Abstract
Airborne single-photon lidar (SPL) is a new technology that holds considerable potential for forest structure and carbon monitoring at large spatial scales because it acquires 3D measurements of vegetation faster and more efficiently than conventional lidar instruments. However, SPL instruments use green wavelength (532 nm) lasers, which are sensitive to background solar noise, and therefore SPL point clouds require more elaborate noise filtering than other lidar instruments to determine canopy heights, particularly in daytime acquisitions. Histogram-based aggregation is a commonly used approach for removing noise from photon counting lidar data, but it reduces the resolution of the dataset. Here we present an alternate voxel-based spatial filtering method that filters noise points efficiently while largely preserving the spatial integrity of SPL data. We develop and test our algorithms on an experimental SPL dataset acquired over Garrett County in Maryland, USA. We then compare canopy attributes retrieved using our new algorithm with those obtained from the conventional histogram binning approach. Our results show that canopy heights derived using the new algorithm have a strong agreement with field-measured heights (r2 = 0.69, bias = 0.42 m, RMSE = 4.85 m) and discrete return lidar heights (r2 = 0.94, bias = 1.07 m, RMSE = 2.42 m). Results are consistently better than height accuracies from the histogram method (field data: r2 = 0.59, bias = 0.00 m, RMSE = 6.25 m; DRL: r2 = 0.78, bias = −0.06 m and RMSE = 4.88 m). Furthermore, we find that the spatial-filtering method retains fine-scale canopy structure detail and has lower errors over steep slopes. We therefore believe that automated spatial filtering algorithms such as the one presented here can support large-scale, canopy structure mapping from airborne SPL data.
Highlights
Single photon lidar (SPL) is a new technology for rapid three-dimensional mapping of terrain and forest structure over large areas at high resolution [1]
At a nominal above ground level (AGL) of 2.3 km, High-Resolution Quantum Lidar System (HRQLS) produced a swath of 1.62 km and a target spot of 5 × 5 m array on the ground, resulting in a ground-pixel dimension of 0.5 m and a mean point density of 12 per m2 per conical scan
The 98th percentile height showed the highest agreement with field data r2 = 0.70, bias = −0.12 m and root mean square error (RMSE) = 4.77 m, while p97 had the lowest bias of 0.07 when compared with discrete return lidar (DRL) heights
Summary
Single photon lidar (SPL) is a new technology for rapid three-dimensional mapping of terrain and forest structure over large areas at high resolution [1]. SPL requires only one detected photon at each ranging measurement, instead of hundreds in the case of conventional sensors [2,3] It allows enhanced 3D mapping with greater coverage, spatial resolution, and photon density, and reduced acquisition time. Despite these advantages, SPL data includes more solar background noise than conventional near-infrared lidar instruments because of its use of green wavelength lidar and high photon detecting sensitivity [4,5,6]. Existing methods largely rely on detecting maximum canopy height through histogram-based filtering algorithms [4,8,10,11] This is achieved by aggregating point clouds into pseudo-waveforms at coarse spatial and vertical resolutions.
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