VIE-Net: regressive U-Net for Vegetation Index Estimation

Vegetation indexes (VIs) are important indicators in agriculture, revealing valuable information about the vegetative status of crops through nondestructive evaluation methods. Among these indexes, the Normalized Difference Vegetation Index (NDVI) is a key metric used for assessing plant cover and health by combining Near-Infrared (NIR) and Red reflectance. NDVI calculation is based on multispectral cameras equipped with NIR sensors. However, the presence of this sensor is what makes the device costly and therefore impractical for small-scale farms. To address this limitation, recent works have explored the use of artificial intelligence to build AI-powered RGB cameras as a more affordable alternative for NDVI estimation. This has been done by means of generative artificial intelligence (often prone to hallucinations) or via shallow neural networks (pixel-wise regression) with the drawback of a high computational cost. Here, we introduce an end-to-end non-generative approach for NDVI estimate from calibrated RGB images. The proposed model, called VIE-Net, is a convolutional neural network based on a regressive version of the U-net model. The model is tested on two datasets for remote (25 meters above the ground level) and proximal sensing (1 meter from the subject), reaching correlation performance up to r 2 = 0.98 when non vegetative background is subtracted. This approach not only provides a cost-effective solution for NDVI estimation but also improves the reliability of vegetation health assessment using standard RGB images.