本論文研製毫米波GIPD射頻晶片嵌入式天線，包含94-GHz GIPD 對數週期偶極子陣列為源振子(driving element)之準八木天線(Yagi Antenna)、帶通濾波平面倒F型天線、整合對數週期偶極子陣列與Balun帶通濾波器之毫米波晶片、以及60-GHz 整合CMOS功率放大器之GIPD對稱雙埠韋瓦第單極子天線射頻晶片。94-GHz GIPD 對數週期偶極子陣列之準八木天線將偶極子陣列作為源振子，並在前、後端加入引向器(director)及反射器(reflector); 94-GHz GIPD 帶通濾波平面倒F型天線，結合λ/4耦合線共振器與天線之等效電路模型，使其近似二階帶通濾波器，天線功率增益於頻率分佈上具有帶通濾波響應; 94-GHz GIPD對數週期偶極子陣列與Balun帶通濾波器之整合晶片，結合毫米波接收機前端三種被動元件(天線、平衡器、帶通濾波器)；60-GHz 整合CMOS功率放大器的GIPD對稱雙埠韋瓦第單極子天線晶片利用flip-chip技術整合GIPD與CMOS製程，結合功率放大器與晶片天線。晶片饋入系統皆以共面波導方式設計，天線架構皆以平面方式實現，使用3D有限元素法分析，晶片量測採用on-wafer方式進行。

This thesis presents the research of millimeter-wave (MMW) GIPD on-chip antennas. The designed GIPD MMW on-chip antennas are fabricated with AFSC general integrated passive device (GIPD) process. The three-dimensional finite element method (3D FEM) is used to design and analysis. The designed MMW on-chip antennas including: (1) 94-GHz GIPD quasi-Yagi antenna with log-periodic dipole array as driver; (2) 94-GHz GIPD bandpass-filtering planar inverted-F antenna; (3) 94-GHz GIPD on-chip log-periodic dipole array antenna with integrated balun-bandpass filter; (4) 60-GHz GIPD symmetrical two-port Vivaldi monopole antenna with integrated CMOS power amplifier. The measured performances of the designed on-chip antennas are all conducted by the on-wafer measurement setup.

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