Digital mapping of coffee ripeness using UAV-based multispectral imagery

Digital mapping of coffee ripeness using UAV-based multispectral imagery

•UAV imagery provides a feasible method for monitoring the coffee fruit ripeness.•The use of spectral and textural variables improved the fruit ripeness mapping.•The spatiotemporal variability of the fruit ripeness was predicted and measured.•The method promotes non-invasive and spatial-specific mon...

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Bibliographic Details
Published in:Computers and electronics in agriculture Vol. 204; p. 107499
Main Authors: Nogueira Martins, Rodrigo, de Assis de Carvalho Pinto, Francisco, Marçal de Queiroz, Daniel, Sárvio Magalhães Valente, Domingos, Tadeu Fim Rosas, Jorge, Fagundes Portes, Marcelo, Sânzio Aguiar Cerqueira, Elder
Format: Journal Article
Language:English
Published: Elsevier B.V 01-01-2023
Subjects:
Digital agriculture
Drone
Fruit ripeness
Random forest
Remote sensing
Fruit ripeness
Random forest
Drone
Remote sensing
Digital agriculture
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Summary:•UAV imagery provides a feasible method for monitoring the coffee fruit ripeness.•The use of spectral and textural variables improved the fruit ripeness mapping.•The spatiotemporal variability of the fruit ripeness was predicted and measured.•The method promotes non-invasive and spatial-specific monitoring of fruit ripeness. Timely and accurate monitoring of coffee ripeness is essential for harvest planning, especially in mountainous areas where the harvest is performed manually due to the limited use of agricultural mechanization. The increasing temporal and spatial resolutions of remote sensing based on low-altitude unmanned aerial vehicles (UAV) provides a feasible way to monitor the fruit ripeness variability. Due to these facts, this study was aimed to: (1) predict the fruit ripeness using spectral and textural variables; and (2) to determine the best variables for developing spatio-temporal variability maps of the fruit ripeness. To do so, an experiment with six arabica coffee fields was set up. During the coffee ripeness stage in the 2018–2019 and 2020–2021 seasons, seven flights were carried out using a quadcopter equipped with a five-band multispectral camera. After that, 12 spectral and 64 textural variables composed of bands and vegetation indices were obtained. For the same period, the percentage of unripe fruits (fruit ripeness) was determined using an irregular grid on each field. Then, the fruit ripeness was predicted with six machine learning (ML) algorithms using as input (1) the spectral variables and (2) the combination of spectral and textural variables. Among the evaluated ML algorithms, the random forest presented the higher accuracy, in which the model using the spectral and textural variables (r2 = 0.71 and RMSE = 11.47%) presented superior performance than the model based solely on spectral variables (r2 = 0.67 and RMSE = 12.09%). Finally, this study demonstrated the feasibility of using spectral and textural variables derived from UAV imagery for mapping and monitoring the spatiotemporal changes in the fruit ripeness at a fine scale.
ISSN:0168-1699
1872-7107
DOI:10.1016/j.compag.2022.107499