Using the Error-in-Variable Simultaneous Equations Approach to Construct Compatible Estimation Models of Forest Inventory Attributes Based on Airborne LiDAR

Airborne LiDAR has been extensively used for estimating and mapping forest attributes at various scales. However, most models have been developed separately and independently without considering the intrinsic mathematical relationships and correlations among the estimates, which results in the mathematical and biophysical incompatibility of the estimates. In this paper, using the measurement error model approach, the error-in-variable simultaneous equation (SEq) for airborne LiDAR-assisted estimations of four forest attributes (stand volume, V; basal area, G; mean stand height, H; and diameter at breast height, D) for four forest types (Chinese fir, pine, eucalyptus, and broad-leaved forest) is developed and compared to the independence models (IMs). The results indicated that both the SEqs and IMs performed well, and the rRMSEs of the SEqs were slightly larger than those of the IMs, while the increases in rRMSE were less than 2% for the SEqs. There were statistically significant differences (α = 0.05) in the means of the estimates between SEqs and IMs, even though their average differences were less than ±1.0% for most attributes. There were no statistically significant differences in the mean estimates between SEqs, except for the estimates of the D and G of the eucalyptus forest. The SEqs with H and G as the endogenous variables (EVs) to estimate V performed slightly better than other SEqs in the fir, pine, and broad-leaved forests. The SEq that used D, H, and V as the EVs for estimating G was best in the eucalyptus forests. The SEq ensures the definite mathematical relationship among the estimates of forest attributes is maintained, which is consistent with forest measurement principles and therefore facilitates forest resource management applications, which is an issue that needs to be addressed for airborne LIDAR forest parameter estimation.

[1]  J. M. López-Guede,et al.  Above-ground biomass estimation from LiDAR data using random forest algorithms , 2021, J. Comput. Sci..

[2]  Joanne C. White,et al.  Modelling lidar-derived estimates of forest attributes over space and time: A review of approaches and future trends , 2021, Remote Sensing of Environment.

[3]  Hailemariam Temesgen,et al.  Model-Based Estimation of Forest Inventory Attributes Using Lidar: A Comparison of the Area-Based and Semi-Individual Tree Crown Approaches , 2020, Remote. Sens..

[4]  Liyong Fu,et al.  Prediction of Individual Tree Diameter and Height to Crown Base Using Nonlinear Simultaneous Regression and Airborne LiDAR Data , 2020, Remote. Sens..

[5]  M. Ducey,et al.  The development of allometric systems of equations for compatible area-based LiDAR-assisted estimation , 2020 .

[6]  T. Jones,et al.  Forest Site and Type Variability in ALS-Based Forest Resource Inventory Attribute Predictions over Three Ontario Forest Sites , 2019, Forests.

[7]  Cong Xu,et al.  Evaluation of modelling approaches in predicting forest volume and stand age for small-scale plantation forests in New Zealand with RapidEye and LiDAR , 2018, Int. J. Appl. Earth Obs. Geoinformation.

[8]  O. Kucuk,et al.  Compatible above-ground biomass equations and carbon stock estimation for small diameter Turkish pine (Pinus brutia Ten.) , 2018, Environmental Monitoring and Assessment.

[9]  Hua Sun,et al.  Development of a System of Compatible Individual Tree Diameter and Aboveground Biomass Prediction Models Using Error-In-Variable Regression and Airborne LiDAR Data , 2018, Remote. Sens..

[10]  O. Mutanga,et al.  Stand-volume estimation from multi-source data for coppiced and high forest Eucalyptus spp. silvicultural systems in KwaZulu-Natal, South Africa , 2017 .

[11]  Lin Cao,et al.  Estimating Forest Structural Parameters Using Canopy Metrics Derived from Airborne LiDAR Data in Subtropical Forests , 2017, Remote. Sens..

[12]  Xinyun Chen,et al.  Construction of compatible and additive individual-tree biomass models for Pinus tabulaeformis in China , 2017 .

[13]  Guangxing Wang,et al.  Comparison of seemingly unrelated regressions with error-in-variable models for developing a system of nonlinear additive biomass equations , 2016, Trees.

[14]  Alberto García-Martín,et al.  Use of low point density ALS data to estimate stand-level structural variables in Mediterranean Aleppo pine forest , 2016 .

[15]  Jiquan Chen,et al.  Estimating Stand Volume and Above-Ground Biomass of Urban Forests Using LiDAR , 2016, Remote. Sens..

[16]  W. Zeng,et al.  Developing Aboveground Biomass Equations Both Compatible with Tree Volume Equations and Additive Systems for Single-Trees in Poplar Plantations in Jiangsu Province, China , 2016 .

[17]  Michael J. Falkowski,et al.  Temporal transferability of LiDAR-based imputation of forest inventory attributes , 2015 .

[18]  D. Pitt,et al.  A Comparison of Airborne Laser Scanning and Image Point Cloud Derived Tree Size Class Distribution Models in Boreal Ontario , 2015 .

[19]  Andrew O Finley,et al.  Integrating forest inventory and analysis data into a LIDAR-based carbon monitoring system , 2014, Carbon Balance and Management.

[20]  D. Pitt,et al.  Parametric vs. nonparametric LiDAR models for operational forest inventory in boreal Ontario , 2013 .

[21]  P. Reinartz,et al.  Assessment of Cartosat-1 and WorldView-2 stereo imagery in combination with a LiDAR-DTM for timber volume estimation in a highly structured forest in Germany , 2013 .

[22]  A. Bloom,et al.  Are Inventory Based and Remotely Sensed Above-Ground Biomass Estimates Consistent? , 2013, PloS one.

[23]  Michael A. Wulder,et al.  Modeling Stand Height, Volume, and Biomass from Very High Spatial Resolution Satellite Imagery and Samples of Airborne LiDAR , 2013, Remote. Sens..

[24]  S. Goetz,et al.  A meta-analysis of terrestrial aboveground biomass estimation using lidar remote sensing , 2013 .

[25]  Göran Ståhl,et al.  Model-assisted estimation of change in forest biomass over an 11 year period in a sample survey supported by airborne LiDAR: A case study with post-stratification to provide “activity data” , 2013 .

[26]  G. Asner,et al.  High-resolution mapping of forest carbon stocks in the Colombian Amazon , 2012 .

[27]  G. Asner,et al.  A universal airborne LiDAR approach for tropical forest carbon mapping , 2011, Oecologia.

[28]  Erik Næsset,et al.  Advances and emerging issues in national forest inventories , 2010 .

[29]  A. Hudak,et al.  Nearest neighbor imputation of species-level, plot-scale forest structure attributes from LiDAR data , 2008 .

[30]  M. Maltamo,et al.  The k-MSN method for the prediction of species-specific stand attributes using airborne laser scanning and aerial photographs , 2007 .

[31]  K. Itten,et al.  Estimation of LAI and fractional cover from small footprint airborne laser scanning data based on gap fraction , 2006 .

[32]  E. Næsset Accuracy of forest inventory using airborne laser scanning: evaluating the first nordic full-scale operational project , 2004 .

[33]  E. Næsset,et al.  Laser scanning of forest resources: the nordic experience , 2004 .

[34]  Shouzheng Tang,et al.  Error-in-variable method to estimate parameters for reciprocal base-age invariant site index models , 2004 .

[35]  R. Birdsey,et al.  National-Scale Biomass Estimators for United States Tree Species , 2003, Forest Science.

[36]  Shouzheng Tang,et al.  A parameter estimation program for the error-in-variable model , 2002 .

[37]  E. Næsset Predicting forest stand characteristics with airborne scanning laser using a practical two-stage procedure and field data , 2002 .

[38]  E. Næsset,et al.  Estimating tree heights and number of stems in young forest stands using airborne laser scanner data , 2001 .

[39]  Shouzheng Tang,et al.  Simultaneous equations, error-in-variable models, and model integration in systems ecology , 2001 .

[40]  M. Lefsky,et al.  Laser altimeter canopy height profiles: methods and validation for closed-canopy, broadleaf forests , 2001 .

[41]  R. G. Oderwald,et al.  Dimensionally compatible volume and taper equations , 2001 .

[42]  Annika Kangas,et al.  Effect of errors-in-variables on coefficients of a growth model and on prediction of growth , 1998 .

[43]  J. L. Clutter Compatible growth and yield models for loblolly pine , 1963 .

[44]  Deepak R. Mishra,et al.  A Model to Estimate Leaf Area Index in Loblolly Pine Plantations Using Landsat 5 and 7 Images , 2021, Remote. Sens..

[45]  R. Fournier,et al.  Generalizing predictive models of forest inventory attributes using an area-based approach with airborne LiDAR data , 2015 .

[46]  Erik Næsset,et al.  Introduction to Forestry Applications of Airborne Laser Scanning , 2014 .

[47]  K. Lim,et al.  Operational implementation of a LiDAR inventory in Boreal Ontario , 2011 .

[48]  R. Bailey,et al.  A Multivariate Simultaneous Prediction System for Stand Growth and Yield with Fixed and Random Effects , 2001 .

[49]  J. Means,et al.  Predicting forest stand characteristics with airborne scanning lidar , 2000 .