Extremely thin silicon on insulator p-channel metal-oxide-semiconductor field-effect transistors(PMOSFETs) with implanted doping and in situ doping are analyzed by TCAD simulation.The critical characteristic parameters acquired by TCAD simulation are compared with each other to analyze their electrical performance.The saturated driven currents of implanted doping devices with a 25 nm gate length(L_g) are about 200 μA/μm bigger than the in situ doping devices at the same saturated threshold voltage(V_(tsat)).Meanwhile the drain-induced barrier lowering(DIBL) and saturated subthreshold swings for implanted doping devices are also 30-50 mV/V and6.3-9.1 mV/dec smaller than those of in situ doping devices at 25 nm L_g and a 9-11 nm thickness of SOI(T_(si)),respectively.The shift of V_(tsat) with T_(si) for in situ doping devices with 15 nm L_g is-31.8 mV/nm,whereas that for in situ doping devices is only-6.8 mV/nm.These outcomes indicate that the devices with implanted doping can produce a more advanced and stable electrical performance. Extremely thin silicon on insulator p-channel metal-oxide-semiconductor field-effect transistors (PMOSFETs) with implanted doping and in situ doping are analyzed by TCAD simulation. The critical characteristic parameters acquired by TCAD simulation are compared with each other to analyze their electrical performance. The saturated driven currents of implanted doping devices with a 25 nm gate length (L_g) are about 200 μA / μm larger than the in situ doping devices at the same saturated threshold voltage (V_ (ts)). barrier lowering (DIBL) and saturated subthreshold swings for implanted doping devices are also 30-50 mV / V and 6.3-9.1 mV / dec smaller than those of in situ doping devices at 25 nm L_g and a 9-11 nm thickness of SOI (T_ (si)), respectively. The shift of V_ (tsat) with T_ (si) for in situ doping devices with 15 nm L_g is -31.8 mV / nm, then that for in situ doping devices is only-6.8 mV / nm. the results of the devices that implanted doping can produce a more advanced and stable electrical performance.