Gürel, LeventOğuz, U.2015-07-282015-07-282003-030018-926Xhttp://hdl.handle.net/11693/11196The finite-difference time-domain method is applied to simulate three-dimensional subsurface-scattering problems, involving a ground-penetrating-radar (GPR) model consisting of two transmitters and a receiver. The receiving antenna is located in the middle of the twos identical transmitters, which are fed 180degrees out of phase. This configuration implies the existence of a symmetry plane in the middle of two transmitters and the cancellation of the direct signals coupled from the transmitters at the receiver location. The antenna polarizations and their separations are arbitrary. The transmitter-receiver-transmitter configured GPR model is optimized in terms of the scattered energy observed at the receiver by varying the antenna separation. Many simulation results are used to demonstrate the effects of the antenna separation and the optimal separation encountered for a specific target and GPR scenario.EnglishFinite-difference time-domain (FDTD) methodGround-penetrating radar (GPR)Perfectly matched layer (PML)Computer simulationProblem solvingReceiving antennasTransmittersSubsurface scatteringOptimization of the transmitter-receiver separation in the ground-penetrating radarArticle10.1109/TAP.2003.809873