A low leakage current subthreshold SRAM in 130 nm CMOS technology is proposed for ultra low voltage(200 mV) applications.Almost all of the previous subthreshold works ignore the leakage current in both active and st...A low leakage current subthreshold SRAM in 130 nm CMOS technology is proposed for ultra low voltage(200 mV) applications.Almost all of the previous subthreshold works ignore the leakage current in both active and standby modes.To minimize leakage,a self-adaptive leakage cut off scheme is adopted in the proposed design without any extra dynamic energy dissipation or performance penalty.Combined with buffering circuit and reconfigurable operation,the proposed design ensures both read and standby stability without deteriorating writability in the subthreshold region.Compared to the referenced subthreshold SRAM bitcell,the proposed bitcell shows:(1) a better critical state noise margin,and(2) smaller leakage current in both active and standby modes. Measurement results show that the proposed SRAM functions well at a 200 mV supply voltage with 0.13μW power consumption at 138 kHz frequency.展开更多
We have presented an analysis of the gate leakage current of the IP3 static random access memory (SRAM) cell structure when the cell is in idle mode(performs no data read/write operations) and active mode (perfor...We have presented an analysis of the gate leakage current of the IP3 static random access memory (SRAM) cell structure when the cell is in idle mode(performs no data read/write operations) and active mode (performs data read/write operations),along with the requirements for the overall standby leakage power,active write and read powers.A comparison has been drawn with existing SRAM cell structures,the conventional 6T,PP, P4 and P3 cells.At the supply voltage,V_(DD) = 0.8 V,a reduction of 98%,99%,92%and 94%is observed in the gate leakage current in comparison with the 6T,PP,P4 and P3 SRAM cells,respectively,while at V_(DD) = 0.7 V,it is 97%,98%,87%and 84%.A significant reduction is also observed in the overall standby leakage power by 56%〉, the active write power by 44%and the active read power by 99%,compared with the conventional 6T SRAM cell at V_(DD)= 0.8 V,with no loss in cell stability and performance with a small area penalty.The simulation environment used for this work is 45 nm deep sub-micron complementary metal oxide semiconductor(CMOS) technology,t_(ox) = 2.4 nm,K_(thn) = 0.22 V,K_(thp) = 0.224 V,V_(DD) = 0.7 V and 0.8 V,at T = 300 K.展开更多
The present paper analyzes the hold and read stability with temperature and aspect ratio variations. To reduce the power dissipation, one of the effective techniques is the supply voltage reduction. At this reduced su...The present paper analyzes the hold and read stability with temperature and aspect ratio variations. To reduce the power dissipation, one of the effective techniques is the supply voltage reduction. At this reduced supply voltage the data must be stable. So, the minimum voltage should be discovered which can also retain the data. This voltage is the data retention voltage(DRV). The DRV for 6T SRAM cell is estimated and analyzed in this paper.The sensitivity analysis is performed for the DRV variation with the variation in the temperature and aspect ratio of the pull up and pull down transistors. Cadence Virtuoso is used for DRV analysis using 45 nm GPDK technology files. After this, the read stability analysis of 6T SRAM cell in terms of SRRV(supply read retention voltage) and WRRV(wordline read retention voltage) is carried out. Read stability in terms of RSNM can be discovered by accessing the internal storage nodes. But in the case of dense SRAM arrays instead of using internal storage nodes,the stability can be discovered by using direct bit line measurements with the help of SRRV and WRRV. SRRV is used to find the minimum supply voltage for which data can be retained during a read operation. Similarly, WRRV is used to find the boosted value of wordline voltage, for which data can be retained during read operation. The SRRV and WRRV values are then analyzed for different Cell Ratios. The results of SRRV and WRRV are then compared with the reported data for the validation of the accuracy of the results.展开更多
基金supported by the China State-Funded Study Abroad Program for High-Level Universities
文摘A low leakage current subthreshold SRAM in 130 nm CMOS technology is proposed for ultra low voltage(200 mV) applications.Almost all of the previous subthreshold works ignore the leakage current in both active and standby modes.To minimize leakage,a self-adaptive leakage cut off scheme is adopted in the proposed design without any extra dynamic energy dissipation or performance penalty.Combined with buffering circuit and reconfigurable operation,the proposed design ensures both read and standby stability without deteriorating writability in the subthreshold region.Compared to the referenced subthreshold SRAM bitcell,the proposed bitcell shows:(1) a better critical state noise margin,and(2) smaller leakage current in both active and standby modes. Measurement results show that the proposed SRAM functions well at a 200 mV supply voltage with 0.13μW power consumption at 138 kHz frequency.
文摘We have presented an analysis of the gate leakage current of the IP3 static random access memory (SRAM) cell structure when the cell is in idle mode(performs no data read/write operations) and active mode (performs data read/write operations),along with the requirements for the overall standby leakage power,active write and read powers.A comparison has been drawn with existing SRAM cell structures,the conventional 6T,PP, P4 and P3 cells.At the supply voltage,V_(DD) = 0.8 V,a reduction of 98%,99%,92%and 94%is observed in the gate leakage current in comparison with the 6T,PP,P4 and P3 SRAM cells,respectively,while at V_(DD) = 0.7 V,it is 97%,98%,87%and 84%.A significant reduction is also observed in the overall standby leakage power by 56%〉, the active write power by 44%and the active read power by 99%,compared with the conventional 6T SRAM cell at V_(DD)= 0.8 V,with no loss in cell stability and performance with a small area penalty.The simulation environment used for this work is 45 nm deep sub-micron complementary metal oxide semiconductor(CMOS) technology,t_(ox) = 2.4 nm,K_(thn) = 0.22 V,K_(thp) = 0.224 V,V_(DD) = 0.7 V and 0.8 V,at T = 300 K.
文摘The present paper analyzes the hold and read stability with temperature and aspect ratio variations. To reduce the power dissipation, one of the effective techniques is the supply voltage reduction. At this reduced supply voltage the data must be stable. So, the minimum voltage should be discovered which can also retain the data. This voltage is the data retention voltage(DRV). The DRV for 6T SRAM cell is estimated and analyzed in this paper.The sensitivity analysis is performed for the DRV variation with the variation in the temperature and aspect ratio of the pull up and pull down transistors. Cadence Virtuoso is used for DRV analysis using 45 nm GPDK technology files. After this, the read stability analysis of 6T SRAM cell in terms of SRRV(supply read retention voltage) and WRRV(wordline read retention voltage) is carried out. Read stability in terms of RSNM can be discovered by accessing the internal storage nodes. But in the case of dense SRAM arrays instead of using internal storage nodes,the stability can be discovered by using direct bit line measurements with the help of SRRV and WRRV. SRRV is used to find the minimum supply voltage for which data can be retained during a read operation. Similarly, WRRV is used to find the boosted value of wordline voltage, for which data can be retained during read operation. The SRRV and WRRV values are then analyzed for different Cell Ratios. The results of SRRV and WRRV are then compared with the reported data for the validation of the accuracy of the results.
