Measurement of forest BRF based on mini-tree models

doi:10.6046/gtzyyg.2014.04.10

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Abstract

Based on mini-tree models, the authors constructed forest stands with different distributions to measure bidirectional reflectance factor (BRF) by a mini goniometer. The results show that the observed BRF of simulated forest canopies is reasonable and inter-compared with a three-dimensional BRF model. The reflectance in different view directions indicates a typical "bowl" shape in the near-infrared band, with significant "hot spot" effects in solar principal plane. The study has confirmed that mini-tree models can be applied to the research on forest BRF. The comparisons between different spatial distributions and terrain conditions of tree models demonstrate that forest density and slope have certain effects on forest BRF. Therefore, their features and regularity can contribute to the inversion of the land surface parameters through modeling.

Keywords ZY-3 sensor corrected image product position precision coastal zone

S771.8

Issue Date: 17 September 2014

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	LIU Rongjie
	ZHANG Jie
	LI Xiaomin
	MA Yi

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LIU Rongjie,ZHANG Jie,LI Xiaomin, et al. Measurement of forest BRF based on mini-tree models[J]. REMOTE SENSING FOR LAND & RESOURCES, 2014, 26(4): 56-62.

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https://www.gtzyyg.com/EN/10.6046/gtzyyg.2014.04.10 OR https://www.gtzyyg.com/EN/Y2014/V26/I4/56

[1] Román M O,Gatebe C K,Schaaf C B,et al.Variability in surface BRDF at different spatial scales(30 m~500 m)over a mixed agricultural landscape as retrieved from airborne and satellite spectral measurements[J].Remote Sensing of Environment,2011,115(9):2184-2203.

[2] 齐超,成思竹,赵忠义,等.植被双向反射分布函数的模型及其发展[J].光学技术,2007,33(4):487-490,493. Qi C,Cheng S Z,Zhao Z Y,et al.Models of vegetation bidirectional reflectance distribution function and development[J].Optical Technique,2007,33(4):487-490,493.

[3] Chen J M,Leblanc S G.A four-scale bidirectional reflectance model based on canopy architecture[J].IEEE Transactions on Geoscience and Remote Sensing,1997,35(5):1316-1337.

[4] Li X W,Strahler A,Woodcock C.A hybrid geometric optical-radiative transfer approach for modeling albedo and directional reflectance of discontinuous canopies[J].IEEE Transactions on Geoscience and Remote Sensing,1995,33(2):466

[5] Myneni R B,Asrar G A three-dimensional radiative transfer method for optical remote sensing of vegetated land surfaces[J].Remote Sensing of Environment,1992,41(2/3):105-121.

[6] Wang Z S,Schaaf C B,Lewis P,et al.Retrieval of canopy height suing moderate-resolution imaging spectroradiometer(MODIS) data[J].Remote Sensing of Environment, 2011,115(6):1595-1601.

[7] Milton E J,Schaepman M E,Adnerson K,et al.Progress in field spectroscopy[J].Remote Sensing of Environment,2009,113(s1):S92-S109.

[8] Sandmeier S,Müller C,Hosgood B,et al.Sensitivity analysis and quality assessment of laboratory BRDF data[J].Remote Sensing of Environment,1998,64(2):176-191.

[9] Sandmeier S R,Itten K I.A field goniometer system (FIGOS) for acquisition of hyperspectral BRDF data[J].IEEE Transactions on Geoscience and Remote Sensing,1999,37(2):978-986.

[10] Sandmeier S R.Acquisition of bidirectional reflectance factor data with field goniometers[J].Remote Sensing of Environment,2000,73(3):257-269.

[11] Roman M O,Schaaf C B,Woodcock C E,et al.The MODIS (Collection V005) BRDF/albedo product:Assessment of spatial representativeness over forested landscapes[J].Remote Sensing of Environment,2009,113(11):2476-2498.

[12] Brakke T W,Smith J A,Harnden J M.Bidirectional scattering of light from tree leaves[J].Remote Sensing of Environment,1989,29(2):175-183.

[13] Kuusk A,Kuusk J,Lang M.A dataset for the validation of reflection models[J].Remote Sensing of Environment,2009,113(5):889-892.

[14] Peltoniemi J I,Kaasalainen S,Näränen J,et al.BRDF measurement of understory vegetation in pine forests:Dwarf shrubs,lichen,and moss[J].Remote Sensing of Environment,2005,94(3):343-354.

[15] Kuusk A.A fast invertible canopy reflectance model[J].Remote Sensing of Environment,1995,51(3):342-350.

[16] Combes D,Bousquet L,Jacquemoud S,et al.A new spectrogoniophotometer to measure leaf spectral and directional optical properties[J].Remote Sensing of Environment,2007,109:107-117.

[17] Pisek J,Rautiainenb M,Heiskanenb J,et al.Retrieval of seasonal dynamics of forest understory reflectance in a northern European boreal forest from MODIS BRDF data[J].Remote Sensing of Environment,2012,117:464-468.

[18] 李新,郑小兵,寻丽娜,等.多角度测量系统实现室外BRDF测量[J].光电工程,2008,35(1):66-70. Li X,Zheng X B,Xun L N,et al.Realization of field BRDF acquisition by multiangular measurement system[J].Opto-Electronic Engineering,2008,35(1):66-70.

[19] Qin W,Goel N S.An evaluation of hotspot models for vegetation canopies[J].Remote Sensing Reviews,1995,18:182-306.

[20] Gerard F F,North P R J.Analyzing the effect of structural variability and canopy gaps on forest BRDF using a geometric-optical model[J].Remote Sensing of Environment,1997,62(1):46-62.

[21] Gastellu-Etchegorry J P,Guillevic P,Zagolski F,et al.Modeling BRF and radiation regime of boreal and tropical forests:I.BRF[J].Remote Sensing of Environment,1999,68(3):281-316.

[22] Rautiainen M,Lang M,Mõttus M,et al.Multi-angular reflectance properties of a hemiboreal forest:An analysis using CHRIS PROBA data[J].Remote Sensing of Environment,2008,112(5):2627-2642.

[23] Qin W H,Gerstl S A W.3-D scene modeling of semidesert vegetation cover and its radiation regime[J].Remote Sensing of Environment,2000,74(1):145-162.

[24] 苏红波,王锦地,李小文,等.三维非同温表面热辐射方向性模型的室内模拟实验验证[J].遥感学报,2000,4(s1):71-80. Su H B,Wang J D,Li X W,et al.The indoor simulation and validation of thermal radiation directionality model for three dimensional surface with heterogeneous temperature[J].Journal of Remote Sensing,2000,4(s1):71-80.

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