Lexiu Xu, Yifang Li, Yuan Liu, Qinzhen Shi, Wenyu Xing, Tao Jiang, Gaobo Zhang, Ying Li, Dean Ta
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引用次数: 0
摘要
传统的超声骨成像模式通常需要先验知识或先进的声速(SoS)估计,这不仅造成成像过程繁琐,而且分辨率有限。为了克服这些缺点,本文提出了一种利用相控阵层析成像技术进行高精度皮质骨成像的频域全波形反转(FDFWI)模式。在频域中提出了超声波在二维空间中的传播情况,以模拟前向波场传播。反演过程中的迭代是通过将模拟波场与实验波场从低频点到高频点进行离散匹配。此外,还探讨了最大初始频率与初始 SoS 模型之间的关联,以防止出现周期跳跃现象,导致结果陷入局部极小值。模拟、模型和体外研究证明了拟议成像方案的可行性和有效性,皮质部分的平均相对误差分别为 3.18%、8.71% 和 9.36%。验证了所提出的 FDFWI 方法是在不预先了解声速的情况下对骨皮质进行参数成像的有效方法。
Full-Waveform Inversion Imaging of Cortical Bone Using Phased Array Tomography.
Classic ultrasound bone imaging modalities usually demand either a prior knowledge or an advanced estimation on speed of sound (SoS), which not only renders to a burdensome imaging process but also supplies a limited resolution. To overcome these drawbacks, this article proposed a frequency-domain full-waveform inversion (FDFWI) modality using phased array tomography for high-accuracy cortical bone imaging. A transmission scenario of ultrasound wave in 2-D space was presented in the frequency domain to simulate the forward wavefield propagation. Iterations in the inversion process were performed by matching the simulation wavefield to the experimental one from low to high discrete frequency points. Moreover, the association between the maximum initial frequency and the initial SoS model was explored to prevent the occurrence of cycle-skipping phenomenon, which could lead to the outcomes being trapped in local minima. The feasibility and effectiveness of the proposed imaging scheme were testified by simulation, phantom, and ex-vivo studies, with mean relative errors of cortical part being 3.18%, 8.71%, and 9.36%, respectively. It is verified that the proposed FDFWI method is an effective way for parametric imaging of cortical bone without any prior knowledge of sound speed.
期刊介绍:
IEEE Transactions on Biomedical Engineering contains basic and applied papers dealing with biomedical engineering. Papers range from engineering development in methods and techniques with biomedical applications to experimental and clinical investigations with engineering contributions.