Title :
Parasitic modeling and noise mitigation in advanced RF/mixed-signal silicon germanium processes
Author :
Singh, Raminderpal ; Tretiakov, Youri V. ; Johnson, Jeffrey B. ; Sweeney, Susan L. ; Barry, Robert L. ; Kumar, Mukesh ; Erturk, Mete ; Katzenstein, John ; Dickey, Carl E. ; Harame, David L.
Author_Institution :
IBM, Essex Junction, VT, USA
fDate :
3/1/2003 12:00:00 AM
Abstract :
The potential for highly integrated radio frequency (RF) and mixed-signal (AMS) designs is today very real with the availability cost-effective scaled silicon-germanium (SiGe) process technologies. However, the lack of effective parasitic modeling and noise mitigation significantly restrict opportunities for integration, due to a lack of computer-aided design solutions and practical guidance for designers. This tutorial paper provides a broad in-depth coverage of the key technical areas that designers need to understand in estimating and mitigating IC parasitic effects. A detailed analysis of the parasitic effects in passive devices, the interconnect (including transmission line modeling) and substrate impedance, and isolation estimation is presented-referencing a large number of key publications in these areas.
Keywords :
Ge-Si alloys; electronic engineering computing; integrated circuit interconnections; integrated circuit modelling; integrated circuit noise; mixed analogue-digital integrated circuits; radiofrequency integrated circuits; semiconductor materials; technology CAD (electronics); transmission line theory; IC parasitic effects; RFIC design; SiGe; TCAD development; advanced SiGe RF/mixed-signal processes; highly integrated RF/mixed-signal designs; interconnect modeling; isolation estimation; noise mitigation; parasitic modeling; passive devices; scaled SiGe process technologies; substrate impedance; technology CAD; transmission line modeling; Crosstalk; Design automation; Germanium silicon alloys; Inductors; Integrated circuit modeling; Integrated circuit noise; Radio frequency; Radiofrequency integrated circuits; Semiconductor device noise; Silicon germanium;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2003.810469
