Synergistic Use of ICESat/GLAS and MISR Data for Estimating Forest Aboveground Biomass

doi:10.7525/j.issn.1673-5102.2015.03.012

Abstract

Abstract: Large footprint lidar ICESat/GLAS data contain lots of vertical structure information of ground including forest vertical profile and terrain, and these parameters have high correlation with above ground biomass. Based on waveform data process, we extracted waveform parameters, and used linear stepwise regression model and Erf-BP neural network model to set up the relation between waveform parameters and forest above ground biomass, respectively. We used the Erf-BP neural network model and waveform data of GLAS to inverse the biomass of GLAS footprints. We used a machine learning approach named random forests and the MISR data to build biomass model to extend point to planar and validated the accuracy of this model with the field measured data from plots. The prediction accuracy of Erf-BP neural network model (P=0.965, R_MSE=3.81 t·ha^-1) was better than that of the linear stepwise regression model (P=0.86, R_MSE=4.54 t·ha^-1). The predicting precision of the biomass spatial extensive model was good (P=0.81, R_MSE=2.39 t·ha^-1), the range of inverse biomass in research area was 0-144.4 t·ha^-1, and the mean of the biomass was 59.28 t·ha^-1. The retrieval precision verified by sample data was high (R²=0.72, R_MSE=8.98 t·ha^-1). The estimation was close to real value. Therefore, using few field measurement data to inverse forest ABG in large scale and high precision could provide an effective approach for forestry inventory, ecology research and carbon investigation.

Key words: biomass, ICESat/GLAS, MISR

CLC Number:

WU Di；FAN Wen-Yi. Synergistic Use of ICESat/GLAS and MISR Data for Estimating Forest Aboveground Biomass[J]. Bulletin of Botanical Research, 2015, 35(3): 397-405.

References

1.Fang J Y,Wang G G,Liu G H.Forest biomass of China:an estimation based on the biomass volume relationship［J］.Ecol Appl,1998,8:1084-1091.

2.Leith H,Whittaker R H.Modeling the Primary Productivity of the World［J］.PrimarProductivity of the Biosphere,1975,4:237-263.

3.Lovell J.Using airborne and ground-based ranging lidar to measure canopy structure in Australian forests［J］.Canadian Journal of Remote Sensing,2003,29(5):607-622.

4.Lee S,Wenge N M,Wenze Y,et al.Physically based vertical vegetation structure retrieval from ICESat data:Validation using LVIS in White Mountain National Forest,New Hampshire,USA［J］.Remote Sensing of Environment,2011,115(11):2776-2785.

5.Choi S H,Ni X L,Shi Y L.Allometric Scaling and Resource Limitations Model of Tree Heights:Part 2.Site Based Testing of the Model［J］.Remote Sensing,2013,5:202-223.

6.Boudreau J.Regional aboveground forest biomass using airborne and spaceborne LiDAR in Québec［J］.Remote Sensing of Environment,2008,112(10):3876-3890.

7.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):045011.

8.Sun G,Ranson K J,Guo Z.Forest biomass mapping from lidar and radar synergies［J］.Remote Sensing of Environment,2011,115(11):2906-2916.

9.Helmer E H,Lefsky M A,Roberts D A.Biomass accumulation rates of Amazonian secondary forest and biomass of old-growth forests from Landsat time series and the Geoscience Laser Altimeter System［J］.Journal of Applied Remote Sensing,2009,3(1):033505.

10.Duncanson L,Niemann K O,Wulder M A.Integration of GLAS and Landsat TM data for aboveground biomass estimation［J］.Canadian Journal of Remote Sensing,2010,36(2):129-141.

11.董立新,吴炳方,唐世浩.激光雷达GLAS与ETM联合反演森林地上生物量研究［J］.北京大学学报:自然科学版,2011,47(4):703-710.

12.Mitchard E T A,Saatchi S S,Lewis S L,et al.Comment on ‘A first map of tropical Africa’s above-ground biomass derived from satellite imagery’［J］.Environmental Research Letters,2011,6(4):049001.

13.Simard M,Twilley R R.A systematic method for 3D mapping of mangrove forests based on Shuttle Radar Topography Mission elevation data,ICEsat/GLAS waveforms andfield data:Application to Ciénaga Grande de Santa Marta,Colombia［J］.Remote Sensing of Environment,2008,112:2131-2144.

14.Mitchard E T A,Saatchi S S,White L J T,et al.Mapping tropical forest biomass with radar and spaceborne LiDAR in Lopé National Park,Gabon:overcoming problems of high biomass and persistent cloud［J］.Biogeosciences,2012,9:179-191.

15.Temilola E F,Simard M.Height and biomass of mangroves in Africa from ICESat/GLAS and SRTM［J］.Remote Sensing,2013,34(2):668-681.

16.Guo Z F,Chi H,Sun G Q.Estimating forest aboveground biomass using HJ-1 Satellite CCD and ICESat GLAS waveform data［J］.Science China,2010,53(Suppl.Ⅰ):16-25.

17.Liang S L.Quantitative remote sensing of land surfaces［M］.New York:John Wiley and Sons,2004.

18.Canisius F,Chen J M.Retrieving forest background reflectance in a boreal region from Multi-angle Imaging Spectro Radiometer(MISR) data［J］.Remote Sensing of Environment,2007,107(1):312-321.

19.Chopping M,Moisen M M,Su L H,et al.Large area mapping of southwestern forest crown cover,canopy height,and biomass using the NASA Multiangle Imaging SpectroRadiometer［J］.Remote Sensing of Environment,2008,112:2051-2063.

20.Chopping M,Schaaf C B,Zhao F,et al.Forest structure and aboveground biomass in the southwestern United States from MODIS and MISR［J］.Remote Sensing of Environment,2011,115(11),2943-2953.

21.Brenner A C.Geoscience Laser Altimeter System Algorithm Theoretical Basis Document,version 4［M］.Maryland:NASA Goddard Space Flight Center,2003.

22.Harding D J,Carabajal C C.ICESat waveform measurements of within-footprint topographic relief and vegetation vertical structure［J］.Geophysical research letters,2005,32(21):1-4.

23.庞勇,李增元.地形对大光斑激光雷达森林回波影响研究［J］.林业科学研究,2007,20(4):464-468.

24.Duong H.Processing and application of ICESat large footprint full waveform laser range data(PhD dissertation)［D］.Netherlands:Delft Univ,2010.

25.池泓.基于ICESat/GLAS和MODIS数据的中国森林地上生物量估算研究［D］.北京：中国科学院遥感应用研究所,2011.

26.Duncanson L.Estimating forest canopy height and terrain relief from GLAS waveform metrics［J］.Remote Sensing of Environment,2010,114(1):138-154.

27.Drake J B.Estimation of tropical forest structural characteristics using large-footprint lidar［J］.Remote Sensing of Environment,2001,79(2):305-319.

28.张俊杰.从星载大光斑激光雷达波形数据中提取森林类型信息：以中国东北冷温带森林为例［D］.武汉：武汉大学，2008.

29.Lefsky M A.Revised method for forest canopy height estimation from Geoscience Laser Altimeter System waveforms［J］.Journal of Applied Remote Sensing,2007,1(1):013537-013537-013518.

30.Kimes D.Predicting lidar measured forest vertical structure from multi-angle spectral data［J］.Remote Sensing of Environment,2006,100(4):503-511.

31.Neuenschwander A L.Landcover classification of small-footprint,full-waveform lidar data［J］.Journal of applied remote sensing ,2009,3(1):033544-033544-033513.

32.Bull M,Matthews J.Multi-angle Imaging Spectro-Radiometer Data Products Specifications［S］.California:Jet Propulsion Laboratory,2011.

33.Canisius F,Chen J M.Retrieving forest background reflectance in a boreal region from Multi-angle Imaging Spectro Radiometer(MISR) data［J］.Remote Sensing of Environment,2007,107(1):312-321.

34.杨金明,范文义.小兴安岭主要树种生物量的理论模型［J］.东北林业大学学报，2011,39(3)：46-48.

35.Breiman L.Random forests［J］.Machine Learning,2001,45(1):5-32.

36.Liaw A,Wiener M.Classification and Regression by randomForest［J］.R News,2002,2(3):18.

37.王全才.随机森林特征选择［D］.大连:大连理工大学,2011.

38.毛学刚,李明泽.近30年来小兴安岭地区生物量变化及地统计分析［J］.地理研究,2011,30(6):1111-1120.

39.王蒙,李凤日,贾炜玮,等.黑龙江省落叶松人工林碳储量动态研究［J］.植物研究,2013,33(5):623-628.

40.孙美欧,贾炜玮,李凤日,等.黑龙江省东部地区红松人工中幼龄林生物量研究［J］.植物研究,2014,34(2):232-237.

[1]	Zhiqi CHEN, Haina ZHANG, Jiali LIU, Xianghui LU, Baocheng YANG. Effects of Nitrogen Addition on Root Growth, Biomass Allocation and Non-structural Carbohydrate Content of Cinnamomum bodinier Seedlings in Rare Earth Tailings [J]. Bulletin of Botanical Research, 2024, 44(1): 86-95.
[2]	Jikang XU, Yanhong HE, Tingyan LIU, Longfei HAO, Shengxi ZHANG, Zhaoyi LI. Characteristics of Rhizosphere Soil Microecological Environment of Different Ecological Restoration Vegetation in Arsenic Sandstone Areas [J]. Bulletin of Botanical Research, 2023, 43(4): 531-539.
[3]	Kenian LINGHU, Shu WANG. Responses of Biomass Allocation to Population Density and Soil Water in Abutilon theophrasti at Different Growth Stages [J]. Bulletin of Botanical Research, 2023, 43(2): 272-280.
[4]	Huixiao YANG, Fang XU, Xiaohui YANG, Huanqin LIAO, Weihua ZHANG, Wen PAN. Effects of Different Water and Nutrient Treatments on Growth and Biomass Distribution of Eucalyptus urophylla Clones [J]. Bulletin of Botanical Research, 2022, 42(4): 667-676.
[5]	Ying WANG, Hong-Bo XU, Yang WANG, Meng-Qian WANG, Cheng-Zhong WANG, Yuan-Sen YIN, Xue SUN, Hui ZHOU, Li-Huan ZHUO. Difference of Tolerance to Heavy Metal Zinc Stress of Five Sedum Plants [J]. Bulletin of Botanical Research, 2021, 41(6): 982-992.
[6]	Guo-Yu SUN, Xiao-Yu MA, Jia-Xin YI, Fang-Ping ZHANG, Chun-Hua ZHANG, Kai-Long LI. Effects of Nutrient Supply on Growth Dynamics and Nutrient Allocation of Poplars [J]. Bulletin of Botanical Research, 2021, 41(5): 690-699.
[7]	Min WANG, Run-Hui ZHOU, Fei-Yan YU, Hong-Jun DONG, Cong-Lin CHEN, Jing YU, Jian-Feng HAO. Dynamic Changes of Undergrowth Species Diversity and Biomass of Eucalyptus robusta Plantations at Different Ages [J]. Bulletin of Botanical Research, 2021, 41(4): 496-505.
[8]	SHANG Kan-Kan, ZHANG Xi-Jin, SONG Kun. Variation of Stem-leaf Size Relationship of Woody Plants among Different LifeForms in Shanghai Chenshan Botanical Garden [J]. Bulletin of Botanical Research, 2020, 40(5): 641-647.
[9]	HOU Xue-Yue, DENG Jun-Jie, YAO Zhi-Hong, HUANG Shou-Chen, LI Jia-Zhe, CHA Xin-You, MA De-Zhi, ZHANG Rong-Shu. Effects of Trichoderma on the Growth-related Physiological Indexes of Rocketsalad(Eruca sativa) [J]. Bulletin of Botanical Research, 2020, 40(3): 347-352.
[10]	ZHAO Zhe, JIN Ze-Xin. Effects of Simulated Nitrogen Deposition on the Growth and the Content of Non-structure Carbohydrate of Sinocalycanthus chinensis Seedlings [J]. Bulletin of Botanical Research, 2020, 40(1): 41-49.
[11]	QIU Dong, ZHANG Jing, WU Nan, TAO Ye. Individual Traits and Their Interrelationships of Gametophyte and Sporophyte of a Moss Pogonatum inflexum in the Dalongshan National Forest Park in Anhui Province [J]. Bulletin of Botanical Research, 2019, 39(6): 835-845.
[12]	CAI Nian-Hui, WANG Da-Wei, HUANG Wen-Xue, WU Jun-Wen, WANG Jun-Min, CHEN Shi, XU Yu-Lan, DUAN An-An. Correlation and Path Analysis on Growth Traits and Biomass of Pinus yunnanensis Seedlings [J]. Bulletin of Botanical Research, 2019, 39(6): 853-862.
[13]	LIU Ting-Yan, HAO Long-Fei, WANG Qing-Cheng, BAI Shu-Lan. Effects of Different Planting Densities on Cultivating Quality of Padus maackii Seedlings [J]. Bulletin of Botanical Research, 2019, 39(6): 863-868.
[14]	XIE Zhi-Yu, ZHANG Wen-Hui, WEI Yong-Tao. Morphological Variations and Physiological Characteristics of Phragmites australis in Three Habitats in Yellow River Delta [J]. Bulletin of Botanical Research, 2019, 39(3): 372-379.
[15]	GUO Hao, ZHUANG Wei-Wei, LI Jin. Characteristics of Biomass and Stoichiometry of Four Desert Herbaceous Plants In the Gurbantunggut Desert [J]. Bulletin of Botanical Research, 2019, 39(3): 421-430.