分布式系统加速器实时边缘人工智能(READS)提案

K. Seiya
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引用次数: 1

摘要

我们的目标是将机器学习集成到费米实验室的加速器操作中,并进一步提供一个可访问的框架,该框架也可用于其他具有动态调谐需求的加速器系统。在本提案中,我们将使用嵌入式片上硬件开发实时加速器控制和分布式系统之间的快速通信。我们将在Mu2e试验中演示该技术,通过两个协同项目增加试验的总体占空系数和正常运行时间。首先,我们将使用深度强化学习技术,通过引导优化来提高调节回路的性能,为Mu2e实验提供从交付环中提取的稳定质子束。这需要开发系统的数字孪生体来模拟加速器并开发实时ML算法。其次,我们将使用去混合技术来解开和分类主注入器和回收环中的重叠光束损失,以减少每台机器的整体光束停机时间。该机器学习模型将部署在半自主的操作模式中。这两种应用都需要毫秒级的处理,并将共享类似的硬件ml技术和波束仪器读出技术。费米实验室和西北大学之间的合作将把加速器物理学家、光束仪器工程师、嵌入式系统架构师、FPGA板设计专家和机器学习专家的人才和资源聚集在一起,解决复杂的实时加速器控制挑战,这将增强物理项目。更广泛地说,随着加速器综合体为PIP-II和DUNE时代升级,为加速器实时边缘人工智能分布式系统(READS)开发的框架可以应用于未来的项目。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Accelerator Real-time Edge AI for Distributed Systems (READS) Proposal
Our objective will be to integrate ML into Fermilab accelerator operations and furthermore provide an accessible framework which can also be used by a broad range of other accelerator systems with dynamic tuning needs. We will develop of real-time accelerator control using embedded ML on-chip hardware and fast communication between distributed systems in this proposal. We will demonstrate this technology for the Mu2e experiment by increasing the overall duty factor and uptime of the experiment through two synergistic projects. First, we will use deep reinforcement learning techniques to improve the performance of the regulation loop through guided optimization to provide stable proton beams extracted from the Delivery Ring to the Mu2e experiment. This requires the development of a digital twin of the system to model the accelerator and develop real-time ML algorithms. Second, we will use de-blending techniques to disentangle and classify overlapping beam losses in the Main Injector and Recycler Ring to reduce overall beam downtime in each machine. This ML model will be deployed within a semi-autonomous operational mode. Both applications require processing at the millisecond scale and will share similar ML-in-hardware techniques and beam instrumentation readout technology. A collaboration between Fermilab and Northwestern University will pull together the talents and resources of accelerator physicists, beam instrumentation engineers, embedded system architects, FPGA board design experts, and ML experts to solve complex real-time accelerator controls challenges which will enhance the physics program. More broadly, the framework developed for Accelerator Real-time Edge AI Distributed Systems (READS) can be applied to future projects as the accelerator complex is upgraded for the PIP-II and DUNE era.
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