Chinese Journal of Magnetic Resonance ›› 2024, Vol. 41 ›› Issue (1): 99-115.doi: 10.11938/cjmr20233067
• Review Article • Previous Articles
LIU Ying*(),LIN Ling,YUAN Binhua,ZHANG Haowei
Received:
2023-04-27
Published:
2024-03-05
Online:
2023-06-21
Contact:
Tel: 18602168660, E-mail: CLC Number:
LIU Ying, LIN Ling, YUAN Binhua, ZHANG Haowei. Research Progress of MRI Gradient Waveform Generator[J]. Chinese Journal of Magnetic Resonance, 2024, 41(1): 99-115.
Fig. 7
Four adjacent slices of a human brain in the sagittal plane using the T1-SE sequence.The main experimental parameters are as follows: spectrometer frequency (SF) = 14.89 MHz; repetition time (TR) = 500 ms; echo time (TE) = 18 ms; number of excitations (NEX) = 2; image size = 256×256; field of view (FOV) = 240×240 mm2 ; slice thickness = 5 mm; slice gap = 1 mm
Table 2
Comprehensive comparison of various design schemes
设计方案 | 第一作者 | 关键技术 | 主时钟频率 | DAC位宽 | 存储器容量 | 精度、时间分辨率及场强 | 优势和劣势 |
---|---|---|---|---|---|---|---|
基于DSP的设计方案 | Dai[ | DSP(TMS320C6713B,TI)基于PCI总线, 接收来自上位机的 数据并预处理,DSP 代码编译环境为 CCS 2.0 | 300 MHz | PCM1704, 采样频率16~96 kHz, 24 bit | 外接SDRAM 与FLASH: 32 MB/8 MB | 数据精度32 bit, 0.3 T | 性能稳定、成本低廉;灵活性、可扩展性不足,实时性较差[ |
基于FPGA的设计方案 | Kumar[ | 采用FPGA构建处理 器及梯度波形合成 器,使用Vivado软 件进行设计与仿真 | / | 未说明所选用的DAC | FIFO IP核,未说明数据 深度 | 输出梯度波形的最 小分辨率为0.4 ms | 节省了FPGA 资源,减少了 梯度波形生成 时间;系统输 出速率快,可 能导致输出 为空 |
Xing[ | 使用FPGA (EP2C35F484, Altara)及Quartus II 软件共同设计梯度波 形发生器 | 50 MHz | 未说明所选用的DAC | RAM: 483840 bit | 数据精度24 bit, 时间分辨率1 μs | 使用串行运算 减少了FPGA 乘法器资源消 耗;增加了 运算的难度 | |
基于DSP和FPGA结合的设计方案 | Tang[ | DSP(TMS320LF2407A, TI)将数据等传至 FPGA(EP3C55F484, Altera),与Simulink 和System Generator 软件联合设计梯度 波形发生器 | / | PCM1704 | RAM: 292 KB | 数据精度32 bit, 时间分辨率1 μs, <0.7 T | 电路板尺寸小, 成本低;采用 USB进行上位 机与梯度波形 发生器的通信, 通信速度相较 以太网而言较慢 |
Ai[ | 上位机由以太网传 递信号至FPGA (EP3C40F484C6, Altera),DSP (ADSP21369,ADI)实现梯度计算,软件Quartus II及 Moldelsim | 50 MHz | PCM1704 | SDRAM: 1GB/4GB | 幅度参数精度24 bit, 时间参数精度为32 bit, 时间分辨率1 μs, <0.5 T | 切换精度小于100 μs;采用DSP进行梯度 计算在运算速 度及计算量上 存在不足 | |
Xiao[ | DSP(TMS320VC33,TI)接收数据, FPGA(EP2C8Q208, Altera)实现梯度计算 | 60 MHz | 未说明所选用的DAC | ROM: 256 KB, SDRAM: 1 MB | 时间分辨率1 μs, 0.35 T | DSP有32条控制线及24条地址线,有利于对FPGA进行控制及传输信号 |
Table 3
Comparison of gradient field parameters of MRI systems produced by various manufacturers
厂家(3.0 T) | 西门子 | 飞利浦 | 通用电气 | 联影 | ||||
---|---|---|---|---|---|---|---|---|
型号 | Skyra | Prisma | Ingenia | Elition | Architect | Premier | uMR 780 | uMR 790 |
最大梯度场强 /(mT/m) | 45 | 80 | 45 | 45 | 44 | 80 | 42 | 100 |
最大梯度分辨率/(T/m/s) | 200 | 200 | 200 | 220 | 200 | 200 | 220 | 200 |
厂家(0.5 T) | 贝斯达 | 鑫高益 | SternMed | Paramed | ||||
型号 | BTI-050 | OPER-0.5 | Marcom | OpenMR | ||||
最大梯度场强 /(mT/m) | 25 | 24 | 25 | 20 | ||||
最大梯度分辨率/(T/m/s) | 75 | 70 | / | 33.3 |
Table 4
Classification of methods and related principles for eliminating or reducing eddy currents
实现方法 | 原理 | 关键技术 | 分类 | 优势和劣势 |
---|---|---|---|---|
抗涡流板法 | 由高电阻率材料制成,可以在一定程度上减小涡流 | 高电阻率材料 | / | 对厚度的要求严格,设计制作成本高;由于加工工艺限制,板材边缘附近仍会产生涡流[ |
自屏蔽 梯度线圈法 | 在梯度线圈的外面加一组电流方向与其相反的线圈,使成像区域的梯度磁场满足设计需要 | 屏蔽线圈[ | 有源屏蔽 梯度线圈 | 在相邻金属结构上的磁场泄露少,图像质量更好;占据较大的MRI扫描仪空间,且需要对梯度线圈进行特殊而复杂的设计,增加了线圈的成本和功耗 |
无源屏蔽 梯度线圈 | ||||
梯度波形 预加重法 | 通过施加电流过驱动的方法,产生一个附加补偿磁场,以补偿涡流引起的伴随场 | RC电路+滑动变阻器/数控电位器 | 模拟 预加重法 | 数控电位器取代滑动变阻器的方法保证了数据的非易失性,且受环境等温度影响小;精度低,灵活性差[ |
DSP/FPGA结合数学物理方法 | 数字 预加重法 | 能够提高预加重精度并可以灵活扩展预加重参数的个数;占用了DAC位数[ |
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