时域有限差分法
振幅
声学
有限差分法
谐波
非线性系统
机械
声压
有限差分
材料科学
失真(音乐)
脉搏(音乐)
热声学
吸收(声学)
非线性声学
声波
物理
计算物理学
光学
数学
数学分析
热力学
放大器
电压
探测器
量子力学
光电子学
CMOS芯片
作者
Ibrahim M. Hallaj,Robin O. Cleveland
摘要
Full wave simulations provide a valuable tool for studying the spatial and temporal nature of an acoustic field. One method for producing such simulations is the finite-difference time-domain (FDTD) method. This method uses discrete differences to approximate derivatives in the governing partial differential equations. We used the FDTD method to model the propagation of finite-amplitude sound in a homogeneous thermoviscous fluid. The calculated acoustic pressure field was then used to compute the transient temperature rise in the fluid; the heating results from absorption of acoustic energy by the fluid. As an example, the transient temperature field was calculated in biological tissue in response to a pulse of focused ultrasound. Enhanced heating of the tissue from finite-amplitude effects was observed. The excess heating was attributed to the nonlinear generation of higher-frequency harmonics which are absorbed more readily than the fundamental. The effect of nonlinear distortion on temperature rise in tissue was observed to range from negligible at 1 MPa source pressure to an 80% increase in temperature elevation at 10 MPa source pressure.
科研通智能强力驱动
Strongly Powered by AbleSci AI