A hybrid method for scattering by large bodies with cracks and gaps

A hybrid method that combines the finite-element method ( ) ( ) FEM and the shooting-and-bouncing-ray SBR method is presented to compute scattering by large bodies with small protruding scatterers. In the method, the field equi¨alence principle is employed to replace the protruding scatterers by a s

We consider the scattering of time‐harmonic acoustic plane waves by a crack buried in a piecewise homogeneous medium. The integral representation for a solution is obtained in the form of potentials by using Green's formula. The density in potentials satisfies the uniquely solvable Fredholm integral

## Abstract In this article, a hybrid method of adaptively modified characteristic basis function method (AMCBFM) and QR factorization with a dual modified Gram‐Schmidt (Dual‐MGS) algorithm, which is called QR‐AMCBFM, is presented. The first step is to derive the primary basis functions by using AM

Figure 6 Nonlinearity of PZT Figure 7 Hysteresis of PZT actuator which was controlled by a DrA converter. Many experiments have been done to test the PZT. A typical sample PZT is made of 30 pieces, and its radius is 10 mm. The curves of nonlinearity and hysteresis are shown in Figures 6 and 7. Its n

Frequency-domain plane-wa¨e scattering from a perfectly conducting two-dimensional cylinder is analyzed by a hybrid formulation ( ) combining the method of moments MoM and physical optics. Asymptotic techniques are employed to e¨aluate many of the impedance matrix integrals. Comparisons are made wit