Tree parameter extraction in Fokienia hodginsii plantation based on airborne LiDAR data

doi:10.13287/j.1001-9332.202402.015

Abstract

Abstract: Accurate and efficient extraction of tree parameters from plantations lay foundation for estimating individual wood volume and stand stocking. In this study, we proposed a method of extracting high-precision tree parameters based on airborne LiDAR data. The main process included data pre-processing, ground filtering, individual tree segmentation, and parameter extraction. We collected high-density airborne point cloud data from the large-diameter timber of Fokienia hodginsii plantation in Guanzhuang State Forestry Farm, Shaxian County, Fujian Province, and pre-processed the point cloud data by denoising, resampling and normalization. The vegetation point clouds and ground point clouds were separated by the Cloth Simulation Filter (CSF). The former data were interpolated using the Delaunay triangulation mesh method to generate a digital surface model (DSM), while the latter data were interpolated using the Inverse Distance Weighted to generate a digital elevation model (DEM). After that, we obtained the canopy height model (CHM) through the difference operation between the two, and analyzed the CHM with varying resolutions by the watershed algorithm on the accuracy of individual tree segmentation and parameter extraction. We used the point cloud distance clustering algorithm to segment the normalized vegetation point cloud into individual trees, and analyzed the effects of different distance thresholds on the accuracy of indivi-dual tree segmentation and parameter extraction. The results showed that the watershed algorithm for extracting tree height of 0.3 m resolution CHM had highest comprehensive evaluation index of 91.1% for individual tree segmentation and superior accuracy with R² of 0.967 and RMSE of 0.890 m. When the spacing threshold of the point cloud segmentation algorithm was the average crown diameter, the highest comprehensive evaluation index of 91.3% for individual tree segmentation, the extraction accuracy of the crown diameter was superior, with R² of 0.937 and RMSE of 0.418 m. Tree height, crown diameter, tree density, and spatial distribution of trees were estimated. There were 5994 F. hodginsii, with an average tree height of 16.63 m and crown diameter of 3.98 m. Trees with height of 15-20 m were the most numerous (a total of 2661), followed by those between 10-15 m. This method of forest parameter extraction was useful for monitoring and managing plantations.

Key words: plantation, airborne LiDAR data, individual tree segmentation, forest parameter extraction

JIANG Ze, CHEN Jie, TANG Liyu, YU Can, XIE Rugen, HUANG Danling, SU Shunde. Tree parameter extraction in Fokienia hodginsii plantation based on airborne LiDAR data[J]. Chinese Journal of Applied Ecology, 2024, 35(2): 321-329.

References

[1] 苏顺德. 基于生长性状育种值和遗传多样性构建福建柏第1代核心育种群体. 西北林学院学报, 2022, 37(6): 85-91
[2] 王昊. 林木种子园研究现状与发展趋势. 世界林业研究, 2013, 26(4): 32-37
[3] 苏顺德, 肖晖, 林文龙, 等. 马尾松第2代种子园营建关键技术. 福建林业科技, 2013, 40(4): 45-50
[4] 代华兵, 李春干, 庞勇, 等. 基于天空地一体化森林资源调查的小班因子设置与信息获取方法. 林业资源管理, 2021(1): 180-188
[5] Tang X, You H, Liu Y, et al. Monitoring of monthly height growth of individual trees in a subtropical mixed plantation using UAV data. Remote Sensing, 2023, 15: 326
[6] Tian L, Qu Y, Qi J. Estimation of forest LAI using discrete airborne LiDAR: A review. Remote Sensing, 2021, 13: 2408
[7] Qu Y, Shaker A, Korhonen L, et al. Direct estimation of forest leaf area index based on spectrally corrected airborne LiDAR pulse penetration ratio. Remote Sensing, 2020, 12: 217
[8] Zhang Q, Ge L, Hensley S, et al. PolGAN: A deep-learning-based unsupervised forest height estimation based on the synergy of PolInSAR and LiDAR data. ISPRS Journal of Photogrammetry and Remote Sensing, 2022, 186: 123-139
[9] Jiang F, Deng M, Tang J, et al. Integrating spaceborne LiDAR and Sentinel-2 images to estimate forest aboveground biomass in Northern China. Carbon Balance and Management, 2022, 17: 12
[10] 刘兵兵, 魏建新, 胡天宇, 等. 卫星遥感监测产品在中国森林生态系统的验证和不确定性分析——基于海量无人机激光雷达数据. 植物生态学报, 2022, 46(10): 1305-1316
[11] Calders K, Adams J, Armston J, et al. Terrestrial laser scanning in forest ecology: Expanding the horizon. Remote Sensing of Environment, 2020, 251: 112102
[12] 李肖肖, 唐丽玉, 彭巍, 等. 基于背包式激光雷达测量系统的城市绿地树木三维绿量估算方法. 应用生态学报, 2022, 33(10): 2777-2784
[13] 黄洪宇, 骆钰波, 唐丽玉, 等. 基于单木位置特征的多源树木三维点云配准方法. 林业科学, 2022, 58(11): 96-107
[14] 刘浩, 张峥男, 曹林. 机载激光雷达森林垂直结构剖面参数的沿海平原人工林林分特征反演. 遥感学报, 2018, 22(5): 872-888
[15] 王伟伟, 庞勇, 杜黎明, 等. 超体素约简和谱聚类结合的机载LiDAR点云单木分割. 遥感学报, 2022, 26(8): 1650-1661
[16] Yu X, Hyypp J, Kukko A, et al. Change detection techniques for canopy height growth measurements using airborne laser scanner data. Photogrammetric Engineering & Remote Sensing, 2006, 72: 1339-1348
[17] 刘峰, 谭畅, 张贵, 等. 长白落叶松单木参数与生物量机载LiDAR估测. 农业机械学报, 2013, 44(9): 219-224
[18] Xu X, Iuricich F, De Floriani L. A topology-based approach to individual tree segmentation from airborne LiDAR data. GeoInformatica, 2023, 27: 1-30
[19] Itakura K, Miyatani S, Hosoi F. Estimating tree structural parameters via automatic tree segmentation from LiDAR point cloud data. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 2022, 15: 555-564
[20] Du L, Pang Y, Wang Q, et al. A LiDAR biomass index-based approach for tree- and plot-level biomass mapping over forest farms using 3D point clouds. Remote Sensing of Environment, 2023, 290: 113543
[21] 惠振阳, 李娜, 程朋根, 等. 基于连通性标记优化的地基LiDAR点云单木分割方法. 中国激光, 2023, 50(6): 155-163
[22] LI W, Guo Q, Jakubowski MK, et al. A new method for segmenting individual trees from the Lidar point cloud. Photogrammetric Engineering and Remote Sensing, 2012, 78: 75-84
[23] Pu Y, Xu D, Wang H, et al. A new strategy for indivi-dual tree detection and segmentation from leaf-on and leaf-off UAV-LiDAR point clouds based on automatic detection of seed points. Remote Sensing, 2023, 15: 1619
[24] Wang JM, Chen XX, Cao L, et al. Individual rubber tree segmentation based on ground-based LiDAR data and faster R-CNN of deep learning. Forests, 2019, 10: 793
[25] Qi CR, Su H, Mo KC, et al. PointNet: Deep learning on point sets for 3D classification and segmentation. Honolulu, HI, USA: 30th IEEE/CVF Conference on Computer Vision and Pattern Recognition, 2017: 77-85
[26] Charles RQ, Li Y, Hao S. PointNet⁺⁺: Deep hierarchical feature learning on point sets in a metric space. Long Beach, CA, USA: 31st Annual Conference on Neural Information Processing Systems (NIPS), 2017: 5099-5108
[27] 江祥庆. 林木种子园现状分析与发展建议——以福建省沙县官庄国有林场林木种子园为例. 安徽农学通报, 2020, 26(11): 72-74
[28] 王道杰, 陈倍, 孙健辉. 机载LiDAR点云密度对DEM精度的影响. 测绘通报, 2022(5): 140-144
[29] Zhang W, Qi J, Wan P, et al. An easy-to-use airborne LiDAR data filtering method based on cloth simulation. Remote Sensing, 2016, 8: 501
[30] 李睿, 孙钊, 谢运鸿, 等. 联合U-Net和分水岭算法的高郁闭度杉木纯林树冠信息提取. 应用生态学报, 2023, 34(4): 1024-1034
[31] 李平昊, 申鑫, 代劲松, 等. 机载激光雷达人工林单木分割方法比较和精度分析. 林业科学, 2018, 54(12): 127-136
[32] 谢运鸿, 荆雪慧, 孙钊, 等. 基于实例分割的高郁闭度林分单木树冠无人机遥感提取. 林业科学研究, 2022, 35(5): 14-21
[33] 耿林, 李明泽, 范文, 等. 基于机载LiDAR的单木结构参数及林分有效冠的提取. 林业科学, 2018, 54(7): 62-72