Tree species classification in an extensive forest area using airborne hyperspectral data under varying light conditions

doi:10.1007/s11676-022-01593-z

Abstract

Abstract:

Although airborne hyperspectral data with detailed spatial and spectral information has demonstrated significant potential for tree species classification, it has not been widely used over large areas. A comprehensive process based on multi-flightline airborne hyperspectral data is lacking over large, forested areas influenced by both the effects of bidirectional reflectance distribution function (BRDF) and cloud shadow contamination. In this study, hyperspectral data were collected over the Mengjiagang Forest Farm in Northeast China in the summer of 2017 using the Chinese Academy of Forestry’s LiDAR, CCD, and hyperspectral systems (CAF-LiCHy). After BRDF correction and cloud shadow detection processing, a tree species classification workflow was developed for sunlit and cloud-shaded forest areas with input features of minimum noise fraction reduced bands, spectral vegetation indices, and texture information. Results indicate that BRDF-corrected sunlit hyperspectral data can provide a stable and high classification accuracy based on representative training data. Cloud-shaded pixels also have good spectral separability for species classification. The red-edge spectral information and ratio-based spectral indices with high importance scores are recommended as input features for species classification under varying light conditions. According to the classification accuracies through field survey data at multiple spatial scales, it was found that species classification within an extensive forest area using airborne hyperspectral data under various illuminations can be successfully carried out using the effective radiometric consistency process and feature selection strategy.

Key words: Tree species classification, BRDF effects, Cloud shadow, Airborne hyperspectral data, Random forest

Wen Jia, Yong Pang. Tree species classification in an extensive forest area using airborne hyperspectral data under varying light conditions[J]. JOURNAL OF FORESTRY RESEARCH, 2023, 34(5): 1359-1377.

Wen Jia, Yong Pang. [J]. 林业研究(英文版), 2023, 34(5): 1359-1377.

References 95

1	Alonso-Sarria F, Valdivieso-Ros C, Gomariz-Castillo F. Isolation forests to evaluate class separability and the representativeness of training and validation areas in land cover classification. Remote Sens, 2019, DOI
2	Breiman L. Random forests. Mach Learn, 2001, 45: 5-32, DOI
3	Briechle S, Krzystek P, Vosselman G. Uav-based lidar data and multispectral imagery in the 3D deep neural network pointnet. ISPRS Ann Photogramm Remote Sens Spat Inf Sci, 2020, 2: 203-210, DOI
4	Clark ML, Buck-Diaz J, Evens J. Mapping of forest alliances with simulated multi-seasonal hyperspectral satellite imagery. Remote Sens Environ, 2018, 210: 490-507, DOI
5	Clark ML, Kilham NE. Mapping of land cover in northern California with simulated hyperspectral satellite imagery. ISPRS J Photogramm Remote Sens, 2016, 119: 228-245, DOI
6	Colgan MS, Baldeck CA, Féret JB, Asner GP. Mapping savanna tree species at ecosystem scales using support vector machine classification and BRDF correction on airborne hyperspectral and LiDAR data. Remote Sens, 2012, 4: 3462-3480, DOI
7	Cross MD, Scambos T, Pacifici F, Marshall WE. Determining effective meter-scale image data and spectral vegetation indices for tropical forest tree species differentiation. IEEE J Sel Top Appl Earth Obs Remote Sens, 2019, 12: 2934-2943, DOI
8	Dalponte M, Ørka HO, Gobakken T, Gianelle D, Næsset E. Tree species classification in boreal forests with hyperspectral data. IEEE Trans Geosci Remote Sens, 2013, 51: 2632-2645, DOI
9	Dian YY, Li ZY, Pang Y. Spectral and texture features combined for forest tree species classification with airborne hyperspectral imagery. J Indian Soc Remote Sens, 2015, 43: 101-107, DOI
10	Fassnacht FE, Latifi H, Stereńczak K, Modzelewska A, Lefsky M, Waser LT, Straub C, Ghosh A. Review of studies on tree species classification from remotely sensed data. Remote Sens Environ, 2016, 186: 64-87, DOI
11	Fassnacht FE, Neumann C, Forster M, Buddenbaum H, Ghosh A, Clasen A, Joshi PK, Koch B. Comparison of feature reduction algorithms for classifying tree species with hyperspectral data on three central european test sites. IEEE J Sel Top Appl Earth Obs Remote Sens, 2014, 7: 2547-2561, DOI
12	Feng BK, Zheng C, Zhang WQ, Wang LG, Yue CR. Analyzing the role of spatial features when cooperating hyperspectral and LiDAR data for the tree species classification in a subtropical plantation forest area. J Appl Remote Sens, 2020, 14: 22213, DOI
13	Ferreira MP, Wagner FH, Aragão LEOC, Shimabukuro YE, de Souza Filho CR. Tree species classification in tropical forests using visible to shortwave infrared worldview-3 images and texture analysis. ISPRS J Photogramm Remote Sens, 2019, 149: 119-131, DOI
14	Foody GM. Explaining the unsuitability of the kappa coefficient in the assessment and comparison of the accuracy of thematic maps obtained by image classification. Remote Sens Environ, 2020, 239: 111630, DOI
15	Franklin SE, Hall RJ, Moskal LM, Maudie AJ, Lavigne MB. Incorporating texture into classification of forest species composition from airborne multispectral images. Int J Remote Sens, 2000, 21: 61-79, DOI
16	Freire S, Santos T, Navarro A, Soares F, Silva JD, Afonso N, Fonseca A, Tenedório J. Introducing mapping standards in the quality assessment of buildings extracted from very high resolution satellite imagery. ISPRS J Photogramm Remote Sens, 2014, 90: 1-9, DOI
17	Furniss J, Rahimzadeh-Bajgiran P, Gara TW, Daigle J, Costanza KKL. Mapping ash species across a mixed forest using hyperspectral imagery. Remote Sens Lett, 2022, 13: 441-451, DOI
18	Gann D. Quantitative spatial upscaling of categorical information: the multi-dimensional grid-point scaling algorithm. Methods Ecol Evol, 2019, 10: 2090-2104, DOI
19	Ghorbanian A, Mohammadzadeh A. An unsupervised feature extraction method based on band correlation clustering for hyperspectral image classification using limited training samples. Remote Sens Lett, 2018, 9: 982-991, DOI
20	Ghosh A, Fassnacht FE, Joshi PK, Kochb B. A framework for mapping tree species combining hyperspectral and LiDAR data: role of selected classifiers and sensor across three spatial scales. Int J Appl Earth Obs Geoinf, 2014, 26: 49-63
21	Green AA, Berman M, Switzer P, Craig MD. A transformation for ordering multispectral data in terms of image quality with implications for noise removal. IEEE Trans Geosci Remote Sens, 1988, 26: 65-74, DOI
22	Gustafson KB, Coates PS, Roth CL, Chenaille MP, Ricca MA, Sanchez-Chopitea E, Casazza ML. Using object-based image analysis to conduct high-resolution conifer extraction at regional spatial scales. Int J Appl Earth Obs Geoinf, 2018, 73: 148-155
23	Haralick RM. Statistical and structural approaches to texture. Proc IEEE, 1979, 67: 786-804, DOI
24	Immitzer M, Böck S, Einzmann K, Vuolo F, Pinnel N, Wallner A, Atzberger C. Fractional cover mapping of spruce and pine at 1 ha resolution combining very high and medium spatial resolution satellite imagery. Remote Sens Environ, 2018, 204: 690-703, DOI
25	Jia W, Pang Y, Tortini R, Schläpfer D, Li ZY, Roujean JL. A kernel-driven BRDF approach to correct airborne hyperspectral imagery over forested areas with rugged topography. Remote Sens, 2020, 12(3): 432, DOI
26	Jones TG, Coops NC, Sharma T. Assessing the utility of airborne hyperspectral and LiDAR data for species distribution mapping in the coastal Pacific Northwest, Canada. Remote Sens Environ, 2010, 114: 2841-2852, DOI
27	Ju JC, Gopal S, Kolaczyk ED. On the choice of spatial and categorical scale in remote sensing land cover classification. Remote Sens Environ, 2005, 96: 62-77, DOI
28	Kang YP, Hu XL, Meng QY, Zou YF, Zhang LL, Liu M, Zhao MF. Land cover and crop classification based on red edge indices features of gf-6 wfv time series data. Remote Sens, 2021, 13: 1-22, DOI
29	Kattenborn T, Lopatin J, Förster M, Braun AC, Fassnacht FE. UAV data as alternative to field sampling to map woody invasive species based on combined Sentinel-1 and Sentinel-2 data. Remote Sens Environ, 2019, 227: 61-73, DOI
30	Kavzoglu T. Increasing the accuracy of neural network classification using refined training data. Environ Model Softw, 2009, 24: 850-858, DOI
31	Ke YH, Quackenbush LJ, Im J. Synergistic use of QuickBird multispectral imagery and LIDAR data for object-based forest species classification. Remote Sens Environ, 2010, 114: 1141-1154, DOI
32	Kishore BSPC, Kumar A, Saikia P, Lele N, Pandey AC, Srivastava P, Bhattacharya BK, Khan ML. Major forests and plant species discrimination in mudumalai forest region using airborne hyperspectral sensing. J Asia Pac Biodivers, 2020, 13: 637-651, DOI
33	Kramm T, Hoffmeister D, Curdt C, Maleki S, Khormali F, Kehl M. Accuracy assessment of landform classification approaches on different spatial scales for the iranian loess plateau. ISPRS Int J Geo-Inf, 2017, 6 (11): 366, DOI
34	Kudela RM, Hooker SB, Houskeeper HF, McPherson M. The influence of signal to noise ratio of legacy airborne and satellite sensors for simulating next-generation coastal and inland water products. Remote Sens, 2019, 11（18）: 2071, DOI
35	Lawrence RL, Ripple WJ. Comparisons among vegetation indices and bandwise regression in a highly disturbed, heterogeneous landscape: Mount St. Helens, Washington. Remote Sens Environ, 1998, 64: 91-102, DOI
36	Laybros A, Schläpfer D, Féret JB, Descroix L, Bedeau C, LefevreVincent MJ. Across date species detection using airborne imaging spectroscopy. Remote Sens, 2019, 11: 1-24, DOI
37	Li JL, Pang Y, Li ZY, Jia W (2018a) Tree species classification of airborne hyperspectral image in cloud shadow area. In: International symposium of space optical instrument and application. Springer, pp 389–398
38	Li JL, Pang Y, Li ZY, Jia W. Tree species classification by airborne hyperspectral image of forest in cloud shadow area. For Res, 2019, 32: 136-141
39	Li J, Wu ZC, Hu ZW, Li ZL, Wang YS, Molinier M. Deep learning based thin cloud removal fusing vegetation red edge and short wave infrared spectral information for sentinel-2A imagery. Remote Sens, 2021, 13: 1-31
40	Li JJ, Xi BB, Li YS, Du Q, Wang KY. Hyperspectral classification based on texture feature enhancement and deep belief networks. Remote Sens, 2018, 10(3): 396, DOI
41	Li ZW, Shen HF, Li HF, Xia GS, Gamba P, Zhang LP. Multi-feature combined cloud and cloud shadow detection in GaoFen-1 wide field of view imagery. Remote Sens Environ, 2017, 191: 342-358, DOI
42	Lin Y, Hyyppä J. A comprehensive but efficient framework of proposing and validating feature parameters from airborne LiDAR data for tree species classification. Int J Appl Earth Obs Geoinf, 2016, 46: 45-55
43	Liu LX, Coops NC, Aven NW, Pang Y. Mapping urban tree species using integrated airborne hyperspectral and LiDAR remote sensing data. Remote Sens Environ, 2017, 200: 170-182, DOI
44	Liu T, Abd-Elrahman A. Multi-view object-based classification of wetland land covers using unmanned aircraft system images. Remote Sens Environ, 2018, 216: 122-138, DOI
45	Luo RB, Liao WZ, Zhang HY, Zhang LP, Scheunders P, Pi YG, Philips W. Fusion of hyperspectral and LiDAR data for classification of cloud-shadow mixed remote sensed scene. IEEE J Sel Top Appl Earth Obs Remote Sens, 2017, 10: 3768-3781, DOI
46	Ma L, Li MC, Ma XX, Cheng L, Du PJ, Liu YX. A review of supervised object-based land-cover image classification. ISPRS J Photogramm Remote Sens, 2017, 130: 277-293, DOI
47	Man QX, Dong PL, Yang XM, Wu QY, Han RQ. Automatic extraction of grasses and individual trees in urban areas based on airborne hyperspectral and LiDAR data. Remote Sens, 2020, 12: 1-22, DOI
48	Martínez-Usó A, Pla F, Sotoca JM, García-Sevilla P. Clustering-based hyperspectral band selection using information measures. IEEE Trans Geosci Remote Sens, 2007, 45: 4158-4171, DOI
49	Maschler J, Atzberger C, Immitzer M. Individual tree crown segmentation and classification of 13 tree species using airborne hyperspectral data. Remote Sens, 2018, 10(8): 1218, DOI
50	Meerdink SK, Roberts DA, Roth KL, King JY, Gader PD, Koltunov A. Classifying california plant species temporally using airborne hyperspectral imagery. Remote Sens Environ, 2019, 232: 111308, DOI
51	Modzelewska A, Fassnacht FE, Stereńczak K. Tree species identification within an extensive forest area with diverse management regimes using airborne hyperspectral data. Int J Appl Earth Obs Geoinf, 2020, 84: 101960
52	Modzelewska A, Kamińska A, Fassnacht FE, Stereńczak K. Multitemporal hyperspectral tree species classification in the Białowieża Forest World Heritage site. For an Int J for Res, 2021, 94: 464-476
53	Mostafa Y, Abdelhafiz A. Accurate shadow detection from high-resolution satellite images. IEEE Geosci Remote Sens Lett, 2017, 14: 494-498, DOI
54	Nagendra H, Gadgil M. Biodiversity assessment at multiple scales: linking remotely sensed data with field information. Proc Natl Acad Sci USA, 1999, 96: 9154-9158, DOI
55	Pang Y, Li ZY, Ju HB, Lu H, Jia W, Si L, Guo Y, Liu QW, Li SM, Liu LX, Xie BB, Tan BX, Dian YY. LiCHy: the CAF’s LiDAR, CCD and hyperspectral integrated airborne observation system. Remote Sens, 2016, 8(5): 398, DOI
56	Pontius J, Hanavan RP, Hallett RA, Cook BD, Corp LA. High spatial resolution spectral unmixing for mapping ash species across a complex urban environment. Remote Sens Environ, 2017, 199: 360-369, DOI
57	Pontius RG, Millones M. Death to kappa: birth of quantity disagreement and allocation disagreement for accuracy assessment. Int J Remote Sens, 2011, 32: 4407-4429, DOI
58	Pu RL. Mapping tree species using advanced remote sensing technologies: a state-of-the-art review and perspective. J Remote Sens, 2021, 2021: 1-26, DOI
59	Pu RL, Landry S, Yu QY. Assessing the potential of multi-seasonal high resolution Pléiades satellite imagery for mapping urban tree species. Int J Appl Earth Obs Geoinf, 2018, 71: 144-158
60	Puissant A, Hirsch J, Weber C. The utility of texture analysis to improve per-pixel classification for high to very high spatial resolution imagery. Int J Remote Sens, 2005, 26: 733-745, DOI
61	Qi YJ (2012) Random forest for bioinformatics. In: Ensemble machine learning. Springer, Boston, MA, pp 307–323
62	Queally N, Ye ZW, Zheng T, Chlus A, Schneider F, Pavlick RP, Townsend PA. FlexBRDF: A flexible BRDF correction for grouped processing of airborne imaging spectroscopy flightlines. J Geophys Res Biogeosci, 2022, 127(1): e2021JG006622, DOI
63	Rahimzadeh-Bajgiran P, Hennigar C, Weiskittel A, Lamb S. Forest potential productivity mapping by linking remote-sensing-derived metrics to site variables. Remote Sens, 2020, 12(12): 2056, DOI
64	Roth KL, Roberts DA, Dennison PE, Peterson SH, Alonzo M. The impact of spatial resolution on the classification of plant species and functional types within imaging spectrometer data. Remote Sens Environ, 2015, 171: 45-57, DOI
65	Roujean JL, Leroy M, Deschamps PY. A bidirectional reflectance model of the Earth’s surface for the correction of remote sensing data. J Geophys Res, 1992, 97: 20455, DOI
66	Sánchez de Miguel A, Kyba CCM, Aubé M, Zamorano J, Cardiel N, Tapia C, Bennie J, Gaston KJ. Colour remote sensing of the impact of artificial light at night (I): the potential of the International Space Station and other DSLR-based platforms. Remote Sens Environ, 2019, 224: 92-103, DOI
67	Schläpfer D, Hueni A, Richter R (2018) Cast shadow detection to quantify the aerosol optical thickness for atmospheric correction of high spatial resolution optical imagery. Remote Sens 10 (2): 200
68	Schlapfer D, Richter R, Feingersh T. Operational BRDF effects correction for wide-field-of-view optical scanners (BREFCOR). IEEE Trans Geosci Remote Sens, 2015, 53: 1855-1864, DOI
69	Shang C, Treitz P, Caspersen J, Jones T. Estimating stem diameter distributions in a management context for a tolerant hardwood forest using ALS height and intensity data. Can J Remote Sens, 2017, 43: 79-94, DOI
70	Shao GF, Tang LN, Liao JF. Overselling overall map accuracy misinforms about research reliability. Landsc Ecol, 2019, 34: 2487-2492, DOI
71	Shao GF, Tang LN, Zhang H. Introducing image classification efficacies. IEEE. Access, 2021, 9: 134809-134816, DOI
72	Shen X, Cao L. Tree-species classification in subtropical forests using airborne hyperspectral and LiDAR data. Remote Sens, 2017, 9(11): 1180, DOI
73	Shen X, Cao L, Coops NC, Fan HC, Wu XQ, Liu H, Wang GB, Cao FL. Quantifying vertical profiles of biochemical traits for forest plantation species using advanced remote sensing approaches. Remote Sens Environ, 2020, 250: 112041, DOI
74	Shi YF, Skidmore AK, Wang TJ, Holzwarth S, Heiden U, Pinnel N, Zhu X, Heurich M. Tree species classification using plant functional traits from LiDAR and hyperspectral data. Int J Appl Earth Obs Geoinf, 2018, 73: 207-219
75	Stehman SV, Wickham JD. Pixels, blocks of pixels, and polygons: Choosing a spatial unit for thematic accuracy assessment. Remote Sens Environ, 2011, 115: 3044-3055, DOI
76	Sun H, Ren JC, Zhao HM, Sun GY, Liao WZ, Fang ZY, Zabalza J. Adaptive distance-based band hierarchy (ADBH) for effective hyperspectral band selection. IEEE Trans Cybern, 2022, 52: 215-227, DOI
77	Sun WW, Du Q. Hyperspectral band selection: A review. IEEE Geosci Remote Sens Mag, 2019, 7: 118-139, DOI
78	Tane Z, Roberts D, Koltunov A, Sweeney S, Ramirez C. A framework for detecting conifer mortality across an ecoregion using high spatial resolution spaceborne imaging spectroscopy. Remote Sens Environ, 2018, 209: 195-210, DOI
79	Trier ØD, Salberg AB, Kermit M, Rudjord Ø, Gobakken T, Næsset E, Aarsten D. Tree species classification in Norway from airborne hyperspectral and airborne laser scanning data. Eur J Remote Sens, 2018, 51: 336-351, DOI
80	van Aardt JAN, Wynne RH. Examining pine spectral separability using hyperspectral data from an airborne sensor: An extension of field-based results. Int J Remote Sens, 2007, 28: 431-436, DOI
81	Wang MY, Zheng Y, Huang CQ, Meng R, Pang Y, Jia W, Zhou J, Huang ZH, Fang LC, Zhao F. Assessing Landsat-8 and Sentinel-2 spectral-temporal features for mapping tree species of northern plantation forests in Heilongjiang Province, China. For Ecosyst, 2022, 9: 100032, DOI
82	Waser LT, Ginzler C, Rehush N. Wall-to-Wall tree type mapping from countrywide airborne remote sensing surveys. Remote Sens, 2017, 9(8): 766, DOI
83	Waser LT, Küchler M, Jütte K, Stampfer T. Evaluating the potential of worldview-2 data to classify tree species and different levels of ash mortality. Remote Sens, 2014, 6: 4515-4545, DOI
84	Wetherley EB, Roberts DA, McFadden JP. Mapping spectrally similar urban materials at sub-pixel scales. Remote Sens Environ, 2017, 195: 170-183, DOI
85	Whiteside TG, Maier SW, Boggs GS. International Journal of Applied Earth Observation and Geoinformation Area-based and location-based validation of classified image objects. Int J Appl Earth Obs Geoinf, 2014, 28: 117-130
86	Wietecha M, Jełowicki Ł, Mitelsztedt K, Miścicki S, Stereńczak K. The capability of species-related forest stand characteristics determination with the use of hyperspectral data. Remote Sens Environ, 2019, 231: 111232, DOI
87	Wu YS, Zhang XL. Object-Based tree species classification using airborne hyperspectral images and LiDAR data. Forests, 2020, 11(1): 32, DOI
88	Xiao CW, Li P, Feng ZM, Liu YY, Zhang XZ. Sentinel-2 red-edge spectral indices (RESI) suitability for mapping rubber boom in Luang Namtha Province, northern Lao PDR. Int J Appl Earth Obs Geoinf, 2020, 93: 102176
89	Xu NX, Tian J, Tian QJ, Xu KJ, Tang SF. Analysis of vegetation red edge with different illuminated/shaded canopy proportions and to construct normalized difference canopy shadow index. Remote Sens, 2019, 11: 1-16
90	Zhai H, Zhang HY, Zhang LP, Li PX. Cloud/shadow detection based on spectral indices for multi/hyperspectral optical remote sensing imagery. ISPRS J Photogramm Remote Sens, 2018, 144: 235-253, DOI
91	Zhang B, Zhao L, Zhang XL. Three-dimensional convolutional neural network model for tree species classification using airborne hyperspectral images. Remote Sens Environ, 2020, 247, DOI
92	Zhang GC, Cerra D, Müller R. Shadow detection and restoration for hyperspectral images based on nonlinear spectral unmixing. Remote Sens, 2020, 12: 1-22, DOI
93	Zhang YL, Bai YL, Li CH (2014) Topographic normalization of Landsat TM images in rugged terrain. In: Proceeding of 2014 7th international congress on image and signal processing CISP, pp 580–585
94	Zhou WQ, Huang GL, Troy A, Cadenasso ML. Object-based land cover classification of shaded areas in high spatial resolution imagery of urban areas: a comparison study. Remote Sens Environ, 2009, 113: 1769-1777, DOI
95	Zhu Z, Wang SX, Woodcock CE. Improvement and expansion of the Fmask algorithm: cloud, cloud shadow, and snow detection for Landsats 4–7, 8, and Sentinel 2 images. Remote Sens Environ, 2015, 159: 269-277, DOI