用于在虚拟和增强现实环境中查看生物医学计算流体动力学结果和相应数据的工作流程。

John Venn, Christopher E Larkee, Guilherme J M Garcia, Vitaliy L Rayz, John F LaDisa
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引用次数: 1

摘要

进行计算流体动力学(CFD)建模的研究人员可能要花费数周的时间来获取成像数据、确定边界条件、运行模拟和后处理文件。然而,结果通常在2D显示器上查看,并且通常在一个时间点上查看,从而将动态和固有的三维数据减少到静态图像。很少实时比较不同病理状态或病例的结果,也很少包括补充数据。因此,通常只有一小部分CFD结果被详细研究,机械刺激和生物反应之间的关联可能被忽视。虚拟现实和增强现实通过利用改进的深度线索,以及自定义内容开发和交互性,促进了立体视觉,可以从CFD结果中提取更多信息,所有这些都在沉浸式方法中。我们的目标是开发一种简单、半自动化的工作流程,以增强在沉浸式虚拟环境(IVE)中查看CFD结果和相关数据的能力。该工作流支持常用的CFD软件,新手在大约一个小时内就能成功完成,证明了其易用性。此外,它的实用性在临床研究领域和IVE平台上得到了证明,涵盖了一系列成本和开发考虑因素。我们乐观地认为,这一进步减少并简化了步骤,促进了沉浸式CFD查看的更广泛使用,将促进工程师和临床医生之间更有效的合作。提供初步临床反馈,并在线提供教学视频、手册、模板和样本数据,以促进社区采用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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A workflow for viewing biomedical computational fluid dynamics results and corresponding data within virtual and augmented reality environments.

Researchers conducting computational fluid dynamics (CFD) modeling can spend weeks obtaining imaging data, determining boundary conditions, running simulations and post-processing files. However, results are typically viewed on a 2D display and often at one point in time thus reducing the dynamic and inherently three-dimensional data to a static image. Results from different pathologic states or cases are rarely compared in real-time, and supplementary data are seldom included. Therefore, only a fraction of CFD results are typically studied in detail, and associations between mechanical stimuli and biological response may be overlooked. Virtual and augmented reality facilitate stereoscopic viewing that may foster extraction of more information from CFD results by taking advantage of improved depth cues, as well as custom content development and interactivity, all within an immersive approach. Our objective was to develop a straightforward, semi-automated workflow for enhanced viewing of CFD results and associated data in an immersive virtual environment (IVE). The workflow supports common CFD software and has been successfully completed by novice users in about an hour, demonstrating its ease of use. Moreover, its utility is demonstrated across clinical research areas and IVE platforms spanning a range of cost and development considerations. We are optimistic that this advancement, which decreases and simplifies the steps to facilitate more widespread use of immersive CFD viewing, will foster more efficient collaboration between engineers and clinicians. Initial clinical feedback is presented, and instructional videos, manuals, templates and sample data are provided online to facilitate adoption by the community.

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