Research on the Calibration Method and Device of Ultrasonic Chordal Phantom Based on Intelligent Technology

QI Fang; WANG Tongyu; LIU Zhe; ZHU Weimin

doi:10.12338/j.issn.2096-9015.2023.0350

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QI Fang, WANG Tongyu, LIU Zhe, ZHU Weimin. Research on the Calibration Method and Device of Ultrasonic Chordal Phantom Based on Intelligent Technology[J]. Metrology Science and Technology. doi: 10.12338/j.issn.2096-9015.2023.0350

Citation:

QI Fang, WANG Tongyu, LIU Zhe, ZHU Weimin. Research on the Calibration Method and Device of Ultrasonic Chordal Phantom Based on Intelligent Technology[J]. Metrology Science and Technology. doi: 10.12338/j.issn.2096-9015.2023.0350

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Research on the Calibration Method and Device of Ultrasonic Chordal Phantom Based on Intelligent Technology

doi: 10.12338/j.issn.2096-9015.2023.0350

QI Fang^1
,,
WANG Tongyu¹,
LIU Zhe²,
ZHU Weimin^{1
,
,}

1.
Henan Institute of Metrology Testing, Zhengzhou 450047, China
2.
Beijing University of Technology, Beijing 100124, China

Received Date: 2023-12-15
Accepted Date: 2024-01-11
Rev Recd Date: 2024-03-12

Available Online: 2024-03-18

Abstract

Abstract

This article studies the calibration method of ultrasonic chordal phantom, designed and developed a ultrasonic chord phantom calibration device based on intelligent technology. This device can collect the rotational speeds of the ultrasonic capstan and driven wheels of the chordal phantom through a dual channel laser velocimeter and input them into the analysis system for analysis and calculation, in order to calculate the chordal speed of the chordal phantom. And it can collect the line speeds of each point within the physiological waveform cycle and compare them with the standard physiological waveform line speeds in the database, in order to determine whether the physiological waveform curve at the setting speed meets the requirements. The experimental results indicate that compared to the existing detection methods for constant blood flow velocity, this method and device can not only conveniently and efficiently detect constant blood flow velocity, but also detect physiological waveforms intelligently, they solved the calibration and traceability problem of ultrasonic chordal phantom effectively.
- metrology,
- chordal phantom,
- capstan,
- linear velocity,
- laser velocimetry,
- physiological waveform

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References(30)

References

[1]	陈思平. 医学超声影像产业现状和发展[J]. 应用声学, 2005, 24(4): 201-207.
[2]	刘吉斌. 超声影像新技术现状及展望[C]. 北京: 北京超声医学学术大会, 2012.
[3]	国家质量监督检疫总局. 彩色多普勒超声诊断仪(血流测量部分)校准规范: JJF1438-2013 [S]. 北京: 中国计量出版社, 2013.
[4]	夏勋荣, 姚绍卫. JJF1438-2013《彩色多普勒超声诊断仪(血流测量部分)校准规范》解读[J]. 中国计量, 2014(4): 120-121.
[5]	陈远, 赵志敏, 郑敏, 等. 人体微小管状血管血流流速自动测量方法研究[J]. 计量学报, 2010, 31(2): 123-126.
[6]	杨平, 边文萍, 朱岩, 等. 彩超血流速度测量功能的校准应用研究[J]. 计量技术, 2010(2): 39-42.
[7]	孙荣荣, 眭国平, 陆逊. 医用超声经颅多普勒血流分析仪校准方法研究[J]. 仪器仪表学报, 2014, 35(12): 178-181.
[8]	张靖, 冯磊, 李丹. 超声多普勒术中及浅表血流模拟系统研制[J]. 医疗装备, 2016, 29(5): 35-36. doi: 10.3969/j.issn.1002-2376.2016.05.024
[9]	赵旭. 超声多普勒术中及浅表血流模拟系统的研制[D]. 北京: 北京理工大学, 2016.
[10]	徐阳, 傅燕翔, 王慧娟, 等. 超声经颅多普勒血流分析仪检测系统的研制[J]. 工业计量, 2020(6): 39-41.
[11]	罗犇, 童云梅, 朱清, 等. 超声经颅多普勒血流分析仪检测装置研究[J]. 品牌与标准化, 2022(3): 63-65.
[12]	国家药品监督管理局. 超声经颅多普勒血流分析仪: YY/T 0593-2022 [S]. 北京: 中国标准出版社, 2022.
[13]	林栋, 杨伟文, 杨木秀, 等. 定量确定超声多普勒频谱图误差的方法 J]. 中国超声医学杂志, 2016, 32(7): 652-654.
[14]	杨祥睿, 王慧娟, 徐阳. 超声经颅多普勒血流分析仪校准方法探讨 J]. 计量与测试技术, 2019, 46(10): 43-44.
[15]	陈春芳, 唐翡, 谢荣鑫. 弦线式体模模拟血流速度测量方法探讨[J]. 计量与测试技术, 2020, 47(12): 36-38.
[16]	王琳, 董佳, 宋洁. 超声经颅多普勒血流分析仪校准方法探究[J]. 品牌与标准化, 2021(2): 58-59,62.
[17]	许祖茂, 赖康生, 王晓旭, 等. 不同固体表面下激光多普勒测速的数值模拟[J]. 光电子激光, 2005, 16(3): 323-327.
[18]	周健, 龙兴武. 差动激光多普勒测速仪在固体速度测量中的应用[J]. 应用光学, 2009, 30(2): 334-337.
[19]	王辉林, 王迎春. 双光束激光多普勒测速实验系统的不确定度分析[J]. 计量学报, 2013, 34(1): 31-35.
[20]	李文. 基于激光多普勒效应的测速系统研究及应用[D]. 南京: 南京理工大学, 2018.
[21]	Losev G, Kolesnichenko I. The influence of the waveguide on the quality of measurements with ultrasonic Doppler velocimetry[J]. Flow Measurement and Instrumentation, 2020, 1: 101786.
[22]	杨振立, 吴斌, 夏源. 基于激光多普勒原理的滚筒直径测量方法研究[J]. 中国计量, 2022(8): 84-86,149.
[23]	马路明. 双光束激光多普勒转速测量系统的实验验证[J]. 应用激光, 2023, 43(2): 116-119.
[24]	鲁伟俊, 彭希锋, 陈爽, 等. 激光多普勒测速仪示值误差检测方法研究[J]. 中国仪器仪表, 2023(11): 35-37.
[25]	杨荣岩, 赵洁, 王大勇, 等. 干涉角度显微测量提高光子相关法空气声声压测量精度研究[J]. 计量学报, 2022, 43(7): 927-933. doi: 10.3969/j.issn.1000-1158.2022.07.14
[26]	孙璟宇, 王中宇, 梁志国. 任意波形失真度的一种评价方法[J]. 北京航空航天大学学报, 2015, 41(1): 334-337.
[27]	李翔. 任意波形广义失真度研究[J]. 科技创新与应用, 2017(12): 54-56.
[28]	赵耀松, 霍凯, 陈志鸿. 交流电失真度测量方法研究与实现[J]. 电测与仪表, 2014, 51(19): 70-74.
[29]	梁志国, 孙璟宇, 孟晓风. 目标序列已知的周期波形总失真度的测量[J]. 计量学报, 2008, 29(2): 172-177.
[30]	梁志国, 孙瞡宇. 周期性任意波形总失真度的精确评价[J]. 计量学报, 2005(4): 176-180.