High-Power Test of a C-band Linear Accelerating Structure with an RFSoC-based LLRF System

TL;DR

This paper presents a high-power test of a C-band linear accelerating structure using an RFSoC-based LLRF system, demonstrating improved performance, flexibility, and compactness for future accelerator applications.

Contribution

The paper introduces a novel RFSoC-based LLRF system that directly samples rf signals, reducing complexity and cost, and demonstrates its effectiveness in high-power accelerator tests.

Findings

Amplitude fluctuation below 0.15%

Phase fluctuation below 0.15 degrees

Successful testing with 16.45 MW rf power

Abstract

Normal conducting linear particle accelerators consist of multiple rf stations with accelerating structure cavities. Low-level rf (LLRF) systems are employed to set the phase and amplitude of the field in the accelerating structure, and to compensate the pulse-to-pulse fluctuation of the rf field in the accelerating structures with a feedback loop. The LLRF systems are typically implemented with analogue rf mixers, heterodyne based architectures and discrete data converters. There are multiple rf signals from each of rf station, so the number of rf channels required increases rapidly with multiple rf stations. With many rf channels, the footprint, component cost and system complexity of the LLRF hardware increase significantly. To meet the design goals to be compact and affordable for future accelerators, we have designed the next generation LLRF (NG-LLRF) with higher integration level based on RFSoC technology. The NG-LLRF system samples rf signals directly and performs the rf mixing digitally. The NG-LLRF has been characterized in a loopback mode to evaluate the performance of the system and tested with a standing-wave accelerating structure, a prototype for the Cool Copper Collider (C3) with peak rf power up to 16.45 MW. The loopback test demonstrated amplitude fluctuation below 0.15% and phase fluctuation below 0.15 degree, which are considerably better than the requirements of C3. The rf signals from the different stages of accelerating structure at different power levels are measured by the NG-LLRF, which will be critical references for the control algorithm designs. The NG-LLRF also offers flexibility in waveform modulation, so we have used rf pulses with various modulation schemes which could be useful for controlling some of rf stations in accelerators. In this paper, the high-power test results at different stages of the test setup will be summarized, analyzed and discussed.