculated indices was between r=0.967 (NBR with NDVI) and r=0.996 (NDVI with MSAVI). The variation of the NBR index, in relation to the other indices, was described by linear equations, in terms of statistical safety (R2=0.965, p<0.001, in relation to MSAVI; R2=0.989, p<0.001 in relation to NDMI; R2=0.934, p<0.001 in relation to NDVI). The variation of indices in relation to time (t, days) during the study period was described by polynomial equations of the 3rd degree, in terms of statistical safety (R2=0.964 for MSAVI, R2=0.934 for NDMI, R2=0.941 for NDVI, and R2=0.961 for NBR). Regression analysis facilitated obtaining some equations, as models for predicting biomass production, under conditions of statistical safety. Based on the RMSEP parameter, it was found that the most reliable level of production prediction was obtained in the case of MSAVI and NDMI indices (RMSEP=0.05923).

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Characterization of Vegetation and Prediction of Biomass Production in Silage Corn Crop Based on Satellite Images

Herbei¹,

POPESCU²,

Sala³

2022

LSSD

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“…31 Additionally, in the field of image classification, convolutional neural networks (CNNs) have gained widespread acceptance due to their proficiency in effectively extracting spatial-temporal features. 32 For instance, Guo et al 33 introduced a convolutional-autoencoder neural network (C-AENN), which combined 1D-CNN and SAE techniques. When compared to traditional machine learning methods, the results demonstrated that C-AENN outperformed them in the task of crop classification, even with limited training data.…”

Section: Introductionmentioning

confidence: 99%

Optimal feature extraction from multidimensional remote sensing data for orchard identification based on deep learning methods

Luo,

Guo,

Zhu

et al. 2024

J. Appl. Rem. Sens.

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Accurate orchard spatial distribution information can help government departments to formulate scientific and reasonable agricultural economic policies. However, it is prominent to apply remote sensing images to obtain orchard planting structure information. The traditional multidimensional remote sensing data processing, dimension reduction and classification, which are two separate steps, cannot guarantee that final classification results can be benefited from dimension reduction process. Consequently, to make connection between dimension reduction and classification, this work proposes two neural networks that fuse stack autoencoder and convolutional neural network (CNN) at one-dimension and three-dimension, namely one-dimension and three-dimension fusion stacked autoencoder (FSA) and CNN networks (1D-FSA-CNN and 3D-FSA-CNN). In both networks, the front-end uses a stacked autoencoder (SAE) for dimension reduction, and the back-end uses a CNN with a Softmax classifier for classification. In the experiments, based on Google Earth Engine platform, two groups of orchard datasets are constructed using multi-source remote sensing data (i.e., GaoFen-1, Sentinel-2 and GaoFen-1, and GaoFen-3). Meanwhile, DenseNet201, 3D-CNN, 1D-CNN, and SAE are used for conduct two comparative experiments. The experimental results show that the proposed fusion neural networks achieve the state-of-the-art performance, both accuracies of 3D-FSA-CNN and 1D-FSA-CNN are higher than 95%.

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“…Several researchers have worked on IDSs in which machine learning (ML) and deep learning (DL) models play a key role [ 10 ]. ML and DL techniques are widely used in different fields, such as in agriculture [ 11 ], medical [ 12 ], and automobile industries [ 13 , 14 ]. DL is a branch of ML, and it is generalizable to new problems with complicated and high-dimensional data.…”

Section: Introductionmentioning

confidence: 99%

A New Intrusion Detection System for the Internet of Things via Deep Convolutional Neural Network and Feature Engineering

Ullah

Ahmad

Khan

et al. 2022

Sensors

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The Internet of Things (IoT) is a widely used technology in automated network systems across the world. The impact of the IoT on different industries has occurred in recent years. Many IoT nodes collect, store, and process personal data, which is an ideal target for attackers. Several researchers have worked on this problem and have presented many intrusion detection systems (IDSs). The existing system has difficulties in improving performance and identifying subcategories of cyberattacks. This paper proposes a deep-convolutional-neural-network (DCNN)-based IDS. A DCNN consists of two convolutional layers and three fully connected dense layers. The proposed model aims to improve performance and reduce computational power. Experiments were conducted utilizing the IoTID20 dataset. The performance analysis of the proposed model was carried out with several metrics, such as accuracy, precision, recall, and F1-score. A number of optimization techniques were applied to the proposed model in which Adam, AdaMax, and Nadam performance was optimum. In addition, the proposed model was compared with various advanced deep learning (DL) and traditional machine learning (ML) techniques. All experimental analysis indicates that the accuracy of the proposed approach is high and more robust than existing DL-based algorithms.

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Identification of Crop Type Based on C-AENN Using Time Series Sentinel-1A SAR Data

Cited by 19 publications

References 50 publications

Characterization of Vegetation and Prediction of Biomass Production in Silage Corn Crop Based on Satellite Images

Characterization of Vegetation and Prediction of Biomass Production in Silage Corn Crop Based on Satellite Images

Optimal feature extraction from multidimensional remote sensing data for orchard identification based on deep learning methods

A New Intrusion Detection System for the Internet of Things via Deep Convolutional Neural Network and Feature Engineering

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