This paper consists of two parts. All the proposed circuits were implemented in TSMC 0.18μm mixed-signal/RF CMOS 1P6M technology. 　　Part I presents a Colpitts current-reused QVCO based on capacitor coupling. The proposed QVCO exists the advantages of Coltpitts and current-reused circuit. Furthermore, using capacitor coupling to generate quadrature signals doesn't make extra phase noise. According to the measured results, the oscillation frequency is 4.57~5.02 GHz, and the power consumption is about 8.46 mW at the supply voltage of 1.8 V. The phase noise at 1 MHz offset is -119 dBc/Hz and the figure-of-merit (FOM) of the proposed QVCO is about -183.7 dBc/Hz. 　　Part II proposes a high gain mixer with low noise amplifier (LNA) in the RF trans-conductance stage of mixer. Using the ability of LNA, this integrated mixer can achieve high conversion gain and low power consumption in one circuit. Furthermore, it reduces the area and avoids the problem of matching that many components integrate in SOC. In chapter 3, analyzing each block of mixer achieve high conversion gain and low noise figure. During measurement, the matching s-parameter is below -10 dB in 14~20 GHz. The measured bandwidth of conversion gain ranges from 12 to 16 GHz and the maximum gain is 18.3 dB at 14 GHz. The minimum noise figure is 13.2 dB. The measured linearity shows that IIP3 is -7.5 dB. The power consumption is 7.56 mW and the FOM is 191.42；In chapter 4, including the analytic method of chapter 3, constructing cascade construction by CCC CG-LNA and CS-LNA at the RF trans-conductance stage achieves high conversion gain and low noise figure in wide band. The measured s-parameter is below -8 dB in 4~20 GHz. The measured bandwidth of conversion gain covers from 2.7 to 17.8 GHz and the maximum gain is 22.7 dB at 4 GHz and 16 GHz. The minimum noise figure is 10.45 dB. The measured linearity shows that IIP3 is -10 dB. The power consumption is 12.058 mW and the FOM is 192.04。