Numerical methods to solve the time-dependent wave equation, applicable to a variety of electromagnetic and acoustic problems, generally require some technique to reduce an infinite physical domain to a finite computational domain, yet preserve the outgoing radiation property (Sommerfeld radiation condition). The task of incorporating this well-known physical constraint into an effective computational procedure has been widely studied, but existing approaches do not achieve good accuracy. In many time-domain computational models, spurious reflections from the computational boundary comprise the largest source of error in the model.
A variety of wave problems occurring at NIST are amenable to modeling using time-domain methods. These include determination of material dielectric constants using resonance cavities, calibration of electromagnetic probes, characterization of microwave and optical transmission lines, and characterization of material defects by acoustic emissions. For each of these problems, model inaccuracy is an important issue limiting the acceptance of numerical methods.
The goal of this collaboration is the creation of an accurate and efficient numerical algorithm for nonreflecting boundary conditions. The researchers are employing an integral operator formulation of the correct boundary conditions to construct a numerical procedure. Their initial results include a new quadrature technique for integral operators. This work has received outside funding through DARPA.