基于形状匹配动力学的心脏跳动运动视觉仿真

Takashi Ijiri, T. Ashihara, Nobuyuki Umetani, Yuki Koyama, T. Igarashi, R. Haraguchi, H. Yokota, K. Nakazawa
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引用次数: 0

摘要

形状匹配动力学(SMD)是一种基于几何约束的鲁棒高效弹性模型。本文介绍了我们利用SMD对心脏跳动运动进行视觉模拟的研究。在我们的技术中,心脏由四面体网格模型表示,并通过连接其近邻在每个顶点定义局部区域。在模拟过程中,我们首先根据预定义的肌纤维方向和收缩率收缩所有局部区域。然后利用SMD计算心脏模型的全局形状,使其满足局部收缩区域。我们的技术引入了一个依赖于纤维取向的加权函数来模拟心肌的各向异性刚度。由于我们的技术是基于SMD的,因此可以在商用PC上实时计算心脏运动。
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Visual simulation of cardiac beating motion with shape matching dynamics
A shape matching dynamics (SMD) is a robust and efficient elastic model based on geometric constraints. This article introduces our study #1$ that adopts SMD to visual simulation of cardiac beating motion. In our technique, a heart is represented by a tetrahedral mesh model and a local region is defined at each vertex by connecting its immediate neighbors. During the simulation, we first contract all local regions depending on predefined muscle fiber orientations and contraction rate. Then using SMD, we compute the global shape of the heart model so that it satisfies the contracted local regions. Our technique introduces a fiber-orientationdependent weighting function to emulate an anisotropic stiffness of myocardium. Since our technique is based on SMD, it is possible to compute cardiac motion in real-time on a commercially available PC.
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