Microwave time reversal for nondestructive testing of buried small damage in composite materials

Abstract

Composite materials are widely applied in aerospace, civil engineering, and sports equipment. Various damages produced during fabrication and long-term use can destroy its original mechanical properties, which brings safety and structural healthy concerns. Microwave imaging based on time reversal is one of the most promising nondestructive testing (NDT) methods for portable, low-cost, and accurate testing with the advantages of auto-focus and super-resolution. This paper applied microwave time reversal for the detection of buried small damage in composites backed by metal plates. Strong reflection from composite-metal interfaces brings challenges in successfully achieving time-reversal auto-focusing on small and weak-scattering damages in composites. Traditional target localization methods, including the entropy regularization method (ERM) and time-integrated energy method (TIEM), may result in the wrong localization of small damages. The main contribution of this paper is that the localization problem caused by the strong reflection from metal plates is revealed first, and the target initial reflection method (TIRM) from through-wall-radar imaging is introduced to solve it. The performance of three target localization methods is investigated, and the physical reasons for failure or successful localization are discussed in detail. Some performance influence factors, such as the arrangement of receivers or the total time step of received signals, are also discussed. Good performance for the detection of a single small damage with a weak scattered signal is achieved, and the performance for detecting multiple damages is studied. All time-reversal simulations are carried out based on the finite-difference time-domain (FDTD) method.