Title :
Ray Tracing for Simulation of Millimeter-Wave Whole Body Imaging Systems
Author :
Williams, Kathryn ; Tirado, Luis ; Zhongliang Chen ; Gonzalez-Valdes, Borja ; Martinez, Jose Angel ; Rappaport, Carey M.
Author_Institution :
ALERT CenSSIS Center, Northeastern Univ., Boston, MA, USA
Abstract :
A ray tracing algorithm for modeling millimeter waves in a whole body imaging system is presented. Ray tracing is a well-known method for approximating high-frequency wave behavior and is well suited for implementation on graphics processing units (GPUs), presenting computational speed advantages over conventional full-wave modeling techniques. This method leverages the NVIDIA OptiX engine to ensure computational efficiency. Numerical results in this work are compared with conventional two-dimensional method of moments solutions to assess accuracy and computational times are compared with a three-dimensional GPU implementation of the modified equivalent current approximation.
Keywords :
approximation theory; graphics processing units; millimetre wave imaging; ray tracing; NVIDIA OptiX engine; graphics processing units; high-frequency wave behavior; millimeter-wave whole body imaging systems; modified equivalent current approximation; ray tracing algorithm; Computational modeling; Image reconstruction; Imaging; Method of moments; Millimeter wave technology; Ray tracing; Receivers; Human body imaging; NVIDIA OptiX Engine; NVIDIA® OptiXTM Engine; millimeter wave; ray tracing;
Journal_Title :
Antennas and Propagation, IEEE Transactions on
DOI :
10.1109/TAP.2015.2486801
