用于紧凑型 C 波段线性加速器的下一代 LLRF 控制平台

Chao Liu, Ryan Herbst, Larry Ruckman, Emilio Nanni
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摘要

线性加速器(LINAC)的低电平射频(LLRF)控制电路传统上是通过基于外差的架构实现的,这种架构具有用于上下转换的模拟射频混频器和分立数据转换器。我们基于 AMD Xilinx 公司的频率片上系统 (RFSoC) 设备,为 C 波段线性加速器开发了一种新型 LLRF 平台。RFSoC 中集成的数据转换器可直接对 C 波段射频信号进行采样,并以数字方式执行上下混合。LLRF 控制系统信号处理所需的可编程逻辑和处理器也包含在单个 RFSoC 芯片中。由于所有重要组件都集成在一个器件中,基于 RFSoC 的 LLRF 控制平台可以更经济、更紧凑地实现,可广泛应用于加速器领域。本文将介绍新开发的 LLRF 平台的结构和配置。LLRF原型已经在冷库珀对撞机(Cool Cooper Collider)加速结构的高功率测试装置上进行了测试。LLRF和固态放大器(SSA)环回装置证明,1秒内的相位抖动低至115 fs,低于C(^3)的要求。将介绍和讨论从速调管正向和加速结构捕获的峰值功率高达 16.45 MW 的射频信号。
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Next Generation LLRF Control Platform for Compact C-band Linear Accelerator
The Low-Level RF (LLRF) control circuits of linear accelerators (LINACs) are conventionally realized with heterodyne based architectures, which have analog RF mixers for up and down conversion with discrete data converters. We have developed a new LLRF platform for C-band linear accelerator based on the Frequency System-on-Chip (RFSoC) device from AMD Xilinx. The integrated data converters in the RFSoC can directly sample the RF signals in C-band and perform the up and down mixing digitally. The programmable logic and processors required for signal processing for the LLRF control system are also included in a single RFSoC chip. With all the essential components integrated in a device, the RFSoC-based LLRF control platform can be implemented more cost-effectively and compactly, which can be applied to a broad range of accelerator applications. In this paper, the structure and configuration of the newly developed LLRF platform will be described. The LLRF prototype has been tested with high power test setup with a Cool Cooper Collider (C\(^3\)) accelerating structure. The LLRF and the solid state amplifier (SSA) loopback setup demonstrated phase jitter in 1 s as low as 115 fs, which is lower than the requirement of C\(^3\). The rf signals from the klystron forward and accelerating structure captured with peak power up to 16.45 MW will be presented and discussed.
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