Guillaume Grégoire scite author profile

Golf course maintenance requires the use of several inputs, such as pesticides and fertilizers, that can be harmful to human health or the environment. Understanding the factors associated with pesticide use on golf courses may help golf-course managers reduce their reliance on these products. In this study, we used a database of about 14,000 pesticide applications in the province of Québec, Canada, to develop a novel hybrid machine learning approach to predict pesticide use on golf courses. We created this proposed model, called RF-SVM-GOA, by coupling a support vector machine (SVM) with random forest (RF) and the grasshopper optimization algorithm (GOA). We applied RF to handle the wide range of datasets and GOA to find the optimal SVM settings. We considered five different dependent variables—region, golf course ID, number of holes, year, and treated area—as input variables. The experimental results confirmed that the developed hybrid RF-SVM-GOA approach was able to estimate the active ingredient total (AIT) with a high level of accuracy (R = 0.99; MAE = 0.84; RMSE = 0.84; NRMSE = 0.04). We compared the results produced by the developed RF-SVM-GOA model with those of four tree-based techniques including M5P, random tree, reduced error pruning tree (REP tree), and RF, as well as with those of two non-tree-based techniques including the generalized structure of group method of data handling (GSGMDH) and evolutionary polynomial regression (EPR). The computational results showed that the accuracy of the proposed RF-SVM-GOA approach was higher, outperforming the other methods. We analyzed sensitivity to find the most effective variables in AIT forecasting. The results indicated that the treated area is the most effective variable in AIT forecasting. The results of the current study provide a method for increasing the sustainability of golf course management.

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Forecasting Pesticide Use on Golf Courses by Integration of Deep Learning and Decision Tree Techniques

Grégoire

Fortin

Ebtehaj

et al. 2023

Agriculture

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In the current study, a new hybrid machine learning (ML)-based model was developed by integrating a convolution neural network (CNN) with a random forest (RF) to forecast pesticide use on golf courses in Québec, Canada. Three main groups of independent variables were used to estimate pesticide use on golf courses, expressed as actual active ingredient rate (AAIR): (i) coordinates (i.e., longitude and latitude of the golf course), (ii) characteristics of the golf courses (i.e., pesticide type and the number of holes), and (iii) meteorological variables (i.e., total precipitation, P, and average temperature, T). The meteorological variables were collected from the Google Earth Engine by developing a JavaScript-based Code. On the basis of the different periods of total precipitation and average temperature, four different scenarios were defined. A data bank with more than 40,000 samples was used to calibrate and validate the developed model such that 70% of all samples were randomly selected to calibrate the model, while the remainder of the samples (i.e., 30%) that did not have any role in calibration were employed to validate the model’s generalizability. A comparison of different scenarios indicated that the model that considered the longitude and latitude of the golf course, pesticide type, and the number of holes in golf courses as well as total precipitation and average temperature from May to November as inputs (R = 0.997; NSE = 0.997; RMSE = 0.046; MAE = 0.026; NRMSE = 0.454; and PBIAS (%) = −0.443) outperformed the other models. Moreover, the sensitivity analysis result indicated that the total precipitation was the most critical variable in AAIR forecasting, while the average temperature, pesticide types, and the number of holes were ranked second to fourth, respectively.

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Contribution of grass clippings to turfgrass fertilization and soil water content under four nitrogen levels

Grégoire

Benjannet

Desjardins

2022

Science of The Total Environment

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Reducing nitrate leaching losses from turfgrass fertilization of residential lawns

Côté

Grégoire

2021

J of Env Quality

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Fertilizer applications on lawns have raised environmental concerns in many Canadian municipalities. In this greenhouse study, NO3–N leaching losses from Kentucky bluegrass (Poa pratensis L.) lawns were evaluated on two soils (a schist loam and a clay loam) and on a sand/peat moss rootzone mix (80% sand, 20% peat moss). Eight different fertilizer N sources (urea, Polyon 8 and 12‐wk release, Duration 45 and 90‐d release, XCU, corn gluten meal, and UFLEXX) were assessed at five application rates (25–200 kg N ha–1 yr–1) and two application frequencies over two 8‐wk trials. Average NO3–N concentration in leachate were measured at levels of 3.5, 7.4, and 1.4 mg L–1 from turf grown in loam, clay, and sand respectively, but losses from loam and clay were mostly affected by N mineralization from organic matter. Turf fertilized with rates ≥100 kg N ha–1 generally resulted in acceptable visual quality on both soils, but coated‐urea fertilizers were more efficient to reduce leaching. In sand, UFLEXX and urea (150 and 200 kg N ha–1) as well as XCU (200 kg N ha–1) resulted in higher NO3–N losses, varying from 8.5 to 23.7 mg L–1, and losses from other N sources were consistently below 3 mg L–1. Our results show that it is possible to maintain good quality turfgrass while keeping low NO3–N leaching losses (i.e., <4 mg L–1) in loam, clay, and sand by selecting the ideal combination of N source, N rate, and application frequency.

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Contribution of Grass Clippings to Turfgrass Fertilization and Soil Water Content Under Four Nitrogen Levels

Grégoire

Benjannet²,

Desjardins³

2022

SSRN Journal

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