New LLRF control system at LNL

2016 IEEE-NPSS Real Time Conference (RT) Pub Date : 2016-06-06 DOI:10.1109/RTC.2016.7543105

D. Bortolato, S. Pavinato, D. Pedretti, M. Betti, F. Gelain, D. Marcato, M. Bellato, R. Isocrate, Matteo Bertocco

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引用次数: 2

Abstract

The Low-level Radio Frequency (LLRF) control system for linear accelerator at Legnaro National Laboratories (LNL) of INFN is being upgraded by a new digital Radio Frequency (RF) controller. This controller is critical to keep phase, amplitude and frequency stability of the RF field in Quarter Wave Resonator (QWR) cavities of the linear accelerator. These cavities work in superconducting condition. The resonance frequency of low beta cavities is 80 MHz, while medium and high beta cavities resonate at 160 MHz. Each RF controller can control at the same time eight different cavities. The RF signals picked-up from the cavities are sampled by RF ADCs. The digitized signals are fed into a field programmable gate array (FPGA) which implements the control loop. The signals processed by the FPGA are in-phase/quadrature modulated and sent to power amplifiers and hence to the cavities. The main feature of the new control system is an all-digital control loop that originates from direct sampling of the antenna RF signal. In-phase and quadrature components are obtained by a suitable choice of the undersampling frequency, while control of the field and phase in the cavity is based on a digital Complex Phase Modulator (CPM). This paper presents the FPGA firmware, the acquisition techniques and the performances of the new RF controller.

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LNL的新型LLRF控制系统

INFN的Legnaro国家实验室(LNL)用于直线加速器的低电平射频(LLRF)控制系统正在通过一种新的数字射频(RF)控制器进行升级。该控制器对保持四分之一波腔内射频场的相位、幅值和频率稳定起着至关重要的作用。这些空腔在超导条件下工作。低腔共振频率为80 MHz，中腔和高腔共振频率为160 MHz。每个射频控制器可以同时控制8个不同的空腔。从空腔中采集的射频信号由射频adc进行采样。数字化后的信号被送入现场可编程门阵列(FPGA)实现控制回路。由FPGA处理的信号经同相/正交调制后送到功率放大器，从而送到腔体。新控制系统的主要特点是一个全数字控制回路，源于天线射频信号的直接采样。通过适当选择欠采样频率来获得同相分量和正交分量，而腔内的场和相位控制则基于数字复相位调制器(CPM)。本文介绍了新型射频控制器的FPGA固件、采集技术和性能。

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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2016 IEEE-NPSS Real Time Conference (RT)

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