Deep learning-assisted locating and sizing of a coating delamination using ultrasonic guided waves.

• Proposed a deep learning-assisted delamination evaluation technique by using guided wave time–space images. • Showed that the developed neural network is capable of accurately predicting delamination locations and sizes. • Demonstrated that the proposed methodology is a baseline-free technique that evaluates the delamination without referring to the pristine condition. This article proposes a deep learning-assisted nondestructive evaluation (NDE) technique for locating and sizing a coating delamination using ultrasonic guided waves. The proposed technique consists of sending a propagating guided wave into a coated plate with a transducer and measuring the corresponding time-domain signals by receivers at several locations at downstream distances from the source transducer. The received time-domain signals are then provided to a trained machine-learning (ML) algorithm, which subsequently outputs the location and size of any delamination flaws between the transducer and receivers. Numerical simulations show that the proposed NDE technique yields accurate results with high throughput, once the ML algorithm is well trained. Although training the ML algorithm is time-consuming, this training only needs to be done once for a given sample configuration. The results of this article demonstrate that the proposed technique has great potential for characterizing delamination flaws in practical NDE and structural health monitoring (SHM) applications. [ABSTRACT FROM AUTHOR]