Harvest chronological planning using a method based on satellite-derived vegetation indices and artificial neural networks

Taghizadeh, S; Navid, Hossein; Adiban, Reza; Maghsodi, Yasser

doi:10.5424/sjar/2019173-14357

Cited by 4 publications

(3 citation statements)

References 55 publications

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“…Orbital images are commonly used in agriculture to identify spectral variations resulting from soil and crop characteristics at a large-scale, supporting diagnostics for agronomical crop parameters and helping farmers to make better management decisions. For example, over the years, orbital images were used to delimit management zones for annual crops [1], monitor within-field yield variability for many crops such as corn [2] and cotton [3], map vineyard variability [4], plan the wheat harvest [5], develop crop growth model [6], and map grasslands biomass [7,8], among others. Some of the main limitations related to orbital images are the lack of ground truth data (calibration) and the measurement accuracy of the agronomical variables [9].…”

Section: Introductionmentioning

confidence: 99%

Sugarcane Yield Mapping Using High-Resolution Imagery Data and Machine Learning Technique

et al. 2021

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Yield maps provide essential information to guide precision agriculture (PA) practices. Yet, on-board yield monitoring for sugarcane can be challenging. At the same time, orbital images have been widely used for indirect crop yield estimation for many crops like wheat, corn, and rice, but not for sugarcane. Due to this, the objective of this study is to explore the potential of multi-temporal imagery data as an alternative for sugarcane yield mapping. The study was based on developing predictive sugarcane yield models integrating time-series orbital imaging and a machine learning technique. A commercial sugarcane site was selected, and Sentinel-2 images were acquired from the beginning of the ratoon sprouting until harvesting of two consecutive cropping seasons. The predictive yield models RF (Random forest) and MLR (Multiple Linear Regression) were developed using orbital images and yield maps generated by a commercial sensor-system on harvesting. Original yield data were filtered and interpolated with the same spatial resolution of the orbital images. The entire dataset was divided into training and testing datasets. Spectral bands, especially the near-infrared at tillering crop stage showed greater contribution to predicting sugarcane yield than the use of derived spectral vegetation indices. The Root Mean Squared Error (RMSE) obtained for the RF regression based on multiple spectral bands was 4.63 Mg ha−1 with an R2 of 0.70 for the testing dataset. Overall, the RF regression had better performance than the MLR to predict sugarcane yield.

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Section: Introductionmentioning

confidence: 99%

Sugarcane Yield Mapping Using High-Resolution Imagery Data and Machine Learning Technique

et al. 2021

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“…Remote sensing, which concentrates on the images examination of the earth's surface, has quickly evolved since the discovery of the infrared spectrum in the early 1800s (Campbell, 2002). The application of remotely sensed images leads to collect of reliable and timely data from crop performance (Lyle et al, 2013, Taghizadeh et al, 2019. Most vegetation indexes (VIs) incorporate reflectance in a few wavebands, which could be collected mainly by satellite broadband sensors.…”

Section: Introductionmentioning

confidence: 99%

Predicting Barley Harvest Time in Dryland Conditions Using Satellite Images

Adiban

Türkoğlu²,

Parchami-Araghi³

2021

Yüzüncü Yıl Üniversitesi Tarım Bilimleri Dergisi

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Barley has an important role in livestock feed. Therefore, an accurate estimation of harvesting time is necessary to minimize the loss in barley farming. The aim of this study is to determine barley harvest time using satellite images accurately. Field data were sampled from the farms in the Dezaj region of the west of Iran. In addition, satellite remote sensing technique was applied during barley growing season in 2019 using Landsat 8 images. The vegetation indexes were used as input in the prediction model in this study. The results showed that satellite imaging has enough potential to predict the harvesting time of barley accurately. R-squared and RMSE values of the best-structured stepwise regression model in this study were 0.791 as well, and 1.34 respectively. This method can be beneficially employed by farm managers to have an accurate estimation of the most appropriate harvesting time and be able to manage the process, which is an important challenge for them.

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“…The results indicated that Green Normalized Difference Vegetation Index (GNDVI) values were the most correlated with grain yield. The contributions of satellite imagery in agriculture are also related to the classification of agricultural surfaces (SONOBE et al, 2018), land use , spatial predictions of soil properties (SILVERO et al, 2021;SICRE et al, 2020), quantification of the available pasture biomass (REIS et al, 2020), to delimit management zones for annual crops (DAMIAN et al, 2020), monitor withinfield yield variability for many crops, such as corn and cotton , mapping vineyard variability and grasslands biomass (CISNEROS et al, 2020), plan the wheat harvest (TAGHIZADEH et al, 2019), develop crop growth model (LEVITAN and GROSS, 2018), among others.…”

Section: Satellite Imagery For Agriculturementioning

confidence: 99%

High-resolution data for mapping the spatio-temporal variability of sugarcane fields

Canata¹

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Harvest chronological planning using a method based on satellite-derived vegetation indices and artificial neural networks

Cited by 4 publications

References 55 publications

Sugarcane Yield Mapping Using High-Resolution Imagery Data and Machine Learning Technique

Sugarcane Yield Mapping Using High-Resolution Imagery Data and Machine Learning Technique

Predicting Barley Harvest Time in Dryland Conditions Using Satellite Images

High-resolution data for mapping the spatio-temporal variability of sugarcane fields

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