Wear Keith A
Center for Devices and Radiological Health, U.S. Food and Drug Administration, Bldg. 62, Room 3108, 10903 New Hampshire Boulevard, Silver Spring, Maryland 20993.
J Acoust Soc Am. 2014 Apr;135(4):2102-12. doi: 10.1121/1.4868473.
In through-transmission interrogation of cancellous bone, two longitudinal pulses ("fast" and "slow" waves) may be generated. Fast and slow wave properties convey information about material and micro-architectural characteristics of bone. However, these properties can be difficult to assess when fast and slow wave pulses overlap in time and frequency domains. In this paper, two methods are applied to decompose signals into fast and slow waves: bandlimited deconvolution and modified least-squares Prony's method with curve-fitting (MLSP + CF). The methods were tested in plastic and Zerdine(®) samples that provided fast and slow wave velocities commensurate with velocities for cancellous bone. Phase velocity estimates were accurate to within 6 m/s (0.4%) (slow wave with both methods and fast wave with MLSP + CF) and 26 m/s (1.2%) (fast wave with bandlimited deconvolution). Midband signal loss estimates were accurate to within 0.2 dB (1.7%) (fast wave with both methods), and 1.0 dB (3.7%) (slow wave with both methods). Similar accuracies were found for simulations based on fast and slow wave parameter values published for cancellous bone. These methods provide sufficient accuracy and precision for many applications in cancellous bone such that experimental error is likely to be a greater limiting factor than estimation error.
在对松质骨进行穿透传输检测时,可能会产生两个纵向脉冲(“快”波和“慢”波)。快波和慢波特性传达了有关骨材料和微观结构特征的信息。然而,当快波和慢波脉冲在时域和频域重叠时,这些特性可能难以评估。本文应用两种方法将信号分解为快波和慢波:带限反卷积和带曲线拟合的改进最小二乘 Prony 方法(MLSP + CF)。这些方法在塑料和 Zerdine(®) 样本中进行了测试,这些样本提供的快波和慢波速度与松质骨的速度相当。相速度估计的精度在 6 m/s(0.4%)以内(两种方法的慢波以及 MLSP + CF 的快波)和 26 m/s(1.2%)以内(带限反卷积的快波)。中频信号损失估计的精度在 0.2 dB(1.7%)以内(两种方法的快波)和 1.0 dB(3.7%)以内(两种方法的慢波)。基于已发表的松质骨快波和慢波参数值进行的模拟也发现了类似的精度。这些方法为松质骨的许多应用提供了足够的准确性和精度,以至于实验误差可能比估计误差更是一个更大的限制因素。