Title :
SRAM leakage suppression by minimizing standby supply voltage
Author :
Qin, Huifang ; Cao, Yu ; Markovic, Dejan ; Vladimirescu, Andrei ; Rabaey, Jan
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., California Univ., Berkeley, CA, USA
Abstract :
Suppressing the leakage current in memories is critical in low-power design. By reducing the standby supply voltage (VDD) to its limit, which is the data retention voltage (DRV), leakage power can be substantially reduced. This paper explores how low DRV can be in a standard low leakage SRAM module and analyzes how DRV is affected by parameters such as process variations, chip temperature, and transistor sizing. An analytical model for DRV as a function of process and design parameters is presented, and forms the basis for further design space explorations. This model is verified using simulations as well as measurements from a 4 kB SRAM chip in a 0.13 μm technology. It is demonstrated that an SRAM cell state can be preserved at sub-300 mV standby VDD, with more than 90% leakage power savings.
Keywords :
SRAM chips; circuit optimisation; integrated circuit design; integrated circuit measurement; integrated circuit modelling; leakage currents; low-power electronics; 0.13 micron; 300 mV; 4 kB; DRV; SRAM cell state preservation; SRAM leakage suppression; chip temperature; data retention voltage; leakage current; low-power design; process variations; standby supply voltage minimization; transistor sizing; Analytical models; Leakage current; Process design; Random access memory; SRAM chips; Semiconductor device measurement; Space exploration; Space technology; Temperature; Voltage;
Conference_Titel :
Quality Electronic Design, 2004. Proceedings. 5th International Symposium on
Print_ISBN :
0-7695-2093-6
DOI :
10.1109/ISQED.2004.1283650
