Development of high-level applications for High Energy Photon Source booster

arXiv - PHYS - Accelerator Physics Pub Date : 2024-06-06 DOI:arxiv-2406.03871

Yuemei Peng, Daheng Ji, Hongfei Ji, Nan Li, Xiaohan Lu, Saike Tian, Yuanyuan Wei, Haisheng Xu, Yaliang Zhao, Yi Jiao, Jingyi Li

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Abstract

The High Energy Photon Source (HEPS), is the first fourth-generation storage ring light source being built in the suburb of Beijing, China. The storage ring was designed with the emittance lower than 60 pm.rad with a circumference of 1.36 km and beam energy of 6 GeV. Its injector contains a 500 MeV S-band Linac and a 454 m booster which was designed as an accumulator at the extraction energy. In the energy ramping control design of HEPS booster, the ramping process was programed to be able to stop and stay at any energy between the injection energy and the extraction energy. This feature enables us to conduct energy-dependent machine studies and ramping curve optimization. The beam commissioning of HEPS Linac finished in June, 2023. And the beam commissioning of booster started in the end of July, 2023. In November 17, main target values proposed in the preliminary design report has been reached. The high-level applications (HLAs) are essential tools for beam commissioning. The development of HLAs, which are based on the framework named Python accelerator physics application set (Pyapas), started in the end of 2021. The HEPS physics team spent more than one year to develop and test the HLAs to meet the requirements of beam commissioning of the booster. Thanks to the modular design, the principle based on physical quantities, and the ability of running simulation models online from the Pyapas, the development efficiency and reliability of the HLAs have been greatly improved. In particular, the principle based on physical quantities allows us to control the beam more intuitively.

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开发高能光子源助推器的高级应用软件

高能光子源（HEPS）是正在中国北京郊区建设的首个第四代存储光源。存储环的设计辐照度低于 60 pm.rad，周长 1.36 千米，光束能量为 6 GeV。其注入器包括一个 500 MeV S 波段直列加速器和一个 454 米的助推器，助推器被设计为提取能量时的蓄能器。在 HEPS 增压器的能量斜坡控制设计中，斜坡过程被编程为能够停止并停留在注入能量和提取能量之间的任何能量。这一特性使我们能够进行能量依赖性机器研究和斜坡曲线优化。高能粒子直读光谱仪的光束调试于2023年6月完成。助推器的光束调试于 2023 年 7 月底开始。17 年 11 月，达到了初步设计报告中提出的主要目标值。高水平应用（HLA）是光束调试的重要工具。高水平应用的开发基于名为 Python 加速器物理应用集（Pyapas）的框架，于 2021 年底开始。HEPS 物理团队花了一年多的时间开发和测试 HLA，以满足助推器光束调试的要求。得益于模块化设计、基于物理量的原理以及从 Pyapas 在线运行仿真模型的能力，HLAs 的开发效率和可靠性得到了极大提高。特别是基于物理量的原理使我们能够更直观地控制光束。

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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arXiv - PHYS - Accelerator Physics

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