A 35-mV supply ring oscillator consisting of stacked body bias inverters for extremely low-voltage LSIs
-
- Nishi Masaya
- Dept. of Electrical and Electronic Engineering, Kobe University
-
- Matsumoto Kaori
- Dept. of Electrical and Electronic Engineering, Kobe University
-
- Kuroki Nobutaka
- Dept. of Electrical and Electronic Engineering, Kobe University
-
- Numa Masahiro
- Dept. of Electrical and Electronic Engineering, Kobe University
-
- Sebe Hikaru
- Dept. of Electrical and Electronic Engineering, Osaka University
-
- Matsuzuka Ryo
- Dept. of Electrical and Electronic Engineering, Osaka University
-
- Maida Osamu
- Dept. of Electrical and Electronic Engineering, Osaka University
-
- Kanemoto Daisuke
- Dept. of Electrical and Electronic Engineering, Osaka University
-
- Hirose Tetsuya
- Dept. of Electrical and Electronic Engineering, Osaka University
Abstract
<p>This paper proposes a ring oscillator (ROSC) for extremely low-voltage LSI applications. The ROSC consists of dedicated low-voltage stacked body bias inverters (SBBIs) that are based on the conventional self-bias inverter (SBI) and stacked inverter (SI). The proposed SBBI employs the advantages of both SBI and SI to oscillate at extremely low supply voltage. The voltage gain of the proposed SBBI is improved by controlling main inverter’s supply (VDD and Gnd) and body-bias voltages, by using stacked and feedback inverters. The novelty of our proposed SBBI is in the combination of the conventional low-voltage circuit design techniques and its demonstration at extremely low supply voltage. Simulated and measured results in a 0.18-µm CMOS process with deep n-well option demonstrated that the proposed ROSC can operate at extremely low supply voltage of 35 mV and generate a clock with an 88% voltage swing from an input supply voltage of 50 mV. To the best of the authors’ knowledge, this is the lowest supply voltage CMOS ring oscillator ever reported.</p>
Journal
-
- IEICE Electronics Express
-
IEICE Electronics Express 18 (6), 20210065-20210065, 2021-03-25
The Institute of Electronics, Information and Communication Engineers
- Tweet
Details
-
- CRID
- 1390850412752289024
-
- NII Article ID
- 130008003169
-
- ISSN
- 13492543
-
- Text Lang
- en
-
- Data Source
-
- JaLC
- Crossref
- CiNii Articles
- KAKEN
-
- Abstract License Flag
- Disallowed