A 0.2 V, 480 kb Subthreshold SRAM With 1 k Cells Per Bitline for Ultra-Low-Voltage Computing

Author

Kim, Tae-Hyoung ; Liu, Jason ; Keane, John ; Kim, Chris H.

Author_Institution

Univ. of Minnesota, Minneapolis

Volume

43

Issue

2

fYear

2008

Firstpage

518

Lastpage

529

Abstract

A 2 muW, 100 kHz, 480 kb subthreshold SRAM operating at 0.2 V is demonstrated in a 130 nm CMOS process. A 10-T SRAM cell allows 1 k cells per bitline by eliminating the data-dependent bitline leakage. A virtual ground replica scheme is proposed for logic "0" level tracking and optimal sensing margin in read buffers. Utilizing the strong reverse short channel effect in the subthreshold region improves cell writability and row decoder performance due to the increased current drivability at a longer channel length. The sizing method leads to an equivalent write wordline voltage boost of 70 mV and a delay improvement of 28% in the row decoder compared to the conventional sizing scheme at 0.2 V. A bitline writeback scheme was used to eliminate the pseudo-write problem in unselected columns.

Keywords

CMOS memory circuits; SRAM chips; low-power electronics; 10-T SRAM cell; CMOS memory circuits; bitline leakage; frequency 100 kHz; power 2 muW; read buffers; reverse short channel effect; size 130 nm; storage capacity 480 Kbit; subthreshold SRAM chips; ultra-low-voltage computing; voltage 0.2 V; voltage 70 mV; voltage scaling; CMOS logic circuits; CMOS process; Decoding; Delay; Energy consumption; Logic circuits; MOSFETs; Random access memory; Robustness; Voltage; Low-voltage memory; reverse short channel effect; subthreshold SRAM; voltage scaling;

fLanguage

English

Journal_Title

Solid-State Circuits, IEEE Journal of

Publisher

ieee

ISSN

0018-9200

Type

jour

DOI

10.1109/JSSC.2007.914328

Filename

4444568