Processing and feature extraction for three-dimensional bullet point cloud data

Numerous sensors can obtain images or point cloud data on land, however, the rapid attenuation of electromagnetic signals and the lack of light in water have been observed to restrict sensing functions. This study expands the utilization of two- and three-dimensional detection technologies in underwater applications to detect abandoned tires. A three-dimensional acoustic sensor, the BV5000, is used in this study to collect underwater point cloud data. Some pre-processing steps are proposed to remove noise and the seabed from raw data. Point clouds are then processed to obtain two data types: a 2D image and a 3D point cloud. Deep learning methods with different dimensions are used to train the models. In the two-dimensional method, the point cloud is transferred into a bird’s eye view image. The Faster R-CNN and YOLOv3 network architectures are used to detect tires. Meanwhile, in the three-dimensional method, the point cloud associated with a tire is cut out from the raw data and is used as training data. The PointNet and PointConv network architectures are then used for tire classification. The results show that both approaches provide good accuracy.

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Research on Generation Rules of Chest Width Point Curve Based on 3D Female Mannequin

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.796.513 ◽

2013 ◽

Vol 796 ◽

pp. 513-518

Author(s):

Rong Jin ◽

Bing Fei Gu ◽

Guo Lian Liu

Keyword(s):

Point Cloud ◽

Three Dimensional ◽

Upper Body ◽

Secondary Development ◽

Linear Regression Method ◽

Point Cloud Data ◽

Body Type ◽

Cloud Data ◽

Engineering Software ◽

The Individual

In this paper 110 female undergraduates in Soochow University are measured by using 3D non-contact measurement system and manual measurement. 3D point cloud data of human body is taken as research objects by using anti-engineering software, and secondary development of point cloud data is done on the basis of optimizing point cloud data. In accordance with the definition of the human chest width points and other feature points, and in the operability of the three-dimensional point cloud data, the width, thickness, and length dimensions of the curve through the chest width point are measured. Classification of body type is done by choosing the ratio values as classification index which is the ratio between thickness and width of the curve. The generation rules of the chest curve are determined for each type by using linear regression method. Human arm model could be established by the computer automatically. Thereby the individual model of the female upper body mannequin modeling can be improved effectively.

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3D Model Registration Based on Feature Extraction

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.299-300.1091 ◽

2011 ◽

Vol 299-300 ◽

pp. 1091-1094 ◽

Cited By ~ 2

Author(s):

Jiang Zhu ◽

Yuichi Takekuma ◽

Tomohisa Tanaka ◽

Yoshio Saito

Keyword(s):

Feature Extraction ◽

Point Cloud ◽

3D Model ◽

Point Cloud Data ◽

Coordinate Systems ◽

High Precision Measurement ◽

Registration Method ◽

Cloud Data ◽

Cad System ◽

Complicated Model

Currently, design and processing of complicated model are enabled by the progress of the CAD/CAM system. In shape measurement, high precision measurement is performed using CMM. In order to evaluate the machined part, the designed model made by CAD system the point cloud data provided by the measurement system are analyzed and compared. Usually, the designed CAD model and measured point cloud data are made in the different coordinate systems, it is necessary to register those models in the same coordinate system for evaluation. In this research, a 3D model registration method based on feature extraction and iterative closest point (ICP) algorithm is proposed. It could efficiently and accurately register two models in different coordinate systems, and effectively avoid the problem of localized solution.

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Fragmentation calculation method for blast muck piles in open-pit copper mines based on three-dimensional laser point cloud data

International Journal of Applied Earth Observation and Geoinformation ◽

10.1016/j.jag.2021.102338 ◽

2021 ◽

Vol 100 ◽

pp. 102338

Author(s):

Yongzhi Wang ◽

Wenlong Tu ◽

Hui Li

Keyword(s):

Calculation Method ◽

Point Cloud ◽

Three Dimensional ◽

Open Pit ◽

Point Cloud Data ◽

Cloud Data ◽

Copper Mines

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Automated Surface Inspection Using 3D Point Cloud Data in Manufacturing: A Case Study

Volume 3: Manufacturing Equipment and Systems ◽

10.1115/msec2018-6542 ◽

2018 ◽

Cited By ~ 1

Author(s):

Romina Dastoorian ◽

Ahmad E. Elhabashy ◽

Wenmeng Tian ◽

Lee J. Wells ◽

Jaime A. Camelio

Keyword(s):

Point Cloud ◽

Surface Defect ◽

Fault Location ◽

Three Dimensional ◽

Practical Case ◽

3D Point Cloud ◽

Point Cloud Data ◽

Defect Inspection ◽

Cloud Data

With the latest advancements in three-dimensional (3D) measurement technologies, obtaining 3D point cloud data for inspection purposes in manufacturing is becoming more common. While 3D point cloud data allows for better inspection capabilities, their analysis is typically challenging. Especially with unstructured 3D point cloud data, containing coordinates at random locations, the challenges increase with higher levels of noise and larger volumes of data. Hence, the objective of this paper is to extend the previously developed Adaptive Generalized Likelihood Ratio (AGLR) approach to handle unstructured 3D point cloud data used for automated surface defect inspection in manufacturing. More specifically, the AGLR approach was implemented in a practical case study to inspect twenty-seven samples, each with a unique fault. These faults were designed to cover an array of possible faults having three different sizes, three different magnitudes, and located in three different locations. The results show that the AGLR approach can indeed differentiate between non-faulty and a varying range of faulty surfaces while being able to pinpoint the fault location. This work also serves as a validation for the previously developed AGLR approach in a practical scenario.

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VISUALIZATION OF THE CONSTRUCTION OF ANCIENT ROMAN BUILDINGS IN OSTIA USING POINT CLOUD DATA

ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences ◽

10.5194/isprs-archives-xlii-2-w3-345-2017 ◽

2017 ◽

Vol XLII-2/W3 ◽

pp. 345-352

Author(s):

Y. Hori ◽

T. Ogawa

Keyword(s):

Point Cloud ◽

Laser Scanning ◽

Feature Matching ◽

Three Dimensional ◽

Point Clouds ◽

Final Report ◽

Point Cloud Data ◽

Cloud Data ◽

Coverage Accuracy ◽

New Research

The implementation of laser scanning in the field of archaeology provides us with an entirely new dimension in research and surveying. It allows us to digitally recreate individual objects, or entire cities, using millions of three-dimensional points grouped together in what is referred to as "point clouds". In addition, the visualization of the point cloud data, which can be used in the final report by archaeologists and architects, should usually be produced as a JPG or TIFF file. Not only the visualization of point cloud data, but also re-examination of older data and new survey of the construction of Roman building applying remote-sensing technology for precise and detailed measurements afford new information that may lead to revising drawings of ancient buildings which had been adduced as evidence without any consideration of a degree of accuracy, and finally can provide new research of ancient buildings. We used laser scanners at fields because of its speed, comprehensive coverage, accuracy and flexibility of data manipulation. Therefore, we “skipped” many of post-processing and focused on the images created from the meta-data simply aligned using a tool which extended automatic feature-matching algorithm and a popular renderer that can provide graphic results.

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