一种基于CORDIC的磁共振射频脉冲发生器设计

doi:10.11938/cjmr20253183

摘要/Abstract

摘要：

核磁共振（Nuclear Magnetic Resonance，NMR）射频脉冲发生器对成像质量至关重要. 传统的直接数字频率合成技术（Direct Digital Synthesizer，DDS）要想实现较高精度则需要依赖大容量查找表，因此会占用较多的片上随机块存储器（Block Random Access Memory，BRAM）资源且灵活度受限. 本文提出一种基于坐标旋转数字计算机（Coordinate Rotation Digital Computer，CORDIC）算法的磁共振射频脉冲发生器设计，通过在现场可编程门阵列（Field-Programmable Gate Array，FPGA）中构建自定义CORDIC核实现射频信号的频率、相位和幅度的数字化调制，结合Zynq-7000全可编程片上系统（System on Chip，SoC）实现高集成度、低功耗的硬件架构. 实验结果表明，所设计脉冲发生器可输出频率分辨率为0.046 Hz、相位分辨率为0.005 5˚的射频脉冲信号，且四通道所占用的BRAM资源较传统DDS方案降低约21.4%. 该设计为NMR设备的射频前端小型化与高性能化提供了可行方案.

关键词: 核磁共振, 坐标旋转数字计算机（CORDIC）, 射频脉冲发生器, 片上随机块存储器（BRAM）

Abstract:

In nuclear magnetic resonance (NMR) systems, the radio frequency (RF) pulse generator critically influences imaging quality. Traditional direct digital synthesis (DDS) techniques rely on large-capacity lookup tables to achieve high precision, which results in excessive consumption of on-chip block random access memory (BRAM) resources and limits flexibility. This study presents a novel RF pulse generator design based on the coordinate rotation digital computer (CORDIC) algorithm. By integrating a custom CORDIC core within a field-programmable gate array (FPGA), the proposed system achieves digital modulation of RF signal’s frequency, phase, and amplitude. Combined with a Zynq-7000 system-on-chip (SoC), this design delivers a highly integrated and low-power hardware architecture. Experimental results demonstrate that the generator can output RF pulses with a frequency resolution of 0.046 Hz and a phase resolution of 0.005 5˚, while reducing BRAM resources occupied by four channels by approximately 21.4% compared to the traditional DDS solution. This design offers a feasible solution for achieving miniaturization and high performance in the RF front-end of NMR instruments.

Key words: NMR, CORDIC, radio frequency pulse generator, BRAM

中图分类号:

O482.53

刘颖, 卢志豪, 吕海龙, 章浩伟. 一种基于CORDIC的磁共振射频脉冲发生器设计[J]. 波谱学杂志, 2026, 43(1): 16-26.

LIU Ying, LU Zhihao, LV Hailong, ZHANG Haowei. A Design of CORDIC-based Magnetic Resonance RF Pulse Generator[J]. Chinese Journal of Magnetic Resonance, 2026, 43(1): 16-26.

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方案	核心技术	BRAM占用度	集成度	适用场景
Hemnani等^[12]	单芯FPGA + LUT型DDS	中	低	低场NQR/NMR紧凑信号源
Asfour等^[13]	DDS + SDR + DSP	高	低	低场NMR全数字控制原型
Li等^[14]	FPGA内嵌LUT型DDS	高	低	低场MRI高精度脉冲控制
Zhu等^[15]	数字调制技术+外部DDS芯片	低	低	NMR软脉冲优化
Usmani^[16]	Red Pitaya FPGA + LUT型DDS	高	高	教学场景MRI演示系统
本文方案	CORDIC算法+ Zynq-7000 SoC	低	高	便携低场NMR系统

二进制代码	角度区间	二进制代码	角度区间
000	[0, π/4]	100	[π, 5π/4]
001	[π/4, π/2]	101	[5π/4, 3π/2]
010	[π/2, 3π/4]	110	[3π/2, 7π/4]
011	[3π/4, π]	111	[7π/4, 2π]