Deep Learning Classification of 2D Orthomosaic Images and 3D Point Clouds for Post-Event Structural Damage Assessment

Yi-jun, Liao; Mohammadi, Mohammad Ebrahim; Wood, Richard L.

doi:10.3390/drones4020024

Cited by 18 publications

(11 citation statements)

References 24 publications

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“…From 2D images to 3D point clouds, DNNs have also been applied to estimate tornado damage using point clouds generated by SfM. 3D fully convolutional networks (FCNs) were used to segment 3D voxels rasterized from post-wind point clouds [27,28]. 3D voxel segmentation requires values for every voxel in 3D grids, including empty spaces, which were labeled as neutral in their work [27,28].…”

Section: Introductionmentioning

confidence: 99%

“…3D fully convolutional networks (FCNs) were used to segment 3D voxels rasterized from post-wind point clouds [27,28]. 3D voxel segmentation requires values for every voxel in 3D grids, including empty spaces, which were labeled as neutral in their work [27,28]. This additional information could have affected the accuracy of their results by adding to the imbalanced training dataset problem [29].…”

Section: Introductionmentioning

confidence: 99%

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Data-Driven Approaches for Tornado Damage Estimation with Unpiloted Aerial Systems

et al. 2021

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Tornado damage estimation is important for providing insights into tornado studies and assisting rapid disaster response. However, it is challenging to precisely estimate tornado damage because of the large volumes of perishable data. This study presents data-driven approaches to tornado damage estimation using imagery collected from Unpiloted Aerial Systems (UASs) following the 26 June 2018 Eureka Kansas tornado. High-resolution orthomosaics were generated from Structure from Motion (SfM). We applied deep neural networks (DNNs) on the orthomosaics to estimate tornado damage and assessed their performance in four scenarios: (1) object detection with binary categories, (2) object detection with multiple categories, (3) image classification with binary categories, and (4) image classification with multiple categories. Additionally, two types of tornado damage heatmaps were generated. By directly stitching the resulting image tiles from the DNN inference, we produced the first type of tornado damage heatmaps where damage estimates are accurately georeferenced. We also presented a Gaussian process (GP) regression model to build the second type of tornado damage heatmap (a spatially continuous tornado damage heatmap) by merging the first type of object detection and image classification heatmaps. The GP regression results were assessed with ground-truth annotations and National Weather Service (NWS) ground surveys. This detailed information can help NWS Weather Forecast Offices and emergency managers with their damage assessments and better inform disaster response and recovery.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Data-Driven Approaches for Tornado Damage Estimation with Unpiloted Aerial Systems

et al. 2021

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“…The inferred primary reason for the limited number of works is the absence of a large-scale airborne LiDAR dataset tailored to 3D building damage detection. Although an SfM-based point cloud dataset was developed and the performance of 3D voxel-based DNN was tested using the developed dataset in [27], the size of the dataset developed was relatively small. A large-scale dataset is a crucial and fundamental resource for developing advanced algorithms for targeted tasks, as well as for providing training and benchmarking data for such algorithms [28][29][30][31], which requires decent expertise and can be labor-intensive.…”

Section: Introductionmentioning

confidence: 99%

Collapsed Building Detection Using 3D Point Clouds and Deep Learning

et al. 2020

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Collapsed buildings should be detected with the highest priority during earthquake emergency response, due to the associated fatality rates. Although deep learning-based damage detection using vertical aerial images can achieve high performance, as depth information cannot be obtained, it is difficult to detect collapsed buildings when their roofs are not heavily damaged. Airborne LiDAR can efficiently obtain the 3D geometries of buildings (in the form of point clouds) and thus has greater potential to detect various collapsed buildings. However, there have been few previous studies on deep learning-based damage detection using point cloud data, due to a lack of large-scale datasets. Therefore, in this paper, we aim to develop a dataset tailored to point cloud-based building damage detection, in order to investigate the potential of point cloud data in collapsed building detection. Two types of building data are created: building roof and building patch, which contains the building and its surroundings. Comprehensive experiments are conducted under various data availability scenarios (pre–post-building patch, post-building roof, and post-building patch) with varying reference data. The pre–post scenario tries to detect damage using pre-event and post-event data, whereas post-building patch and roof only use post-event data. Damage detection is implemented using both basic and modern 3D point cloud-based deep learning algorithms. To adapt a single-input network, which can only accept one building’s data for a prediction, to the pre–post (double-input) scenario, a general extension framework is proposed. Moreover, a simple visual explanation method is proposed, in order to conduct sensitivity analyses for validating the reliability of model decisions under the post-only scenario. Finally, the generalization ability of the proposed approach is tested using buildings with different architectural styles acquired by a distinct sensor. The results show that point cloud-based methods can achieve high accuracy and are robust under training data reduction. The sensitivity analysis reveals that the trained models are able to locate roof deformations precisely, but have difficulty recognizing global damage, such as that relating to the roof inclination. Additionally, it is revealed that the model decisions are overly dependent on debris-like objects when surroundings information is available, which leads to misclassifications. By training on the developed dataset, the model can achieve moderate accuracy on another dataset with different architectural styles without additional training.

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“…Advances intechnologyandavailabilityhaveboosted the number of applications in many sectors but especially in regions with local and regional dynamic features. Just a few innovative and successful examples of UAS-based monitoring are glacier monitoring for ice flow and mass wasting (Immerzeel et al, 2014;Kraaijenbrink et al, 2016), landslide dynamics monitoring and surface deformation (McKean, 2004;Niethammer et al, 2012;Lucieer et al, 2014;Giordan et al, 2020;Karantanellis et al, 2020), dune dynamics (Ruessink et al, 2018), flood risk mapping (Hashemi-Beni et al, 2018), night-time light monitoring as proxy for economic activity (Li et al, 2020), public health care and health-related services (Amukele et al, 2015;Scalea, 2020), and post-disaster damage assessment (Kerle et al, 2019;Liao et al, 2020).…”

mentioning

confidence: 99%

“…Machine learning and advanced "Big Data" analysis methods have developed considerably over recent years. Methods such as Random Forests, Support Vector Machines, Convolution Neural Networks will contribute largely to the high-speed and possible automated analysis of the huge amount of drone data that can be collected during just a few field surveys (Khan and Al-Mulla, 2019;Liao et al, 2020).…”

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confidence: 99%