Title :
A 90-nm low-power 32-kB embedded SRAM with gate leakage suppression circuit for mobile applications
Author :
Nii, Koji ; Tsukamoto, Yasumasa ; Yoshizawa, Tomoaki ; Imaoka, Susumu ; Yamagami, Yoshinobu ; Suzuki, Toshikazu ; Shibayama, Akinori ; Makino, Hiroshi ; Iwade, Shuhei
Author_Institution :
Renesas Technol. Corp., Hyogo, Japan
fDate :
4/1/2004 12:00:00 AM
Abstract :
In sub-100-nm generation, gate-tunneling leakage current increases and dominates the total standby leakage current of LSIs based on decreasing gate-oxide thickness. Showing that the gate leakage current is effectively reduced by lowering the gate voltage, we propose a local dc level control (LDLC) for SRAM cell arrays and an automatic gate leakage suppression driver (AGLSD) for peripheral circuits. We designed and fabricated a 32-kB 1-port SRAM using 90-nm CMOS technology. The six-transistor SRAM cell size is 1.25 μm2. Evaluation shows that the standby current of 32-kB SRAM is 1.2 μA at 1.2 V and room temperature. It is reduced to 7.5% of conventional SRAM.
Keywords :
CMOS memory circuits; SRAM chips; embedded systems; leakage currents; 1.2 V; 1.2 muA; 32 kbit; 90 nm; CMOS technology; LSI; SRAM cell arrays; automatic gate leakage suppression driver; decreasing gate-oxide thickness; gate leakage suppression circuit; gate voltage; gate-tunneling leakage current; local dc level control; low-power embedded SRAM; mobile applications; peripheral circuits; six-transistor SRAM cell; total standby leakage current; CMOS technology; Dielectric materials; Driver circuits; Gate leakage; Leakage current; Level control; Random access memory; Standby generators; Temperature; Voltage;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2004.825235
