DocumentCode
1173991
Title
Independently driven DG MOSFETs for mixed-signal circuits: part I-quasi-static and nonquasi-static channel coupling
Author
Pei, Gen ; Kan, Edwin Chih-Chuan
Author_Institution
Sch. of Electr. & Comput. Eng., Cornell Univ., Ithaca, NY, USA
Volume
51
Issue
12
fYear
2004
Firstpage
2086
Lastpage
2093
Abstract
The two tightly coupled channels in independently driven double-gate (IDDG) MOSFET offer new opportunities in constructing mixed-signal circuit modules. Understanding of channel coupling in various bias and frequency regimes is imperative to conceptualize the circuit design and optimization. In Part I, we will investigate both quasi-static and nonquasi-static channel coupling in IDDG through capacitance simulation. The charge reshuffling between channels provides effective coupling at high frequency when source/drain (S/D) carriers cannot respond spontaneously to the applied gate signals, which opens up new high-frequency circuit possibilities beyond the S/D transit time set by the lithography limit. The bias and frequency regions that enhance channel coupling are identified. The transition frequency related to channel charge reshuffling is investigated for its dependence on device geometry. Operational principles and practical limitations are discussed. In Part II, we will present the circuit design examples based on the interchannel coupling.
Keywords
MOSFET; circuit simulation; mixed analogue-digital integrated circuits; bias region; capacitance network; capacitance simulation; channel charge reshuffling; circuit optimization; frequency region; independently driven double-gate MOSFET; mixed-signal circuit module; nonquasistatic channel coupling; nonquasistatic modeling; quasistatic channel coupling; source-drain carriers; Circuit simulation; Circuit synthesis; Coupling circuits; Frequency; Geometry; MOSFETs; Parasitic capacitance; Semiconductor device modeling; Solid modeling; Space technology; 65; Capacitance network; DG; MOSFET; channel coupling; double-gate; mixed-signal circuits; nonquasi-static modeling; quasi-static modeling;
fLanguage
English
Journal_Title
Electron Devices, IEEE Transactions on
Publisher
ieee
ISSN
0018-9383
Type
jour
DOI
10.1109/TED.2004.838338
Filename
1362972
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