To　enhance　the　zero-voltage　switching　(ZVS)　range　and　power　density　of　the　phase-shift　full-bridge　(PSFB)　ZVS　converters　used　in　geophysical　exploration,　an　additional　resonant　inductor　is　used　as　a　leakage　inductance　and　a　blocking　capacitor　which　is　equivalent　to　interlayer　capacitance　is　integrated　into　a　novel　integrated　inductor-capacitor-transformer　(L-C-T).　The　leakage　inductance　and　equivalent　interlayer　capacitance　of　the　novel　integrated　L-C-T　are　difficult　to　determine　by　conventional　methods.　To　address　this　issue,　this　paper　presents　accurate　and　efficient　methods　to　compute　the　leakage　inductance　and　equivalent　interlayer　capacitance.　Moreover,　the　accuracy　of　this　methodology,　which　is　based　on　electromagnetic　energy　and　Lebedev＇s　method,　is　verified　by　an　experimental　analysis　and　a　finite　element　analysis　(FEA).　Taking　the　problems　of　the　novel　integrated　L-C-T　into　consideration,　the　losses　of　the　integrated　L-C-T　are　analyzed　and　the　temperature　rise　of　the　integrated　L-C-T　is　determined　by　FEA.　Finally,　a　PSFB　ZVS　converter　prototype　with　the　novel　integrated　L-C-T　is　designed　and　tested.