基于无人机机载激光雷达估算黄河三角洲孤岛刺槐林地上生物量

doi:10.11924/j.issn.1000-6850.casb18050091

中国农学通报 ›› 2018, Vol. 34 ›› Issue (26): 52-57.doi: 10.11924/j.issn.1000-6850.casb18050091

所属专题：农业工程

基于无人机机载激光雷达估算黄河三角洲孤岛刺槐林地上生物量

李桂林,王红,宋音

河海大学地球科学与工程学院,河海大学地球科学与工程学院,河海大学地球科学与工程学院

收稿日期:2018-05-15 修回日期:2018-08-01 接受日期:2018-07-17 出版日期:2018-09-19 发布日期:2018-09-19
通讯作者: 李桂林
基金资助:
国家自然科学基金资助项目“黄河三角洲刺槐林健康时空变化成因及模拟”(41471419)。

Estimating Aboveground Biomass of Robinia pseudoacacia in the Yellow River Delta Based on UAV Airborne Laser Radar

Received:2018-05-15 Revised:2018-08-01 Accepted:2018-07-17 Online:2018-09-19 Published:2018-09-19

摘要/Abstract

摘要： 研究旨在利用无人机机载激光雷达数据来计算黄河三角洲孤岛林场刺槐地上生物量。以黄河三角洲孤岛林场刺槐林为研究对象，利用无人机机载激光雷达数据，采用分水岭分割算法从单木尺度提取孤岛林场刺槐的树高和冠幅；然后利用背包移动雷达数据提取8 个样方单株刺槐胸径；再结合异速生长方程，从单木尺度计算8 个样方的刺槐地上生物量。为了验证结果，用野外实测树高和胸径验证雷达数据中提取的单木结构参数；最后利用无人机机载激光雷达提取的树高和冠幅及两者的对数与乘积的对数形式，构建估算刺槐地上生物量模型，对模型估算过程中存在不确定性进行讨论，获得孤岛林场生物量分布图，并且结合前人研究的孤岛刺槐健康状况进行分析。结果表明：（1）基于分水岭分割算法能较精确地从无人机机载激光雷达数据中提取刺槐的单木结构参数。（2）树高与冠幅乘积的对数模型估算效果（R2=0.82，RMSE=3.66 kg/株）优于非对数模型（R2=0.58，RMSE=6.73 kg/株），也优于两者对数的模型（R2=0.76，MSE=4.52 kg/株）。（3）模型构建过程中有一定的不确定性，这种不确定性主要来自单木识别过程。（4）刺槐地上生物量高低与其健康状况有很强的相关性。

关键词: 圆铃大枣, 圆铃大枣, 气候适宜性, 茌平

Abstract: The aim is to calculate the aboveground biomass of Robinia pseudoacacia in Gudao forest farm of the Yellow River Delta based on UAV airborne laser radar. Taking the R. pseudoacacia forest in the island forest of the Yellow River Delta as the research object, using the UAV airborne laser radar data, the watershed segmentation algorithm was used to extract the height and the crown diameter of the R. pseudoacacia in the island forest from the single wood scale; then the backpack mobile radar was used to fit eight samples. The DBH was combined with the allometric growth equation to calculate the biomass of 8 plots of R. pseudoacacia forests from the single wood scale. To verify the results, the measured tree height and DBH were used to validate the single wood structure parameters extracted from the radar data. The tree height and crown diameter extracted by UAV LIDAR and the logarithmic form of logarithm and product logarithm of the UAV were used to construct and estimate the aboveground biomass model of R. pseudoacacia and discuss the uncertainties in the model estimation process. Biomass distribution map was obtained, and previous research on the health status of the island-specific R. pseudoacacia was analyzed. The results showed that: (1) based on the watershed segmentation algorithm, the single wood structure parameters of the R. pseudoacacia could be extracted from the UAV LIDAR data accurately; (2) the logarithmic model of the product of crown and tree height (R2=0.82, RMSE=3.66 kg/plant) was superior to the non-logarithmic model (R2=0.58, RMSE=6.73 kg/plant) and was better than the logarithm model (R2=0.76, RMSE=4.52 kg/plant); (3) there was a certain degree of uncertainty in the model construction process, this uncertainty mainly came from the single wood recognition process; (4) there was a strong correlation between the aboveground biomass and its health status.

中图分类号:

李桂林,王红,宋音. 基于无人机机载激光雷达估算黄河三角洲孤岛刺槐林地上生物量[J]. 中国农学通报, 2018, 34(26): 52-57.

参考文献

[1]曹林, 佘光辉, 代劲松,等. 激光雷达技术估测森林生物量的研究现状及展望[J]. 南京林业大学学报(自然科学版), 2013, 37(3):163-169.
[2]李旺,牛铮,王成等。机载LiDAR数据估算样地和单木尺度森林地上生物量[J].遥感学报,2015(4):669-679
[3]虞海英. 融合机载LIDAR和高光谱数据的滨海湿生植被生物量反演方法研究[D]. 中国测绘科学研究院, 2015.
[4]庞勇, 李增元. 基于机载激光雷达的小兴安岭温带森林组分生物量反演[J]. 植物生态学报, 2012, 36(10):1095-1105.
[5]徐婷, 曹林, 申鑫等. 基于机载激光雷达与Landsat 8 OLI数据的亚热带森林生物量估算[J]. 植物生态学报, 2015, 39(4):309-321.
[6]张耀.机载激光雷达LVIS指标的森林生物量估测[J].现代园艺.2015(4)
[7]孙学莲,舒清态,欧光龙等.基于随机森林回归模型的思茅松人工林生物量遥感估测[J]..林业资源管理.2015(1).
[8]Pflugmacher D, Cohen W B, Kennedy R E, et al. Using Landsat-derived disturbance and recovery history and lidar to map forest biomass dynamics[J]. Remote Sensing of Environment, 2014, 151(8):124-137.
[9]Baccini A, Laporte N, Goetz S J, et al. A first map of tropical Africa’s above-ground biomass derived from satellite imagery[J]. Environmental Research Letters, 2008, 3(4):45011-45019.
[10]Laan C V D, Verweij P A, Qui?ones M J, et al. Analysis of biophysical and anthropogenic variables and their relation to the regional spatial variation of aboveground biomass illustrated for North and East Kalimantan, Borneo[J]. Carbon Balance Management, 2014, 9(1):1-12.
[11]Tangki H, Chappell N A. Biomass variation across selectively logged forest within a 225-km2 region of Borneo and its prediction by Landsat TM[J]. Forest Ecology Management, 2008, 256(11):1960-1970.
[12]Halperin J, Lemay V, Coops N, et al. Canopy cover estimation in miombo woodlands of Zambia: Comparison of Landsat 8 OLI versus RapidEye imagery using parametric, nonparametric, and semiparametric methods[J]. Remote Sensing of Environment, 2016, 179:170-182.
[13]Frazier R J, Coops N C, Wulder M A, et al. Characterization of aboveground biomass in an unmanaged boreal forest using Landsat temporal segmentation metrics[J]. Isprs Journal of Photogrammetry Remote Sensing, 2014, 92(92):137-146.
[14]Zheng G, Chen J M, Tian Q J, et al. Combining remote sensing imagery and forest age inventory for biomass mapping.[J]. Journal of Remote Sensing, 2007, 85(3):616-623.
[15]Ji L, Wylie B K, Nossov D R, et al. Estimating aboveground biomass in interior Alaska with Landsat data and field measurements[J]. International Journal of Applied Earth Observation Geoinformation, 2012, 18(1):451-461.[12]Zheng D, Rademacher J, Chen J, et al. Estimating aboveground biomass using Landsat 7 ETM+ data across a managed landscape in northern Wisconsin, USA[J]. Remote Sensing of Environment, 2004, 93(3):402-411.[13]Günlü A, Ercanli? I, Bas?Kent E Z, et al. Estimating aboveground biomass using Landsat TM imagery: a case study of Anatolian Crimean pine forests in Turkey.[J]. Annals of Forest Research, 2014, 57(2):289-298.[14]Soenen S A, Peddle D R, Hall R J, et al. Estimating aboveground forest biomass from canopy reflectance model inversion in mountainous terrain[J]. Remote Sensing of Environment, 2010, 114(7):1325-1337.[15]Badreldin N, Sanchezazofeifa A. Estimating Forest Biomass Dynamics by Integrating Multi-
[16]汤旭光. 基于激光雷达与多光谱遥感数据的森林地上生物量反演研究[D]. 中国科学院大学, 2013.
[17]李增元,庞勇,刘清旺等.激光雷达森林参数反演技术与方法.北京：科学出版社,2015
[18]国家林业局应对气候变换和节能减排工作领导小组办公室.造林项目碳汇计量与监测指南[M].北京：林业出版社,2008. [State Forestry Administration. Guidelines for Carbon Accounting and Monitoring. Beijing: China Forestry Publishing House, 2008]
[19] Tommaso Jucker, John Caspersen, David Coomes. Allometric equations for integrating remote sensing imagery into forest monitoring programmes[J]. Global Change Biology,2016,23(1):177-190AR.
[20] Hong Wang, Yi Zhong, R Pu etc. Dynamic analysis of Robinia pseudoacacia forest health levels from 1995 to 2013 in the Yellow River Delta, China using multitemporal Landsat imagery[J]. International Journal of Remote Sensing.2018,39(12):4232-4253
[21]Keiko Ioki, Satoshi Tsuyuki, Yasumasa HirataEstimating above-ground biomass of tropical rainforest of different degradation levels in Northern Borneo using airborne LiD

基于无人机机载激光雷达估算黄河三角洲孤岛刺槐林地上生物量

Estimating Aboveground Biomass of Robinia pseudoacacia in the Yellow River Delta Based on UAV Airborne Laser Radar

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