期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

Barker码激励超声导波在长骨检测中的应用 被引量:12

Application of Barker code excited ultrasonic guided waves to long bone detection
原文传递
导出
摘要 单脉冲激励的超声导波在长骨中传播时,信号的衰减大,导致接收信号的幅度很小,且噪声严重。Barker码激励能有效增大接收信号幅度,提高信噪比(SNR)。将其应用到超声导波长骨检测中,进行仿真和长骨实验,得到的信号分别用加权匹配滤波器和有限冲激响应-最小均方误差(FIR-LS)逆滤波器进行压缩,并与单脉冲激励的结果进行了对比。结果表明,对于13位的Barker码,采用加权匹配滤波器进行解码时,压缩信号幅度是单脉冲激励接收信号的13倍;而FIR-LS逆滤波器则达到-63.59 dB的峰值旁瓣水平(PSL),更好地抑制噪声。说明可以将Barker码激励超声导波应用于长骨的检测中。 Single pulse excited ultrasonic guided waves suffer high attenuation during the propagation in long bones. This results in small amplitude and low signal-to-noise ratio (SNR) of measured waveform. Barker code excitation is introduced into long bone detection, because of its efficiency in increasing amplitude and SNR of received signals. Both simulation and long bone experiment had been done, and the results were compressed by weighted match filter and finite impulse response - least squares (FIR-LS) inverse filter, respectively. The comparison between the results of Barker code excitation and single pulse excitation was presented. For 13 bits Barker code excitation, weighted match filter produced 13 times larger amplitude than single pulse excitation, while FIR-LS inverse filter achieved higher peak-sidelobe-level (PSL) of -63.59 dB and performed better in noise suppression. The results show that the Barker code excited ultrasonic guided waves have the potential to be applied to the long bone detection.
作者 张慧琳 宋小军 他得安
机构地区 复旦大学电子工程系
出处 《声学学报》 EI CSCD 北大核心 2014年第2期257-263,共7页 Acta Acustica
基金 国家自然科学基金(11174060 11327405) 上海市科技支撑计划(13441901900) 教育部博士点基金(20110071130004 20130071110020)资助
关键词 超声导波 码激励 长骨 应用 检测 Barker码 接收信号 匹配滤波器 Bone Impulse response Ultrasonic waves
分类号 TN911.7 [电子电信—通信与信息系统]
  • 相关文献

参考文献4

二级参考文献66

  • 1他得安 王威琪 汪源源.相位谱法研究长骨中超声导波的频散[J].仪器仪表学报,2007,28(8):139-142.
  • 2Laugier P, Wear K A, Waters K R. Introduction to the special issue on diagnostic and therapeutic applications of ultrasound in bone-part I. IEEE Trans. on UFFC, 2008; 55(6): 1177--1178.
  • 3Laugier P, Wear K A, Waters K R. Introduction to the special issue on diagnostic and therapeutic applications of ultrasound in bone-part II. IEEE Trans. on UFFC, 2008; 55(7): 1415--1416.
  • 4Moilanen P. Ultrasonic guided waves in bone. IEEE Trans. on UFFC, 2008; 55(6): 1277--1286.
  • 5TA De'an, HUANG Kai, WANG Weiqi et al. Identification and analysis of multimode guided waves in tibia cortical bone. Ultrasonics, 2006; 44(51): e279--284.
  • 6Protopappas V C, Fotiadis D I, Malizos K N. Guided ultrasound wave propagation in intact and healing long bones. Ultrasound in Med.& Biol., 2006; 32(5): 693--708.
  • 7Moilanen P, Nicholson P H F, Kilappa V, Cheng S, Timonen J. Assessment of the cortical bone thickness using ultrasonic guided waves: Modelling and in vitro study. Ultrasound in Med. &Biol., 2007; 33(2): 254--262.
  • 8Moilanen P, Nicholson P H F, Kilappa V et al. Measuring guided waves in long bones- Modeling and experiments in free and immersed plates. Ultrasound in Med.& Biol., 2006; 32(5): 709--719.
  • 9Moilanen P, Kilappa V, Nicholson P H F. Thickness sensitivity of ultrasound velocity in long bone phantoms. Ultrasound in Med. & Biol., 2004; 30(11): 1517--1521.
  • 10Bossy E, Talmant M, Defontaine Met al. Bidirectional axial transmission can improve accuracy and precision of ultrasonic velocity measurement in cortical bone- a validation on test materials. IEEE Trans. on UFFC, 2004; 51(1): 71--79.

共引文献38

同被引文献114

引证文献12

二级引证文献53

声学学报
2014年 第2期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部