Fusion of Hyperspectral Imaging and Convolutional Neural Networks for Early Detection of Crop Diseases in Precision Agriculture
Kavitha Dasari, Suman Avdhesh Yadav, Lavish Kansal, J Adilakshmi, Gopal Kaliyaperumal, Ali Albawi
Abstract
This research investigates the integration of hyperspectral imaging (HSI) and advanced convolutional neural networks (CNNs) for the early detection of crop diseases, a critical aspect in the realm of precision agriculture. Hyperspectral imaging, known for capturing a wide spectrum of light per pixel, provides detailed information about crops that is not visible to the naked eye. The study focuses on developing a novel framework wherein these detailed spectral signatures are utilized as inputs for deep learning models, specifically tailored CNNs. The proposed CNN architecture is designed to efficiently process the high-dimensional HSI data, extracting salient features relevant to various crop diseases. This integration facilitates the early identification of subtle physiological changes in plants that precede visible symptoms, thereby enabling timely interventions. The methodology involves collecting a comprehensive hyperspectral dataset from different crop types under varied conditions. This data is preprocessed to mitigate issues like atmospheric interference and sensor noise. The CNN models are trained and validated on this dataset, with a focus on generalizability across different crop species and disease types. The paper also addresses challenges such as the high computational cost and the need for large labeled datasets in HSI-CNN fusion. The results demonstrate a significant improvement in early disease detection accuracy compared to traditional methods, underscoring the potential of this approach in transforming precision agriculture practices. This study opens new pathways for sustainable farming by enabling proactive disease management, ultimately contributing to increased crop yield and reduced pesticide usage.