Importance of Meteorological Parameters and Airborne Conidia to Predict Risk of on a Potato Crop Ambient Using Machine Learning Algorithms

Overview

Journal Sensors (Basel)

Publisher MDPI

Specialty Biotechnology

Date 2022 Sep 23

PMID 36146412

Authors

Laura Meno

Olga Escuredo

Isaac Kwesi Abuley

Maria Carmen Seijo

Affiliations

Soon will be listed here.

Abstract

Secondary infections of early blight during potato crop season are conditioned by aerial inoculum. However, although aerobiological studies have focused on understanding the key factors that influence the spore concentration in the air, less work has been carried out to predict when critical concentrations of conidia occur. Therefore, the goals of this study were to understand the key weather variables that affect the hourly and daily conidia dispersal of and in a potato field, and to use these weather factors in different machine learning (ML) algorithms to predict the daily conidia levels. This study showed that conidia per hour in a day is influenced by the weather conditions that characterize the hour, but not the hour of the day. Specifically, the relative humidity and solar radiation were the most relevant weather parameters influencing the conidia concentration in the air and both in a linear model explained 98% of the variation of this concentration per hour. Moreover, the dew point temperature three days before was the weather variable with the strongest effect on conidia per day. An improved prediction of conidia level was achieved via ML algorithms when the conidia of previous days is considered in the analysis. Among the ML algorithms applied, the CART model with an accuracy of 86% were the best to predict daily conidia level.

Citing Articles

Predicting Daily Aerobiological Risk Level of Potato Late Blight Using C5.0 and Random Forest Algorithms under Field Conditions.

Meno L, Escuredo O, Abuley I, Carmen Seijo M Sensors (Basel). 2023; 23(8).

PMID: 37112159 PMC: 10146589. DOI: 10.3390/s23083818.

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