• Voxel-based virtual Chinese cabbage fields with shadow correction were developed to simulate 3D canopy structural dynamics. • Red band reflectance was simulated using a voxel-based canopy framework driven by incident solar irradiance simulated by SMARTS model and validated against Sentinel 2 imagery. • A lookup table was constructed by simulating Red band reflectance across growth stages, cultivation patterns, sun zenith angles, and survival rates. • The proposed framework provides a 3D-based methodology that can be also extended to other vegetable crops for satellite-based phenology monitoring. Crop phenological information is crucial for agricultural activities such as fertilizer management, irrigation, disease prevention, and yield estimation. While optical Vegetation Indices and Synthetic Aperture Radar estimate crop phenology using satellite time series data, their universal application remains limited. Recently, simulating reflectance of virtual scenarios has proven effective for detecting crop biophysical parameters. This study simulated extensive voxel-based virtual Chinese cabbage fields under various seasons, growth stages, cultivation patterns, and survival rates across East Asia. A lookup table was created using reflectance simulations from the Simple Model of the Atmospheric Radiative Transfer of Sunshine (SMARTS) model, linked to Sentinel-2 Red band reflectance with shadow correction. Our key findings include: (1) Red band reflectance decreases from the rosette stage to heading, rebounding slightly during dormancy due to biophysical changes; (2) higher Sun Zenith Angles (SZAs) in winter increase atmospheric path length, leading to greater radiation scattering and absorption, reducing Red band reflectance; (3) a 0.6-meter cultivation spacing is optimal, as 0.4 meters may hinder growth due to leaf overlap, while 0.8 meters could lead to inefficient land use; and (4) increased survival rates elevate vegetation fraction, reducing Red band reflectance. The lookup table was validated against Sentinel-2 imagery from 13 sites across Northeastern China, Japan, and the Koreas, achieving an R² value of 0.75. This methodology, while focused on Chinese cabbage, is also expected to enhance phenological stage detection for other vegetable crops using high-resolution satellite imagery.
Shao et al. (Tue,) studied this question.