High quality RF devices for 60GHz systems are required because RF device imperfections cause serious problems in these systems, such as carrier frequency offset, I/Q imbalance and phase noise. This thesis proposes a dual mode low complexity phase noise cancellation algorithm and its hardware design for wide bandwidth phase noise cancellation. This algorithm supports both orthogonal frequency division multiplexing (OFDM) mode and single carrier (SC) mode. It achieves the specifications of the IEEE 802.15.3c standard. Most importantly, its low complexity makes it possible to be implemented at baseband receivers. The dual mode algorithm consists of a hybrid domain phase noise cancellation algorithm for OFDM mode and a two-stage phase noise cancellation algorithm for SC mode. In OFDM mode, the hybrid domain phase noise cancellation algorithm comprises a frequency domain algorithm for common phase error (CPE) cancellation and a time domain algorithm for inter-carrier interference (ICI) cancellation. The hardware of the time domain algorithm has about the same size as the hardware of the frequency domain algorithm. 99.8% of the hardware of the two-stage phase noise cancellation algorithm for SC mode can be shared with the frequency domain algorithm for HSI mode. A 65nm CMOS process is applied. Excluding the shared memory and the shared FFT blocks, the gate count of the frequency domain algorithm is 115K and the gate count of the time domain algorithm is 119K when the timing constraint used for the synthesis is 1.5ns. Consider the situation that QPSK is applied and the SNR equals 12dB. For HSI mode, when the bandwidth of phase noise is 12.5MHz and the RMS of phase noise is 15 degrees, the BER of the system is 3.3×10^-4. For SC mode, when the bandwidth of phase noise is 12.5MHz and the RMS of phase noise is 8 degrees, the BER of the system is 8.91×10^-4.