Aboveground biomass estimation using spaceborne LiDAR in managed conifer forests in south central British Columbia

dc.contributor.authorDuncanson, Laura Innice
dc.contributor.supervisorNiemann, K. O.
dc.date.accessioned2010-11-15T19:53:47Z
dc.date.available2010-11-15T19:53:47Z
dc.date.copyright2009en
dc.date.issued2010-11-15T19:53:47Z
dc.degree.departmentDept. of Geographyen
dc.degree.levelMaster of Science M.Sc.en
dc.description.abstractIn the context of growing concerns regarding global climatic change, developing methods to assess the carbon storage of various ecosystems has become important. This research attempts to develop low or no cost methods to estimate carbon stock in forests using satellite-based data. More specifically, this research explores the utility of spaceborne Light Detection and Ranging (LiDAR) data for forest canopy height and aboveground biomass estimation. High-resolution (sub meter) airborne LiDAR data were collected and validated for a 75 000 ha area near Clearwater, British Columbia. Airborne LiDAR has been widely demonstrated to yield accurate aboveground biomass estimates. 110 temporally coincident Geospatial Laser Altimeter System (GLAS) waveforms from the study site were used in this research. First, I demonstrate that airborne LiDAR can be manipulated to represent waveform curves with a high degree of similarity to GLAS waveform curves. Based on the relationship between the GLAS and simulated waveforms I am able to visualize the ground contribution to GLAS waveforms. Second, I calculate a suite of novel GLAS waveform metrics and develop models of terrain relief, canopy height, and terrain adjusted canopy height. These models compare favourably to other GLAS studies (terrain relief R2=0.76, canopy height R2= 0.75-0.88) and indicate that terrain relief should be included in GLAS derived canopy height models. Third, I attempt to extrapolate the spatially discrete GLAS estimates to spatially continuous estimates using Landsat TM data. Landsat data have been used extensively for AGBM estimation, although they are known to have limitations for studies in high biomass or structurally complex forests. I develop models to predict GLAS AGBM estimates from Landsat bands and indices (R2=0.6). I then use an airborne LiDAR derived AGBM map to generate a map of over and under prediction of AGBM, and evaluate the success of the model in areas of differing forest species and structure. I conclude that GLAS data is appropriate for AGBM estimation in forests over a wide range of biomass values, but that GLAS and Landsat integration for AGBM estimation should only be conducted in forests with less than approximately 120 Mg/ha of AGBM, 60 years of age, or 60% canopy cover.en
dc.identifier.urihttp://hdl.handle.net/1828/3102
dc.languageEnglisheng
dc.language.isoenen
dc.rightsAvailable to the World Wide Weben
dc.subjectBiomassen
dc.subjectConifersen
dc.subject.lcshUVic Subject Index::Sciences and Engineering::Agriculture::Forests and forestryen
dc.subject.lcshUVic Subject Index::Humanities and Social Sciences::Social Sciences::Geographyen
dc.titleAboveground biomass estimation using spaceborne LiDAR in managed conifer forests in south central British Columbiaen
dc.typeThesisen

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