A novel approach to design efficient high-output-power fundamental oscillators beyond f(max)/2 of the employed process is presented. The idea is to shape and maximize the unilateral power gain (U) of the network at the desired frequency using optimum passive internal and external feedback networks. The proposed technique significantly improves the output power and dc-to-RF efficiency of the oscillator. To show the feasibility of this novel approach, a 175 GHz fundamental oscillator is designed in a 130 nm SiGe BiCMOS process (f(max) similar or equal to 280 GHz), which achieves a measured dc-to-RF efficiency of 11.7% that is markedly higher than all reported oscillators above f(max)/3 of their active device. Measurements show that the designed oscillator generates a peak power of 3 mW (4.8 dBm) with a phase noise figure of merit (FoM) of -195.4 dBc/Hz at 1 MHz offset frequency, which is the highest phase noise FoM among all reported CMOS/BiCMOS millimeter-wave and terahertz oscillators. The proposed method considers the possible process, voltage, temperature variations as well as modeling errors of the passive components in the design stage.

• 出版日期2017-11