本論文第一個部分是分析探討在單石微波積體電路設計中所常用的薄膜電容在相同單位面積下改變佈局設計的高頻特性,以了解何種形式下的薄膜電容能夠達到最佳的共振頻率。論文中薄膜電容製作是利用半導體製程將其製作於砷化鎵基板上,並設計了十一種薄膜電容佈局形式且固定面積為100 × 100μm2。為了得到其精確的共振頻率及品質因素特性,在論文中介紹四種去嵌入法,藉由量測與模擬結果可知二階段開路/直通去嵌入法與探針墊/開路/直通去嵌入法較適用於薄膜電容。 而第二個部分則是探討藉由國家晶片中心(National Chip Implementation Center)所提供的玻璃基板整合式被動元件(Glasses Integrated Passive Device, GIPD)製程,透過覆晶封裝技術(Flip-Chip)將玻璃基板上的被動元件與台積電 0.18 μm CMOS製程所設計的驅動/功率級串疊式元件(Cascode MOSFET)晶片整合為一1.8 GHz差動Class-E 功率放大器。此電路架構的主要特色在於將被動元件製作在高絕緣度的玻璃基板上,藉此改善以往被動元件製作於矽基板上所造成的基板損失與以往打線(wire bonding)造成的寄生電感所產生的寄生效應,使得飽和功率(saturation power)與功率附加增益(power added efficiency)能有所提升。 The first part of this thesis is to study the high frequency performance of thin-film capacitor in different geometry with the same layout area and to investigate which capacitor can achieve the best self-resonant frequency for the monolithic microwave integrated circuit (MMIC) circuit design. The thin-film capacitors were fabricated on GaAs substrate by using semiconductor process. There are different layout styles, 11 types in total, were designed into an unit area of 100 × 100μm2. In order to obtain the precisely characteristics of self-resonant frequency and quality factor, the thin-film capacitors including RF pads were extracted by using de-embedding method. Four de-embedding method are introduced in the thesis. Based on the results from measurement and simulation, the de-embedding methods, 2-step/open/thru and the pad/open/thru, are suitable for the thin-film capacitance extraction. The second part presents a differential-type Class-E power amplifier for 1.8 GHz wireless application in which the amplifier was integrated by a chip having a driving and a power cascode MOSFETs designed by TSMC 0.18μm CMOS technology and the passive components based on Glasses Integrated Passive Device(GIPD) process. This circuit architecture not only avoids the parasitic inductors from bonding wire but also reduces the loss of the passive components on silicon substrate. Because of the improvement using GIPD technique, the saturation power and the power added efficiency therefore can be enhanced in power amplifier design.
