Deriving forest plot inventory parameters using terrestrial laser scanning in the tropical rainforest of Malaysia

ABSTRACT

Forest inventory parameters, in particular DBH (diameter at breast height) and tree height, can be used to accurately estimate above-ground carbon, which is an important indicator of forest productivity and sequestration of carbon. This study demonstrates and tests a method to automatically and manually derive forest inventory parameters for estimating above-ground carbon (AGC) using a Terrestrial Laser Scanner (TLS). The study was conducted in the Royal Belum State Park of Peninsular Malaysia by establishing 24 circular inventory sample plots of 0.05 ha. A RIEGL VZ-400 TLS system was used to acquire point cloud data of the sample plots through multiple scanning, and these data were further pre-processed and co-registered using the RiSCAN PRO software. The DBH and tree height for each tree within the plots were manually measured using a distance measurement tool in RiSCAN PRO and automatically derived from Computree software using a tree segmentation approach. The inventory parameters derived from TLS were compared with the field measurements for calculating the AGC using an allometric equation. On average, 89% and 90% of the sampled trees were detected from the point cloud data of the plots using the manual and automatic detection methods, respectively. The mean values of R² (coefficient of determination) and RMSE (Root Mean Square Error) for manually measured DBH and tree height across the plots were 0.95 and 2.70 cm, and 0.77 and 2.96 m, respectively. We also obtained an average value of 0.86 and 2.47 cm, and 0.51 and 3.15 m for R² and RMSE, respectively between field-measured and automatically derived DBH and tree height from TLS data across all the sample plots of the study area. Our method provides clear evidence that TLS has the potential to derive forest inventory parameters, which can be used to estimate above-ground carbon in the tropical rainforest accurately.

Acknowledgements

This paper is an outcome of collaborative research by the Faculty of Geoinformation Science and Earth Observation (ITC), University of Twente, The Netherlands, and the Razak School of Engineering and Advanced Technology, University Technology Malaysia (UTM). We would like to acknowledge Christoph Furst from REIGL Laser Management Systems, Dr Ram Kumar Deo from University of Minnesota St. Paul, and A. Khosravipour from ITC for their valuable suggestions. Our special appreciation goes to Dr Kamarrul Azhari Razak of UTM for the excellent management during the fieldwork in Malaysia. We appreciate the support of all members of the Royal Belum Expedition team for their assistance in the field. We are grateful to both anonymous reviewers who provided constructive feedback and comments to improve earlier versions of the manuscript.

Disclosure statement

No potential conflict of interest was reported by the authors.

Supplementary material

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