This thesis presents the researches for 60 GHz short range wireless system and millimeter-wave passive imaging applications. The high frequency effects in both designs need to be considered and observed through electromagnetic simulation. This thesis will focus on the design of CMOS circuits operating at high frequency and put the design considerations for passive components into discussion. The V-band low-noise active balun combines a low-noise amplifier and an active balun circuit, so the signal can be amplified and converted from single to differential at front-end. The proposed circuit calibrates the phase error of active balun through circuit structure and provides a robust calibration technique for millimeter-wave application. The chip is fabricated in 90 nm low power CMOS technology and occupies an active area of 0.275 mm2. The 3 dB bandwidth is from 60.4-66.6 GHz, the maximum equivalent voltage gain is 17.6 dB and the minimum noise figure is 8.6 dB. The power consumption is only 19 mW from a 1.4 V supply voltage. The measured phase error maintains less than 6.8˚ within 3 dB bandwidth and keeps below 10˚ within 50-67 GHz. The W-band power detector receives the signal from 75 GHz to 110 GHz and converts the power level into the change of DC voltage. The transistor of this work operates at linear region to improve the performance of noise-equivalent power. The chip is fabricated by 65 nm CMOS technology and the chip area is 0.163 mm2. The power consumption is 0.18 mW and the supply voltage is 1V. The measured input reflection coefficient is less than -10 dB within W-band frequency. The measured average responsivity is designed to achieve 1.77k while the measured NEP with average responsivity is about 17 pW/(Hz)^0.5.