Weakly Supported Plane Surface Reconstruction via Plane Segmentation Guided Point Cloud Enhancement

Yan, Shen; Yang, Pengling; Wang, Guangyue; Lai, Shupeng; Zhang, Maojun

doi:10.1109/access.2019.2946456

Cited by 7 publications

(5 citation statements)

References 63 publications

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“…Ref. [19] combines the MVS with PlaneNet to repair incorrect points by correcting and integrating inaccurate prior information from pretrained CNN models and depth map merging methods, then interpolating in weak support planes.…”

Section: Related Workmentioning

confidence: 99%

“…In structured scenes, surfaces with weakly textured regions can be approximately characterized as identical planes. This allows the plane-based methodology [16][17][18][19][20][21] to effectively guide the elimination of the fuzzy matching problem that occurs in weakly textured regions, then improves the completeness of the reconstruction. Following their previous work, the authors of [18,22] introduce the prior plane to help the recovery of weakly textured regions.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Confidence-Guided Planar-Recovering Multiview Stereo for Weakly Textured Plane of High-Resolution Image Scenes

Huang

et al. 2023

Remote Sensing

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Multiview stereo (MVS) achieves efficient 3D reconstruction on Lambertian surfaces and strongly textured regions. However, the reconstruction of weakly textured regions, especially planar surfaces in weakly textured regions, still faces significant challenges due to the fuzzy matching problem of photometric consistency. In this paper, we propose a multiview stereo for recovering planar surfaces guided by confidence calculations, resulting in the construction of large-scale 3D models for high-resolution image scenes. Specifically, a confidence calculation method is proposed to express the reliability degree of plane hypothesis. It consists of multiview consistency and patch consistency, which characterize global contextual information and local spatial variation, respectively. Based on the confidence of plane hypothesis, the proposed plane supplementation generates new reliable plane hypotheses. The new planes are embedded in the confidence-driven depth estimation. In addition, an adaptive depth fusion approach is proposed to allow regions with insufficient visibility to be effectively fused into the dense point clouds. The experimental results illustrate that the proposed method can lead to a 3D model with competitive completeness and high accuracy compared with state-of-the-art methods.

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Section: Related Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Confidence-Guided Planar-Recovering Multiview Stereo for Weakly Textured Plane of High-Resolution Image Scenes

Huang

et al. 2023

Remote Sensing

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show abstract

“…For example, billions of points need to be processed separately, which consumes computer resources, especially when the background, noise, and objects of no interest need to be deleted [2], [13], [46]. Second, the completeness of the point cloud is difficult to guarantee, and sufficient overlap between images is required to cover all regions of interest [12], [14], [47]. In addition, point clouds have problems such as high noise and difficulty in segmentation and registration [5], [48].…”

Section: ) Trouble With Point Cloudsmentioning

confidence: 99%

Rough Registration of BIM Element Projection for Construction Progress Tracking

Xue

Hou

Zeng³

2022

IEEE Access

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Monitoring construction progress is essential for project management. A variety of excellent automatic schedule acquisition methods have been proposed, particularly 3D reconstruction. However, both laser-based and image-based 3D reconstruction methods rely on point clouds which have some inherent defects. In this study, a rough registration method was proposed to obtain construction progress. The method does not generate point clouds during the entire process but determines the actual construction progress by registering the target detection results and the projection of building information model elements. The method was tested at the construction sites of commercial and residential buildings. The experimental results indicated that the registration accuracy reached 95.13%. The average external parameter calibration time and the registration time of each image are 18.57s and 50.59ms, respectively. Compared to similar 3D reconstruction methods, the proposed method is realistic, fast, and simple. This provides a promising method for 3D reconstruction from unordered construction-site images.

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“…These points are often scattered in a 3D space sparsely. Recently, we have witnessed a great deal of efforts that are devoted to drive the point cloud-based applications, such as resampling [3], enhancement [4], [5], saliency detection [6], classification [7], [8], segmentation [9], [10], and compression [2], [11]- [15]. A variety of noises would be inevitably induced by these processing techniques, impairing the reconstruction quality perceived by the human visual system (HVS).…”

Section: Introductionmentioning

confidence: 99%

“…3 extracts keypoints of a point cloud using the geometry information for local graph construction, color gradient moments aggregation and similarity derivation as discussed in Sec. 4. Experimental studies are conducted in Sec.…”

mentioning

confidence: 99%

Inferring Point Cloud Quality via Graph Similarity

Yang¹,

Ma²,

Yan³

et al. 2020

Preprint

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Objective quality estimation of media content plays a vital role in vast applications. Though numerous metrics have been successfully devised for 2D image or video, it still lacks of a counterpart for emerging 3D point clouds with unstructured and sparsely distributed points. We propose the GraphSIM -an objective metric to accurately predict the subjective quality of point cloud with superimposed geometry and color impairments. Motivated by the facts that human vision system is more sensitive to the high spatial-frequency components (e.g., contours, edges), and weighs more to the local structural variations rather individual point intensity, we first extract geometric keypoints by resampling the reference point cloud geometry information to form the object skeleton; we then construct local graphs centered at these keypoints for both reference and distorted point clouds, followed by collectively aggregating color gradient moments (e.g., zeroth, first, and second) that are derived between all other points and centered keypoint in the same local graph for significant feature similarity (a.k.a., local significance) measurement; Final similarity index is obtained by pooling the local graph significance across all color channels and by averaging across all graphs. Our GraphSIM is validated using two large and independent point cloud assessment datasets that involve a wide range of impairments (e.g., re-sampling, compression, additive noise), reliably demonstrating the state-of-the-art performance for all distortions with noticeable gains in predicting the subjective mean opinion score (MOS), compared with those point-wise distance-based metrics adopted in standardization reference software. Ablation studies have further shown that GraphSIM is generalized to various scenarios with consistent performance by examining its key modules and parameters. Models and associated materials will be made to public at https://njuvision.github.io/GraphSIM or http://smt.sjtu.edu.cn/papers/GraphSIM.

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Weakly Supported Plane Surface Reconstruction via Plane Segmentation Guided Point Cloud Enhancement

Cited by 7 publications

References 63 publications

Confidence-Guided Planar-Recovering Multiview Stereo for Weakly Textured Plane of High-Resolution Image Scenes

Confidence-Guided Planar-Recovering Multiview Stereo for Weakly Textured Plane of High-Resolution Image Scenes

Rough Registration of BIM Element Projection for Construction Progress Tracking

Inferring Point Cloud Quality via Graph Similarity

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