A widely used, free, and open-source FDTD software package developed at MIT. It supports Python scripting, advanced material modeling, and runs efficiently on Linux, macOS, and Windows.
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This paper presents a numerical FDTD study on the detection of cracks in concrete using ultrasonic waves. The authors propose a fixed-grid FDTD method to model the ultrasonic wave propagation and investigate the effects of crack size, shape, and location on the ultrasonic signal.