Prototype Design of a Digital Low-level RF System for S-band Deflectors

arXiv - PHYS - Accelerator Physics Pub Date : 2024-05-16 DOI:arxiv-2405.09796

J. F. Zhu, H. L. Ding, H. K. Li, Y. Li, X. W. Dai, J. W. Han, W. Q. Zhang

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Abstract

S-band deflectors are generally operated on pulsed mode for beam diagnosis. We plan to deploy 5 S-band (2997 MHz) deflectors to accurately measure the longitudinal time distribution of ultra-short electron beam pulses in Shenzhen Superconducting Soft X-ray Free Electron Laser (S3FEL). A microwave system of one deflector consists of a low-level RF system (LLRF), a solid-state amplifier, waveguide couplers, and a klystron, operated in pulse mode with a maximum repetition frequency of 50 Hz. Its microwave amplitude and phase stability must be better than 0.06%/0.08{\deg} (RMS). This article will introduce the prototype design of the hardware, firmware, and software of the digital LLRF system. We use homemade Local Oscillators (LOs) and commercial cards based on the MicroTCA standard in hardware design. The firmware design will use a Non-IQ demodulation and a pulse feedforward algorithm to suppress noise from high voltage of klystron. The software design is based on the EPICS control system architecture, achieving slow control and interface display functions. This report will also show some preliminary test results.

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用于 S 波段偏转器的数字低电平射频系统原型设计

我们计划部署 5 个 S 波段（2997 MHz）偏转器，以精确测量深圳超导软 X 射线自由电子激光器（S3FEL）中超短电子束脉冲的纵向时间分布。一个偏转器的微波系统由一个低电平射频系统（LLRF）、一个固态放大器、波导耦合器和一个速调管组成。其微波振幅和相位稳定性必须优于 0.06%/0.08{deg}（有效值）。本文将介绍数字 LLRF 系统的硬件、固件和软件的原型设计。在硬件设计中，我们使用自制的本地振荡器（LO）和基于 MicroTCA 标准的商用卡。固件设计将使用非 IQ 解调和脉冲前馈算法来抑制来自高电压速调管的噪声。软件设计基于 EPICS 控制系统架构，可实现慢速控制和界面显示功能。本报告还将展示一些初步测试结果。

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arXiv - PHYS - Accelerator Physics

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