X-ray imaging software tools for HPC clusters and the Cloud

D. Thompson, A. Khassapov, Y. Nesterets, T. Gureyev, John A. Taylor
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引用次数: 3

Abstract

Computed Tomography (CT) is a non-destructive imaging technique widely used across many scientific, industrial and medical fields. It is both computationally and data intensive, and therefore can benefit from infrastructure in the “supercomputing” domain for research purposes, such as Synchrotron science. Our group within CSIRO has been actively developing X-ray tomography and image processing software and systems for HPC clusters. We have also leveraged the use of GPU's (Graphical Processing Units) for several codes enabling speedups by an order of magnitude or more over CPU-only implementations. A key goal of our systems is to enable our targeted “end users”, researchers, easy access to the tools, computational resources and data via familiar interfaces and client applications such that specialized HPC expertise and support is generally not required in order to initiate and control data processing, analysis and visualzation workflows. We have strived to enable the use of HPC facilities in an interactive fashion, similar to the familiar Windows desktop environment, in contrast to the traditional batch-job oriented environment that is still the norm at most HPC installations. Several collaborations have been formed, and we currently have our systems deployed on two clusters within CSIRO, Australia. A major installation at the Australian Synchrotron (MASSIVE GPU cluster) where the system has been integrated with the Imaging and Medical Beamline (IMBL) detector to provide rapid on-demand CT-reconstruction and visualization capabilities to researchers whilst on-site and remotely. A smaller-scale installation has also been deployed on a mini-cluster at the Shanghai Synchrotron Radiation Facility (SSRF) in China. All clusters run the Windows HPC Server 2008 R2 operating system. The two large clusters running our software, MASSIVE and CSIRO Bragg are currently configured as “hybrid clusters” in which individual nodes can be dual-booted between Linux and Windows as demand requires. We have also recently explored the adaptation of our CT-reconstruction code to Cloud infrastructure, and have constructed a working “proof-of-concept” system for the Microsoft Azure Cloud. However, at this stage several challenges remain to be met in order to make it a truly viable alternative to our HPC cluster solution. Recently, CSIRO was successful in its proposal to develop eResearch tools for the Australian Government funded NeCTAR Research Cloud. As part of this project our group will be contributing CT and imaging processing components.
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用于高性能计算集群和云的x射线成像软件工具
计算机断层扫描(CT)是一种无损成像技术,广泛应用于许多科学、工业和医学领域。它既是计算密集型的,也是数据密集型的,因此可以从“超级计算”领域的基础设施中受益,用于研究目的,比如同步加速器科学。我们在CSIRO的团队一直在积极开发用于高性能计算集群的x射线断层扫描和图像处理软件和系统。我们还利用GPU(图形处理单元)对几个代码的使用,使速度比仅使用cpu的实现提高一个数量级或更多。我们系统的一个关键目标是使我们的目标“最终用户”,研究人员,通过熟悉的界面和客户端应用程序轻松访问工具,计算资源和数据,这样就不需要专门的HPC专业知识和支持来启动和控制数据处理,分析和可视化工作流程。我们努力使HPC设施能够以一种交互的方式使用,类似于熟悉的Windows桌面环境,与传统的面向批处理作业的环境形成对比,后者仍然是大多数HPC安装的标准。已经形成了几个合作,我们目前已经将我们的系统部署在澳大利亚CSIRO的两个集群上。在澳大利亚同步加速器(MASSIVE GPU集群)的主要安装中,该系统与成像和医疗光束线(IMBL)探测器集成在一起,为现场和远程研究人员提供快速的按需ct重建和可视化功能。在中国上海同步辐射设施(SSRF)的一个小型集群上也部署了一个较小规模的装置。所有集群的操作系统均为Windows HPC Server 2008 R2。运行我们软件的两个大型集群MASSIVE和CSIRO Bragg目前被配置为“混合集群”,其中单个节点可以根据需要在Linux和Windows之间双启动。我们最近还探索了将ct重建代码适配到云基础设施上,并为微软Azure云构建了一个工作的“概念验证”系统。然而,在这个阶段,为了使它成为我们的HPC集群解决方案的真正可行的替代方案,仍然需要遇到一些挑战。最近,CSIRO成功地提出了为澳大利亚政府资助的NeCTAR研究云开发电子研究工具的建议。作为这个项目的一部分,我们小组将提供CT和成像处理组件。
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