Abstract
Weeds can be major environmental and economic burdens in New Zealand. Traditional methods of weed control including manual and chemical approaches can be time consuming and costly. Some chemical herbicides may have negative environmental and human health impacts. One of the proposed important steps for providing alternatives to these traditional approaches is the automated identification and mapping of weeds. We used hyperspectral imaging data and machine learning to explore the possibility of fast, accurate and automated discrimination of weeds in pastures where ryegrass and clovers are the sown species. Hyperspectral images from two grasses (Setaria pumila [yellow bristle grass] and Stipa arundinacea [wind grass]) and two broad leaf weed species (Ranunculus acris [giant buttercup] and Cirsium arvense [Californian thistle]) were acquired and pre-processed using the standard normal variate method. We trained three classification models, namely partial least squares-discriminant analysis, support vector machine, and Multilayer Perceptron (MLP) using whole plant averaged (Av) spectra and superpixels (Sp) averaged spectra from each weed sample. All three classification models showed repeatable identification of four weeds using both Av and Sp spectra with a range of overall accuracy of 70–100%. However, MLP based on the Sp method produced the most reliable and robust prediction result (89.1% accuracy). Four significant spectral regions were found as highly informative for characterizing the four weed species and could form the basis for a rapid and efficient methodology for identifying weeds in ryegrass/clover pastures.
Highlights
Pastures based on perennial ryegrass (Lolium perenne) and white clover (Trifolium repens) are the main source of forage for animal production in New Zealand (McClearn et al, 2020)
The notations used for models developed with Av and Sp data using partial least squares discriminant analysis (PLS-DA), support vector machine (SVM), and Multilayer Perceptron (MLP) are given below: (a) Av_PLS-DA: PLS-DA model developed with Av data (b) Sp_PLS-DA : PLS-DA model developed with Sp data (c) Av_SVM: SVM model created with Av data (d) Sp_SVM: SVM model created with Sp data (e) Av_MLP: MLP model generated with Av data (f) Sp_MLP: MLP model generated with Sp data
The full-length spectra with 5% dropout was set as the input layer, and the four classification classes were set as the output layer
Summary
Pastures based on perennial ryegrass (Lolium perenne) and white clover (Trifolium repens) are the main source of forage for animal production in New Zealand (McClearn et al, 2020). Within the primary sector alone, weeds cost farmers NZ$50M in actual expenditure on chemical herbicides and labor (Bourdôt et al, 2007) Technologies that reduce these costs, and help minimize the use of synthetic herbicides, would improve the value of forage production (Bacco et al, 2018). Technologies such as hyperspectral imaging (HSI) systems are providing opportunities for rapid classification of plant species both in the laboratory and the field (Griffel et al, 2018; Liu and Zhang, 2018; Xu et al, 2018; Ferreira et al, 2019). Absorbance at specific wavelengths, which might be related to specific chemical bands, can be used for different materials classification and quality determination (Vaiphasa et al, 2007; Schwanninger et al, 2011)
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