Time-series point clouds have emerged as an effective approach for precise, continuous crop monitoring and quantitative growth analysis. This study constructed a spatiotime-series point cloud dataset containing four species and eleven plant varieties, exploring crop organ instance segmentation, phenotypic parameter extraction, growth quantification, and canopy photosynthesis assessment. A skeleton-based framework for organ-level instance segmentation and time-series analysis is proposed, demonstrating robust performance across all four crops. To fully utilize the time-series data, a novel time-series leaf matching method was introduced, achieving a matching accuracy, defined as the proportion of correctly matched leaves, of over 0.823 for all species. By integrating the matching results with phenotypic parameter extraction, time-series phenotypic data were generated, and a phenotypic variation rate was defined as a suitable metric for quantifying crop growth. Furthermore, these results were integrated into a canopy photosynthesis model to derive key time-series photosynthetic metrics, including photosynthetic rate, absorbed light quantity, light energy utilization efficiency, and each crop organ's contribution to photosynthesis. These metrics provide insights into the crop’s growth patterns and photosynthetic strategy. This study offers refined quantitative analysis of crop morphology and photosynthetic parameters through time-series point cloud segmentation, contributing valuable data for advancing plant biology research and enhancing the understanding of crop growth dynamics. • Skeleton-guided 3D segmentation and tracking: Developed a robust method for organ-level point cloud segmentation and time-series matching, enabling accurate monitoring of crop development. • Leaf-scale growth and photosynthesis quantification: Established a pipeline to track leaf-level growth and compute key photosynthetic traits, including photosynthetic rate, absorbed light, and light use efficiency. • Phenotypic Variation Rate (PVR): Proposed a new metric to quantify dynamic changes in 3D plant structure, enhancing the analysis of growth patterns across time.
Zhou et al. (Sun,) studied this question.