In　this　paper,　a　hybrid　numerical　technique　is　presented　for　modeling　a　photoconducting　antenna　structure　designed　for　optoelectronic　generation　of　millimeter　waves.　The　technique　interfaces　the　solid-state　device　model　with　the　three-dimensional　(3D)　finite-difference　time-domain　(FDTD)　method　to　achieve　the　active　antenna　modeling　effectiveness　and　efficiency.　The　FDTD　algorithm　is　applied　to　simulate　the　passive　part　of　the　antenna　structure,　whereas　the　numerical　device　simulation　is　employed　to　model　the　photoconductor　that　is　illuminated　by　lasers.　Physical　performance　of　the　photoconductor　and　response　of　the　antenna　are　analyzed.　Numerical　results　show　good　correlation　with　the　experimental　result　and　consequently　demonstrate　the　feasibility　of　the　full-wave　modeling.