Enhancing UAV–SfM 3D Model Accuracy in High-Relief Landscapes by Incorporating Oblique Images

Nesbit, Paul Ryan; Hugenholtz, Chris H.

doi:10.3390/rs11030239

Cited by 161 publications

(183 citation statements)

References 80 publications

(157 reference statements)

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“…Aerial imaging, as applied in this study, may also be limited in capturing significantly occluded panicles [75]. The value of applying both nadir and oblique has been demonstrated in other UAS-based studies [76][77][78]. In our case multi-angle images should provide better view of panicles and likely lead to better detection.…”

Section: Discussionmentioning

confidence: 79%

A Deep Learning Semantic Segmentation-Based Approach for Field-Level Sorghum Panicle Counting

Malambo

Popescu

et al. 2019

Remote Sensing

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Small unmanned aerial systems (UAS) have emerged as high-throughput platforms for the collection of high-resolution image data over large crop fields to support precision agriculture and plant breeding research. At the same time, the improved efficiency in image capture is leading to massive datasets, which pose analysis challenges in providing needed phenotypic data. To complement these high-throughput platforms, there is an increasing need in crop improvement to develop robust image analysis methods to analyze large amount of image data. Analysis approaches based on deep learning models are currently the most promising and show unparalleled performance in analyzing large image datasets. This study developed and applied an image analysis approach based on a SegNet deep learning semantic segmentation model to estimate sorghum panicles counts, which are critical phenotypic data in sorghum crop improvement, from UAS images over selected sorghum experimental plots. The SegNet model was trained to semantically segment UAS images into sorghum panicles, foliage and the exposed ground using 462, 250 × 250 labeled images, which was then applied to field orthomosaic to generate a field-level semantic segmentation. Individual panicle locations were obtained after post-processing the segmentation output to remove small objects and split merged panicles. A comparison between model panicle count estimates and manually digitized panicle locations in 60 randomly selected plots showed an overall detection accuracy of 94%. A per-plot panicle count comparison also showed high agreement between estimated and reference panicle counts (Spearman correlation ρ = 0.88, mean bias = 0.65). Misclassifications of panicles during the semantic segmentation step and mosaicking errors in the field orthomosaic contributed mainly to panicle detection errors. Overall, the approach based on deep learning semantic segmentation showed good promise and with a larger labeled dataset and extensive hyper-parameter tuning, should provide even more robust and effective characterization of sorghum panicle counts.

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Section: Discussionmentioning

confidence: 79%

A Deep Learning Semantic Segmentation-Based Approach for Field-Level Sorghum Panicle Counting

Malambo

Popescu

et al. 2019

Remote Sensing

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“…The advent of UAVs as carrier platforms of active and passive mapping sensors had a huge impact in the field of photogrammetry and remote sensing [14]. The introduction of Structure-from-Motion (SfM) and Dense Image Matching (DIM) techniques providing automatic orientation of entire image blocks and height estimates for every image pixel [15,16] has democratized image-based 3D mapping of topography and dramatically increased the achievable point densities [17,18]. The applicability of UAV-photogrammetry is further facilitated due to the existence of easy-to-use software solutions Remote Sens.…”

Section: Uav-borne Multimedia Photogrammetrymentioning

confidence: 99%

Concept and Performance Evaluation of a Novel UAV-Borne Topo-Bathymetric LiDAR Sensor

Mandlburger

Pfennigbauer²,

Schwarz³

et al. 2020

Remote Sensing

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We present the sensor concept and first performance and accuracy assessment results of a novel lightweight topo-bathymetric laser scanner designed for integration on Unmanned Aerial Vehicles (UAVs), light aircraft, and helicopters. The instrument is particularly well suited for capturing river bathymetry in high spatial resolution as a consequence of (i) the low nominal flying altitude of 50-150 m above ground level resulting in a laser footprint diameter on the ground of typically 10-30 cm and (ii) the high pulse repetition rate of up to 200 kHz yielding a point density on the ground of approximately 20-50 points/m 2 . The instrument features online waveform processing and additionally stores the full waveform within the entire range gate for waveform analysis in post-processing. The sensor was tested in a real-world environment by acquiring data from two freshwater ponds and a 500 m section of the pre-Alpine Pielach River (Lower Austria). The captured underwater points featured a maximum penetration of two times the Secchi depth. On dry land, the 3D point clouds exhibited (i) a measurement noise in the range of 1-3 mm; (ii) a fitting precision of redundantly captured flight strips of 1 cm; and (iii) an absolute accuracy of 2-3 cm compared to terrestrially surveyed checkerboard targets. A comparison of the refraction corrected LiDAR point cloud with independent underwater checkpoints exhibited a maximum deviation of 7.8 cm and revealed a systematic depth-dependent error when using a refraction coefficient of n = 1.36 for time-of-flight correction. The bias is attributed to multi-path effects in the turbid water column (Secchi depth: 1.1 m) caused by forward scattering of the laser signal at suspended particles. Due to the high spatial resolution, good depth performance, and accuracy, the sensor shows a high potential for applications in hydrology, fluvial morphology, and hydraulic engineering, including flood simulation, sediment transport modeling, and habitat mapping.Remote Sens. 2020, 12, 986 2 of 28 UAV-based 3D data acquisition was first accomplished using light-weight camera systems, where advancements in digital photogrammetry and computer vision-enabled automatic data processing workflows for the derivation of dense 3D point clouds based on Structure-from-Motion (SfM) and Dense Image Matching (DIM). Due to advancements in UAV-platform technology and ongoing sensor miniaturization, today compact LiDAR sensors are increasingly integrated on both multi-copter and fixed-wing UAVs, enabling 3D mapping with unprecedented spatial resolution and accuracy. The tackled applications include topographic mapping, geomorphology, infrastructure inspection, environmental monitoring, forestry, and precision farming. While UAV-borne laser scanning (ULS) can already be considered state-of-the-art for mapping tasks above the water table, UAV-based bathymetric LiDAR still lacks behind, mainly due to payload restrictions.The established techniques for mapping bathymetry are single-or multi-beam echo sounding (SBES/MBES), incl...

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“…For example, if wanting to produce a fine spatial resolution map, or look at animal species relationship to habitat structure, absolute precision and accuracy might not be as important as it would be with wanting to establish plant below ground biomass derived from above ground biomass (13) or other volume critical measurements (58). Alongside the aforementioned, there are some more useful general principles for data collection which can be applied to any and all SfM-MVS projects; Collect data with as high an overlap as is practicable – Nearly every SfM-MVS software will have its own guidelines for the amount of side and forward overlap between images, these range from 60%/60% (63) to 60%/80% (64), though recent studies have shown that higher overlap, upto 90% in both side and forward, is better for accuracy and precision within SfM-MVS derived data (65). Collect both nadir and oblique imagery - James and Robson (66) demonstrated that nadir - that is looking straight down - aerial images captured via drone, along with inherent lens distortion of a camera, can induce a systematic error in the form of a doming effect in DEMs.…”

Section: Collection Of Datamentioning

confidence: 99%

“…Collect both nadir and oblique imagery - James and Robson (66) demonstrated that nadir - that is looking straight down - aerial images captured via drone, along with inherent lens distortion of a camera, can induce a systematic error in the form of a doming effect in DEMs. Cunliffe et al (13) have shown that incorporating oblique imagery can help improve the accuracy of SfM-MVS derived DTMs, whilst Nesbit and Hugenholtz (65) have gone on to quantify that incorporating oblique imagery between 20–35° from nadir, along with higher overlap can improve both precision and accuracy by up to 50%. Collect data over a wider area than is required – SfM-MVS data quality deteriorates towards the edges of a reconstruction. Making sure your AOI (area of interest) is central within the data set will ensure there is enough overlap and subsequently be of higher quality (60).…”

Section: Collection Of Datamentioning

confidence: 99%

“…Collect data with as high an overlap as is practicable – Nearly every SfM-MVS software will have its own guidelines for the amount of side and forward overlap between images, these range from 60%/60% (63) to 60%/80% (64), though recent studies have shown that higher overlap, upto 90% in both side and forward, is better for accuracy and precision within SfM-MVS derived data (65).…”

Section: Collection Of Datamentioning

confidence: 99%

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Species and habitat mapping in two dimensions and beyond. Structure-from-Motion Multi-View Stereo photogrammetry for the Conservation Community

DeBell

McKinley

et al. 2019

Preprint

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15Structure-from-Motion Multi View Stereo (SfM-MVS) photogrammetry is a technique 16 by which volumetric data can be derived from overlapping image sets, using changes of an 17 objects position between images to determine its height and spatial structure. Whilst SfM-MVS 18 has fast become a powerful tool for scientific research, its potential lies beyond the scientific 19 setting, since it can aid in delivering information about habitat structure, biomass, landscape 20 topography, spatial distribution of species in both two and three dimensions, and aid in 21 mapping change over time -both actual and predicted. All of which are of strong relevance for 22 the conservation community, whether from a practical management perspective or 23 understanding and presenting data in new and novel ways from a policy perspective. 24 For practitioners outside of academia wanting to use SfM-MVS there are technical 25 barriers to its application. For example, there are many SfM-MVS software options, but 26 knowing which to choose, or how to get the best results from the software can be difficult for 27 the uninitiated. There are also free and open source software options (FOSS) for processing 28 data through a SfM-MVS pipeline that could benefit those in conservation management and 29 policy, especially in instances where there is limited funding (i.e. commonly within grassroots 30 or community-based projects). This paper signposts the way for the conservation community 31 to understand the choices and options for SfM-MVS implementation, its limitations, current 32 best practice guidelines and introduces applicable FOSS options such as OpenDroneMap, 33MicMac, CloudCompare, QGIS and speciesgeocodeR. It will also highlight why and where 34 this technology has the potential to become an asset for spatial, temporal and volumetric studies 35 of landscape and conservation ecology. 36 37 38 39 Relatively new technologies, such as drones (1,2), advances in computational power 40 (3,4), improvements in digital cameras (5), along with classic remote sensing platforms such 41 as kite aerial photography (KAP) and balloons (6,7), have all combined to help create a new 42 opportunity in remote sensing research utilising SfM-MVS photogrammetry. It is these 43 convergent developments that now position SfM-MVS as a cost-effective and democratic tool 44 for conservation research.45SfM-MVS approaches use parallax (i.e. minor displacements in similar images) in 46 conjunction with computer vision techniques, in order to derive 3D structures from 2D data moving object). Data such as overlapping digital photographs and GPS/GNSS (Global 49 Positioning System/Global Navigation Satellite System) information are stitched together, 50 adding distance (X and Y) and height (Z) values to pixels (points) in the combined data, 51 producing a "point cloud" (Figure 1). From this, SfM-MVS software is able to output two 52 dimensional orthographic images containing detailed geographical location information, 53 alongside 2.5 dimensional reconstruct...

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Enhancing UAV–SfM 3D Model Accuracy in High-Relief Landscapes by Incorporating Oblique Images

Cited by 161 publications

References 80 publications

A Deep Learning Semantic Segmentation-Based Approach for Field-Level Sorghum Panicle Counting

A Deep Learning Semantic Segmentation-Based Approach for Field-Level Sorghum Panicle Counting

Concept and Performance Evaluation of a Novel UAV-Borne Topo-Bathymetric LiDAR Sensor

Species and habitat mapping in two dimensions and beyond. Structure-from-Motion Multi-View Stereo photogrammetry for the Conservation Community

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