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

基于时频分布的盲信号分离方法研究长骨中的多模式导波信号 被引量:16

Study on the multiple guided waves in long bones using spatial time-frequency based blind source separation method
原文传递
导出
摘要 由于超声导波对长骨皮质骨的材料特性及厚度变化非常敏感,因此用导波评价长骨状况的研究已成为近年来的一个研究热点。在接收到的导波中,往往多种模式混叠在一起,使得进一步求取每种导波模式的群速度等与骨质状况密切相关的参数时遇到困难。本文采用基于时频分布的盲信号分离(TFBSS)方法对长骨中混叠的多模式进行分离,然后对分离后的单一导波模式求取群速度。研究结果表明TFBSS方法能够准确的分离出混叠的多模式导波,且实验测量的群速度与其理论值吻合。利用导波的群速度就可以得到长骨皮质骨的厚度,这对诊断其骨质状况具有重要意义。 Ultrasonic guided waves are very sensitive to the material's characteristics and the change of the cortical thickness in long bones.Therefore,it has been a great interest of using guided waves to assess long bones.However,it's a challenge to acquire the group velocity and other parameters from the long bone because of the mixed multiple modes in the received signals.In the study,the spatial time-frequency based blind source separation(TFBSS)method was employed to separate the mixed signals and then calculate the group velocities of each single mode.The result showed that the TFBSS method can separate the mixed signals correctly,and the experimental measured group velocities are agreed with theory values very well.The cortical thickness could be acquired based on the group velocities,which is quite significant to assess the properties of long bones.
作者 宋小军 他得安 王威琪
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 2011年第3期318-324,共7页 Acta Acustica
基金 国家自然科学基金(10774029 30870720) 教育部博士点基金(20090071110066)资助项目
关键词 盲信号分离 超声导波 分离方法 时频分布 多模式 长骨 模式混叠 厚度变化 Bone Guided electromagnetic wave propagation Light velocity
分类号 R318.0 [医药卫生—生物医学工程]
  • 相关文献

参考文献18

  • 1Reginster J Y, Burlet N. Osteoporosis: A still increasing prevalence. Bone, 2006; 38:S4--S9.
  • 2Blake G M, Fogelman I. Review--DXA scanning and its interpretation in osteoporosis. Hosp Med, 2003; 64: 521-- 525.
  • 3Petro Moilanen. Ultrasonic guided waves in bone. IEEE Trans. UFFC, 2008; 55(6): 1277--1286.
  • 4TA De'an, WANG Weiqi, WANG Yuanyuan et al. Measurement of the dispersion and attenuation of cylindrical ultrasonic guided waves in long bone. Ultrasound in Med. & Biol., 2009; 35(4): 641 -652.
  • 5Yamato Y, Matsukawa M, Yanagitani T. Distribution of hydroxyapatite crystallit orientation and ultrasonic wave velocity in ring-shaped cortical bone of bovine femur. IEEE Trans. UFFC, 2008; 55(6): 1298--1302.
  • 6TA De'an, HUANG Kai, WANG Weiqi et al. Identification and analysis of multimode guided waves in tibia cortical bone. Ultrasonics, 2006; 44:e279 -284.
  • 7他得安,王威琪,汪源源.超声轴向传播技术评价长骨的研究[J].应用声学,2009,28(3):161-165. 被引量:5
  • 8许凯亮,他得安,王威琪.骨折长骨中超声导波传播特性的仿真研究[J].声学学报,2009,34(5):423-429. 被引量:16
  • 9Moilanen P, Nicholson P H F, Kilappa V ef al. Measuring guided waves in long bones- Modeling and experiments in free and immersed plates. Ulfrasound in Med. & Biol., 2006; 32(5): 709--719.
  • 10Nicholson P H F, Moilanen P, Karklminen T et al. Guided ultrasonic waves in long bones: modeling, experiment and in vivo application. Phys measu, 2002; 23:755--768.

二级参考文献64

  • 1Bossy E, Talmant M, .Defontaine M, et al. Bidirectional axial transmission can improve accuracy and precision of ultrasonic velocity measurement in cortical bone- a validation on test materials. IEEE Tran on UFFC, 2004, 51(1): 71-79.
  • 2Moilanen P, Kilappa V, Nicholson PHF. Thickness sensitivity of ultrasound velocity in long bone phantoms. Ultrasound in Med & Biol, 2004, 30(11) 1517-1521.
  • 3Bossy E, Akrout L, Cloetens P, et al. An in vitro study of the ultrasonic axial transmission technique at the radius: 1-MHz velocity measurements are sensitive to both mineralization and intracortical porosity. J Bone Miner Res, 2004, 19(9): 1548-1556.
  • 4Nicholson PHF, Moilanen P, Karkkainen T, et al. Guided ultrasonic waves in long bones: modelling, experiment and in vivo application. Physiol Meas, 2002, 23:755-768.
  • 5Muller M, Moilanen P, Bossy E, et al. Comparison of three ultrasonic axial transmission methods for bone assessment. Ultrasound in Med & Biol, 2005, 31(5): 633-642.
  • 6Bensarnoun S, Gherbezza JM, Belleval JF, et al. Transmission scanning acoustic imaging of human cortical bone and relation with the microstructure. Clinical Biomechanics, 2004, 19: 639-647.
  • 7Bossy E, Talmant M, Laugier P. Three-dimensional simulations of ultrasonic axial transmission velocity measurement on cortical bone models. J Acoust Soc Am, 2004, 115(5): 2314-2324.
  • 8Nicholson PHF, Chcng S, Karkkaincn T. Measurement of guided ultrasonic waves in the human tibia and radius. J Acoust Soc Am, 2001, 110(5): 2622.
  • 9Moilanen P, Nieholson PHF, Karkkainen T, et al. Assessment of the tibia using ultrasonic guided waves in pubertal girls. Osteoporosis Int, 2003, 14(12): 1020-1027.
  • 10Moilanen P, Nicholson PHF, Kilappa V, et al. Assessment of the cortical bone thickness using ultrasonic guided waves: Modelling and in vitro study. Ultrasound in Med& Biol 2007, 33(2): 254-262.

共引文献24

同被引文献101

引证文献16

二级引证文献62

声学学报
2011年 第3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