• Title/Summary/Keyword: branching surface generation

Search Result 3, Processing Time 0.019 seconds

Contour based Algorithms for Generating 3D Models from CT Images (CT 이미지로부터 3차원 모델 생성을 위한 contour 기반 알고리즘)

  • 류재헌;김현수;이관행
    • Journal of the Korean Society for Precision Engineering
    • /
    • v.20 no.4
    • /
    • pp.174-182
    • /
    • 2003
  • Recently, medical imaging has taken interest on CAD based solution for anatomical part fabrication or finite element analysis of human body. In principle, contours representing object boundary are obtained through image processing techniques. Surface models are then approximated by a skinning method. For this, various methods should be applied to medical images and contours. The major bottleneck of the reconstruction is to remove shape inconsistency between contours and to generate the branching surface. In order to solve these problems, bi-directional smoothing and the composite contour generation method are proposed. Bi-directional smoothing has advantage of removing the shape inconsistency between contours and minimizing shrinkage effect with a large number of iterations. The composite contour by the proposed method ensures smooth transition in branching region.

The Effects of the Microstructures on the Fatigue Crack Propagation Behaviors of Cast Irons (주철의 피로전파거동에 미치는 미세조직의 영향)

  • Kim, Sug-Won;Park, Jin-Sung;Lee, Hyung-Chul;Kim, Dong-Keun;Woo, Kee-Do
    • Journal of Korea Foundry Society
    • /
    • v.25 no.1
    • /
    • pp.16-22
    • /
    • 2005
  • This study aims to investigate the effects of the microstructures and nodule type on the fatigue characteristics of cast iron. Fatigue tests were carried out in tension-tension mode using a servo-hydraulic testing machine with load control mode operating at a frequency of 15 Hz. The tests were conducted at stress ratio R=Kmin/Kmax, of 0.1. Initial crack ${\Dalta}K$ values were highly performed with increase in tensile strength of DCI fatigue specimens. ${\Dalta}K_{th}$ region, fatigue crack propagation was primarily advanced through cell boundary and in periphery of near nodule. Fatigue crack propagation rate of D2 consisted with 2Phase(Ferrite+Pearlite) was slow due to crack closure enhanced by crack deflection and occurred crack branching. The generation of crack branch was occurred due to interaction of crack-nodule. At Threshold and Paris zone, the fractographs of the fatigue fracture surface for DCI show typical striations of a ductile fracture and isolated cleavage planes near graphite. The effect of microstructure on fatigue crack propagation of GC strongly depends on the type of flake. The generation of crack branch occurred due to interaction of crack-nodule. The fractographs of the fatigue fracture surface for GC show cleavage plane along the flake graphite.

Generation of Triangular Mesh of Coronary Artery Using Mesh Merging (메쉬 병합을 통한 관상동맥의 삼각 표면 메쉬 모델 생성)

  • Jang, Yeonggul;Kim, Dong Hwan;Jeon, Byunghwan;Han, Dongjin;Shim, Hackjoon;Chang, Hyuk-jae
    • Journal of KIISE
    • /
    • v.43 no.4
    • /
    • pp.419-429
    • /
    • 2016
  • Generating a 3D surface model from coronary artery segmentation helps to not only improve the rendering efficiency but also the diagnostic accuracy by providing physiological informations such as fractional flow reserve using computational fluid dynamics (CFD). This paper proposes a method to generate a triangular surface mesh using vessel structure information acquired with coronary artery segmentation. The marching cube algorithm is a typical method for generating a triangular surface mesh from a segmentation result as bit mask. But it is difficult for methods based on marching cube algorithm to express the lumen of thin, small and winding vessels because the algorithm only works in a three-dimensional (3D) discrete space. The proposed method generates a more accurate triangular surface mesh for each singular vessel using vessel centerlines, normal vectors and lumen diameters estimated during the process of coronary artery segmentation as the input. Then, the meshes that are overlapped due to branching are processed by mesh merging and merged into a coronary mesh.