Abstract

Although efforts and progress have been made in crop classification using optical remote sensing images, it is still necessary to make full use of the high spatial, temporal, and spectral resolutions of remote sensing images. However, with the increasing volume of remote sensing data, a key emerging issue in the field of crop classification is how to find useful information from massive data to balance classification accuracy and processing time. To address this challenge, we developed a novel crop classification method, combining optimal feature selection (OFSM) with hybrid convolutional neural network-random forest (CNN-RF) networks for multi-temporal optical remote sensing images. This research used 234 features including spectral, segmentation, color, and texture features from three scenes of Sentinel-2 images to identify crop types in the Jilin province of northeast China. To effectively extract the effective features of remote sensing data with lower time requirements, the use of OFSM was proposed with the results compared with two traditional feature selection methods (TFSM): random forest feature importance selection (RF-FI) and random forest recursive feature elimination (RF-RFE). Although the time required for OFSM was 26.05 s, which was between RF-FI with 1.97 s and RF-RFE with 132.54 s, OFSM outperformed RF-FI and RF-RFE in terms of the overall accuracy (OA) of crop classification by 4% and 0.3%, respectively. On the basis of obtaining effective feature information, to further improve the accuracy of crop classification we designed two hybrid CNN-RF networks to leverage the advantages of one-dimensional convolution (Conv1D) and Visual Geometry Group (VGG) with random forest (RF), respectively. Based on the selected optimal features using OFSM, four networks were tested for comparison: Conv1D-RF, VGG-RF, Conv1D, and VGG. Conv1D-RF achieved the highest OA at 94.27% as compared with VGG-RF (93.23%), Conv1D (92.59%), and VGG (91.89%), indicating that the Conv1D-RF method with optimal feature input provides an effective and efficient method of time series representation for multi-temporal crop-type classification.

Highlights

  • In recent years, with the increase in satellites at different spatial, temporal, radiometric, and spectral resolutions, remote sensing techniques have emerged as optimal tools to identify crop types over larger areas

  • This study aims to develop a novel crop classification method based on optimal feature selection (OFSM) and hybrid convolutional neural network-random forest (CNN-random forest (RF)) networks for multi-temporal remote sensing images

  • (2) Considering the advantages of multiple classifiers, we propose two hybrid convolutional neural networks (CNN)-RF networks to integrate the advantages of Conv1D and Visual Geometry Group (VGG) with RF, respectively

Read more

Summary

Introduction

With the increase in satellites at different spatial, temporal, radiometric, and spectral resolutions, remote sensing techniques have emerged as optimal tools to identify crop types over larger areas. When obtaining high volumes of spectral and temporal information data, considering information redundancy and the processing time required, feature selection preprocessing is used to improve the speed and accuracy of crop classification. Xu et al [23] utilized convolutional neural networks (CNN) to classify multi-source remote sensing images and obtained land-cover classification with a 97.92% accuracy. These networks were not designed to process sequential data or represent temporal features. This study aims to develop a novel crop classification method based on optimal feature selection (OFSM) and hybrid CNN-RF networks for multi-temporal remote sensing images.

Data Resources
44 TTootatlal
Feature Selection
Deep-Learning Classification
Feature Selection Comparison
Features from OFSM
Methods
Findings
Classification and Accuracy Assessment

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.