A power amplifier (PA) is the most power-hungry circuit block in a RF frontend. Increasing its efficiency of transferring the DC power to RF power is therefore eminent when it comes to reducing the DC power consumption of RF systems. This thesis discusses two efficiency-enhancing techniques, namely, tunable load and area resizing. The techniques are applied to and verified by two CMOS PA designs. Based on tunable-load and area-resizing techniques, two switchable PAs operating at 2.535 GHz are designed and implemented in TSMC 0.18-μm CMOS technology. The first PA can be switched between two states; each state has a different transistor size and corresponds to a different load impedance. At 3.3-V supply voltage, the P1dB and the corresponding PAE are 23.1 dBm and 31.2%, respectively. By resizing the area and switching the load impedance, the DC power consumption of the PA can be reduced by more than 40% as the power is backed off by 3 dB or more. The second PA has 8 area-resizing states and its load impedance can be switched between two different values. In addition, it contains a bypass-capacitor-sharing design that suits area-resizing with multiple controls. Simulation results show, at 3.3-V supply, the P1dB and the corresponding PAE are 21.2 dBm and 30.6%, respectively. The DC power consumption is reduced by 40% at 3-dB power back-off. It is successfully demonstrated that, combining area resizing and tunable load techniques, the DC power consumption of PAs at low-power region can be effectively reduced and the power efficiency can be significantly enhanced.