Abstract
Ultrasonic Lamb wave testing has been successfully applied in nondestructive testing. However, because of Lamb wave multimodal and dispersion characteristics, the received signals are often multimodal and overlapping, which makes them very complicated. This paper proposes a mode separation method by combining dispersion compensation with the independent component analysis of fourth-order cumulant. Taking two-mode overlapped signals as an example, the single-mode dispersion compensation is performed according to the measured distance difference between the two sets of signals. The two sets of signals are returned to the same distance. The fourth-order cumulant independent component analysis method is further used to process the Lamb wave signals of different superposition situations at the same distance. The corresponding mode signal contained in the two sets of signals is separated through the joint diagonalization of the whitened fourth-order cumulant matrix. The different modes are compensated and separated successively, achieving the multimodal signal separation. Experimental results in steel plates show that the presented method can accurately achieve mode separation for the multimodal overlapping Lamb waves. This is helpful for the signal processing of multimodal Lamb waves.
Highlights
The ultrasonic Lamb wave technique has been successfully applied in the nondestructive testing (NDT) of plates
Lamb wave signals have different modes for any given plate thickness and excitation frequency, and the dispersion of each mode is different; that is, different frequency components of a specific propagation mode propagate at different speeds, which leads to the signal stretching in time and reducing the spatial resolution [5]
In order to separate multimodal overlapped Lamb waves effectively, this paper proposes a mode separation method by means of the combination of dispersion compensation with independent component analysis (ICA) [18] of fourth-order cumulant
Summary
The ultrasonic Lamb wave technique has been successfully applied in the nondestructive testing (NDT) of plates. Lamb wave signals have different modes for any given plate thickness and excitation frequency, and the dispersion of each mode is different; that is, different frequency components of a specific propagation mode propagate at different speeds, which leads to the signal stretching in time and reducing the spatial resolution [5]. It can be seen from the dispersion characteristics that the phase velocities of some modes are very close under certain excitation conditions. Lamb wave signals are often overlapped in both time and frequency domains, and signal interpretations are often difficult
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