An E band MMIC power amplifier design using 100 nm T-Gate GaN HEMT on SiC

The small signal modeling, design, fabrication, and measurement about monolithic millimeter-wave integrated circuit (MMIC) using gallium nitride (GaN) power amplifier (PA) on silicon carbide (SiC) working at the E band are proposed in this paper. The two stage PA used customized 4 x 75 mu m transistor with 100 nm T gate technology. The extraction and optimization of small signal model are based on single GaN high electron mobility transistor (HEMT)'s measurement. Balanced structure and new method are used by low impedance matching, which can simplify circuits prominently and benefit for die size reduction. Radial stub and LC stub are made the whole circuit in absolute stable status; the in-series DC block metal-insulator-metal capacitor from the matching circuit ensure the process is within small tolerances. From the 61-66 GHz bandwidth, a peak 10.7 dB small signal gain is obtained from the designed MMIC GaN PA, and also, the maximum output power can reach 29.7 to 30.4 dBm from 61 to 66 GHz, with an associated the peak drain efficiency of 18.8%. The final die size without dicing slot is 3.0 x 1.74 mm2. A novel E band power amplifier monolithic millimeter-wave integrated circuit (MMIC) using 100 nm T-Gate gallium nitride HEMT on silicon carbide is proposed in this paper. New matching, circuit stability, and small tolerances in process optimization methods are used for this MMIC, and finally, good measurement results verify the design.image