Identification and mapping of soybean and maize crops based on Sentinel-2 data

Bao She,Dongyan Zhang,Zhigen Zhao,Dong Liang,Yuying Yang,Linsheng Huang

doi:10.25165/j.ijabe.20201306.6183

Abstract

Soybean and maize are important raw materials for the production of food and livestock feed. Accurate mapping of these two crops is of great significance to crop management, yield estimation, and crop-damage control. In this study, two towns in Guoyang County, Anhui Province, China, were selected as the study area, and Sentinel-2 images were adopted to map the distributions of both crops in the 2019 growing season. The data obtained on August 18 (early pod-setting stage of soybean) was determined to be the most applicable to soybean and maize mapping by means of the Jeffries–Matusita (JM) distance. Subsequently, three machine-learning algorithms, i.e., random forest (RF), support vector machine (SVM) and back-propagation neural network (BPNN) were employed and their respective performance in crop identification was evaluated with the aid of 254 ground truth plots. It appeared that RF with a Kappa of 0.83 was superior to the other two methods. Furthermore, twenty candidate features containing the reflectance of ten spectral bands (spatial resolution at 10 m or 20 m) and ten remote-sensing indices were input into the RF algorithm to conduct an important assessment. Seven features were screened out and served as the optimum subset, the mapping results of which were assessed based on the ground truth derived from the unmanned aerial vehicle (UAV) images covering six ground samples. The optimum feature-subset achieved high-accuracy crop mapping, with a reduction of data volume by 65% compared with the total twenty features, which also overrode the performance of ten spectral bands. Therefore, feature-optimization had great potential in the identification of the two crops. Generally, the findings of this study can provide a valuable reference for mapping soybean and maize in areas with a fragmented landscape of farmland and complex planting structure. Keywords: soybean and maize, crop identification, Sentinel-2 data, machine learning, feature selection DOI: 10.25165/j.ijabe.20201306.6183 Citation: She B, Yang Y Y, Zhao Z G, Huang L S, Liang D, Zhang D Y. Identification and mapping of soybean and maize crops based on Sentinel-2 data. Int J Agric & Biol Eng, 2020; 13(6): 171–182.

Highlights

Soybean (Glycine max L.) and maize (Zea mays L.) are two important food crops, which are extensively grown all over the world and attract considerable attention in global food production[1]
Traditional methods of manual field investigation to estimate the acreage of soybean and maize usually consume lots of time, labor, and resources with low efficiency and strong subjectivity, and the results of the investigation lack spatial distribution information[6]
Huang et al.[6] evaluated the performance of different Vegetation index (VI) derived from multi-temporal GF-1 WFV data to map soybean and maize by using maximum likelihood, support vector machine (SVM), and random forest (RF) classifiers and the results showed that RF classifier combined with normalized difference vegetation index (NDVI), normalized difference water index (NDWI), and wide dynamic range vegetation index (WDRVI) as the input had the best performance

Summary

Introduction

Soybean (Glycine max L.) and maize (Zea mays L.) are two important food crops, which are extensively grown all over the world and attract considerable attention in global food production[1]. In 2018, the cultivated area of maize in China reached 42159 khm (ranking first in the world), and the acreage of soybean reached 7974 khm (ranking fifth in the world) (http://www.fao.org/ faostat/en/#data). Obtaining information on the spatial distributions of soybean and maize in a timely and accurate manner is essential for the government to guide agricultural production and formulate agricultural policies[5]. Traditional methods of manual field investigation to estimate the acreage of soybean and maize usually consume lots of time, labor, and resources with low efficiency and strong subjectivity, and the results of the investigation lack spatial distribution information[6]. Remote sensing has the potential of large-scale crop identification and mapping in the field of agriculture, providing a timely, efficient, low-cost and objective way to monitor large areas simultaneously[7]

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