With the rapid development of the wireless communication technologies, radio frequency integrated circuit tends to higher frequency, higher data rate, wider bandwidth and higher integration. Unlicensed multi-GHz bandwidth around 60GHz makes very high data rate transmission feasible. The low noise amplifier (LNA) is one of the most important components in the 60GHz front-end transceiver. The low noise amplifier contributes to minimum noise figure when amplifying the weak signal from the antenna. We adopt CMOS technology. It has the advantages of small size, low cost, low power consumption, and high level of integration, all of which are attractive for MMW applications. In this thesis, tow CMOS low noise amplifiers were designed for V band specifications. They are fabricated in TSMC 90nm RF CMOS process. The first chip, we present a V-band 3-stage LNA that the first and second stages utilizes the common source topology for reduce noise figure and The third stage is adopted cascode topology to boost gain. Therefore our LNA achieves excellent noise figure of 5.4dB at 55.5GHz, with miniature chip size of 0.46 mm2 including testing pads. The maximum gain is 13.1dB at 56.6GHz. The second chip, employs a 2-stage cascode topology. Compared with conventional cascode device design, the cascode device design we proposed has improved stability, lowered noise figure, contributed to higher gain and consumed lower power. The 2-stage LNA, which achieves a peak gain of 18.95dB at 56.9GHz, a noise figure of 4.7dB at 65.5GHz, a 3dB frequency bandwidth ranging from 54.7 to 63.1 GHz, an input 1dB compression point of -20dBm at 60GHz. Also the LNA consumes only 15.3mW. The total LNA die area with pads is 0.308 mm2.