Substrate parasitics and dual-resistivity substrates [microwave integrated circuits]

Author

Lowther, Rex ; Begley, Patrick A. ; Bajor, George ; Rivoli, Anthony ; Eisenstadt, William R.

Author_Institution

Harris Semicond., Melbourne, FL, USA

Volume

44

Issue

7

fYear

1996

fDate

7/1/1996 12:00:00 AM

Firstpage

1170

Lastpage

1174

Abstract

In high-frequency semiconductor applications, substrate effects can be a dominant source of parasitics unless they are carefully minimized. Here a dual-resistivity substrate in a bonded-oxide process is considered for the optimization of the two major types of substrate parasitics: resistive substrate losses and capacitive coupling (crosstalk) through the substrate. These will both depend on the frequency, the two substrate resistivities, and the thickness of the two substrate layers. The thickness of the upper layer is treated as a fully designable parameter. The mechanisms are evaluated numerically, but intuitive rule-of-thumb arguments are also provided for a good understanding of the physics and of the tradeoffs in selecting an optimal design. The results of these sections may also serve as a guide for determining standard substrate resistivities

Keywords

MMIC; crosstalk; electrical conductivity; integrated circuit technology; losses; silicon-on-insulator; substrates; Si; bonded-oxide process; capacitive coupling; crosstalk; dual-resistivity substrates; high-frequency semiconductor applications; optimal design; resistive substrate losses; substrate effects; substrate parasitics; Conductivity; Costs; Gallium arsenide; Integrated circuit technology; Microwave frequencies; Microwave integrated circuits; Silicon; Skin; Substrates; Wafer bonding;

fLanguage

English

Journal_Title

Microwave Theory and Techniques, IEEE Transactions on

Publisher

ieee

ISSN

0018-9480

Type

jour

DOI

10.1109/22.508657

Filename

508657