3D Modeling of Highway Guardrails for Sight Distance Assessment

The safe and efficient operation of highways largely depends on the adequate provision of sight distance. Small unmanned aerial vehicles (UAVs) can be utilized to efficiently complete data acquisition very soon after identifying an issue when searching for potential highway safety risks. A double grid flight is proposed to obtain an adequate three-dimensional (3D) recreation of the road environment, ensuring an unbiased sight distance output. Then, a dense cloud point is derived through a Structure from Motion Multi-View Stereo process. The point cloud is classified to produce both a terrain model, characterized by its resolution, and a 3D-object model, characterized by the maximum edge length of the entities. The resulting road environment model is utilized to calculate sight distance in a geographic information system. The results enabled the detection of accident-prone locations caused by sight distance limitations. Moreover, the impact of the 3D modeling parameters on the results was assessed.

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A Model Is Worth 1,000 Pictures: Applications of 3D-Modeling in Skull Base Surgery Neuroanatomy Education

10.1055/s-0040-1702387 ◽

2020 ◽

Author(s):

Christopher S. Graffeo ◽

Avital Perry ◽

Lucas P. Carlstrom ◽

Michael J. Link ◽

Jonathan Morris

Keyword(s):

Skull Base ◽

3D Modeling ◽

Skull Base Surgery

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3D modeling of the vascular system

Journal of Theoretical and Applied Vascular Research ◽

10.24019/jtavr.8 ◽

2016 ◽

Vol 1 (1) ◽

pp. 51-58 ◽

Cited By ~ 1

Author(s):

Jean François Uhl ◽

Maxime Chahim ◽

François Cros ◽

Amina Ouchene ◽

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...

Keyword(s):

Augmented Reality ◽

3D Modeling ◽

Vascular System ◽

Arterial System ◽

Chronic Venous Disease ◽

Venous Disease ◽

Software Products ◽

Operative Planning ◽

Morphological Modeling ◽

Pre Treatment

The 3D modeling of the vascular system could be achieved in different ways: In the venous location, the morphological modeling by MSCT venography is used to image the venous system: this morphological modeling tool accurately investigates the 3D morphology of the venous network of our patients with chronic venous disease. It is also a fine educational tool for students who learn venous anatomy, the most complex of the human body. Another kind of modeling (mathematical modeling) is used to simulate the venous functions, and virtually tests the efficacy of any proposed treatments. To image the arterial system, the aim of 3D modeling is to precisely assess and quantify the arterial morphology. The use of augmented reality before an endovascular procedure allows pre-treatment simulation, assisting in pre-operative planning as well as surgical training. In the special field of liver surgery, several 3D modeling software products are available for computer simulations and training purposes and augmented reality.

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