This research explores the potential benefits of fusing active and passive medium resolution satellite-borne sensor data for forest structural assessment. Image fusion was applied as a means of retaining disparate data features relevant to modeling and mapping of forest structural attributes in even-aged (4-11 years) Eucalyptus plantations, located in the southern Kwazulu-Natal midlands of South Africa. Remote sensing data used in this research included the visible and near-infrared bands of the Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER), as well as a fine beam (6.25 m resolution) Radarsat-1 image. Both data sets were collected during the spring of 2006 and fused using a modified discrete wavelet transformation. Spatially referenced forest inventory data were also collected during this time, with 122 plots enumerated in 38 plantation compartments. Empirical relationships (ordinary and multiple regression) were used to test whether fused data sources produced superior statistical models. Secondary objectives of the paper included exploring the roles of texture, derived from grey level co-occurrence matrices, and scale in terms of forest modelling at the plot and extended plot levels (Voroni diagrams). Results indicate that single bands from both the optical and SAR data sets were not adept at modeling both basal area and merchantable timber volume with adjusted R2–values < 0.3. An optimized multiple regression approach (adjusted R2) improved results based on mean, range, and standard deviation statistics when compared to single bands, but were still not suitable for operational forest applications (Basal Area = 0.55 & Volume = 0.59). No significant difference was found between fused and non-fused data sets, however optical and fused data sets produced superior models when compared to SAR results. Investigations into potential benefits of using textural indices and varied scales also returned inconclusive results. Findings indicate that the spatial resolutions of both sensors are inappropriate for plantation forest assessment. The frequency of the C-band Radarsat-1 image is for instance unable to penetrate the canopy and interact with the woody structures below canopy, leading to weak statistical models. The lack of variability in both the optical and SAR data lead to unconvincing results in the fused imagery, where in some cases the adjusted R2 results were worse than the single data set approach. It was concluded that future research should focus on high spatial resolution optical and LiDAR data and the development of automated and semi-automated forest inventory procedures.
Reference:
Roberts, JW, Van Aardt, JAN and Ahmed, FB. 2011. Image fusion for enhanced forest structural assessment. International Journal of Remote Sensing, Vol. 32(1), pp 243-266
Roberts, J., Van Aardt, J., & Ahmed, F. (2011). Image fusion for enhanced forest structural assessment. http://hdl.handle.net/10204/4993
Roberts, JW, JAN Van Aardt, and FB Ahmed "Image fusion for enhanced forest structural assessment." (2011) http://hdl.handle.net/10204/4993
Roberts J, Van Aardt J, Ahmed F. Image fusion for enhanced forest structural assessment. 2011; http://hdl.handle.net/10204/4993.
Copyright: 2010 Taylor & Francis. This is a pre print version of the work. The definitive version is published in the International Journal of Remote Sensing, Vol. 32(1), pp 243-266