Hardware-ased parallel computing tools for realtime haptic and deformation rendering of soft objects

用于软物体实时触觉和变形渲染的硬件并行计算工具

• 批准号: 288305-2009
• 负责人: Sirouspour, Shahin
• 金额: $ 2.62万
• 依托单位: McMaster University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2011
• 资助国家: 加拿大
• 起止时间: 2011-01-01 至 2012-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=480472
• 关键词: Hardware; ased; parallel; computing; tools

Interactive virtual reality simulators are becoming increasingly realistic by incorporating sensing modalities such as vision, kinesthesia and force feedback, also known as haptics. Interactions with non-rigid deformable objects often occur in medical applications involving biological soft-tissue. While a great deal of progress has been made in physics-based mathematical modeling of these interactions, practical applications of such models in real-time simulations have remained limited mainly due to their computational complexity. In particular, applications with haptic feedback would require very high simulation update rates to maintain the system stability, imposing strict timing constraints beyond the capabilities of existing single-processor computers. Building upon our previous work in haptics, this research explores a new paradigm in parallel computing for real-time high-fidelity simulation of soft-object interaction involving visual and haptic feedback. Customized computing tools will be developed that concurrently employ thousands of processing units to solve a large sparse system of equations arising from the finite element models of soft-object deformation. The solution will be obtained at sufficiently high update rates for simulation stability and fidelity. These computing tools will be essentially parallel implementations of recursive equation solvers on synthesized hardware architectures using the Field-Programmable Gate Array (FPGA) technology. Massive parallelization of the computations on multiple interconnected FPGA chips will provide enormous computing power in an inexpensive and compact package enabling the simulation of high-fidelity soft-tissue deformation models. The results of this research will be instrumental in the development of the next generation of computer-assisted surgical systems and medical training simulators. The integration of the resulting core computational technologies into such systems will create improved and new operational capabilities in computer-assisted medical training, diagnosis, and planning and execution of medical interventions. Other scientific applications requiring fast solutions to sparse linear systems of equations will also benefit from this research.

交互式虚拟现实模拟器通过结合视觉、动觉和力反馈（也称为触觉）等传感方式变得越来越逼真。与非刚性可变形物体的相互作用经常发生在涉及生物软组织的医学应用中。虽然这些相互作用的基于物理的数学建模已经取得了很大的进展，但这些模型在实时模拟中的实际应用仍然有限，主要是由于其计算复杂性。特别是，触觉反馈的应用程序将需要非常高的仿真更新速率，以保持系统的稳定性，施加严格的时间限制超出了现有的单处理器计算机的能力。基于我们以前在触觉方面的工作，本研究探索了一种新的并行计算模式，用于实时高保真仿真涉及视觉和触觉反馈的软对象交互。将开发定制的计算工具，同时采用数千个处理单元来求解由软物体变形的有限元模型产生的大型稀疏方程组。该解决方案将获得足够高的更新速率的模拟稳定性和保真度。这些计算工具将基本上是并行实现递归方程求解器的合成硬件架构，使用现场可编程门阵列（FPGA）技术。在多个互连的FPGA芯片上进行大规模并行计算，将在廉价紧凑的封装中提供巨大的计算能力，从而能够模拟高保真软组织变形模型。这项研究的结果将有助于开发下一代计算机辅助手术系统和医疗培训模拟器。将由此产生的核心计算技术整合到这些系统中，将在计算机辅助医疗培训、诊断以及医疗干预的规划和执行方面创造更好的新的业务能力。其他需要快速求解稀疏线性方程组的科学应用也将从这项研究中受益。