Design of 10T SRAM cell with improved read performance and expanded write margin

Ashish Sachdeva, V. Tomar
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引用次数: 12

Abstract

Ashish Sachdeva, ECE Department, GLA University, Mathura, India. Email: er.ashishsachdeva@gmail.com Funding Information The authors have no relevant financial or non‐ financial/ Funding interests to disclose. Abstract The need of genuine processors operation improvement cultivates the necessity for reliable, low power and fast memories. Several challenges follow this improvement at lower technology nodes. The impact of variability of process, temperature and voltage, on different performance parameters turns out to be most relevant issues in the nanometre SRAM design. The authors propose a 10T SRAM circuit that shows reduction in read power dissipation while maintaining fair performance and stability. Impression of process parameter variations on various design metrics such as read power, read current and data retention voltage of the proposed cell are presented and compared with already proposed SRAM cell. The projected topology offers differential read and single‐ended write operation. The read margin and write margin are enhanced by 8.69% and 16.85% respectively in comparison to standard 6T SRAM cell even when single‐ended write operation is performed. Furthermore, the read and write delay of projected topology improve by 1.78� and 2.326� in comparison with conventional 6T bit SRAM cell. In FF process corner, the proposed topology shows lowest data retention voltage (DRV) and minimum variation in DRV with temperature. Out of all considered topologies, the proposed circuit is optimized to minimum power delay product during read operation. Further, standby power and read power of proposed 10T cell is reduced by 34.65% and 2.03� in contrast to conventional 6T SRAM at 0.9 V supply voltage. Analysis of process variations tolerance read power and read current is also presented with 45 nm generic process design kit technology file using cadence virtuoso tool.
10T SRAM单元的设计,提高了读取性能并扩大了写入余量
Ashish Sachdeva,印度马图拉GLA大学欧洲经委会。作者没有相关的财务或非财务/资金利益需要披露。对正版处理器性能改进的需求催生了对可靠、低功耗、快速存储器的需求。在较低的技术节点上,这种改进带来了一些挑战。工艺、温度和电压的变化对不同性能参数的影响是纳米SRAM设计中最相关的问题。作者提出了一种10T SRAM电路,在保持良好性能和稳定性的同时降低了读功耗。提出了工艺参数变化对各种设计指标的影响,如读功率、读电流和数据保持电压,并与已经提出的SRAM单元进行了比较。投影拓扑提供差分读和单端写操作。与标准6T SRAM单元相比,即使执行单端写入操作,其读裕量和写裕量也分别提高了8.69%和16.85%。此外,与传统的6T位SRAM单元相比,投影拓扑的读写延迟分别提高了1.78°和2.326°。在FF过程角,所提出的拓扑具有最低的数据保留电压(DRV), DRV随温度的变化最小。在所有考虑的拓扑结构中,所提出的电路在读取操作期间被优化到最小的功率延迟产品。此外,在0.9 V电源电压下,与传统的6T SRAM相比,10T电池的待机功率和读取功率分别降低了34.65%和2.03°。利用cadence virtuoso工具对45 nm通用工艺设计套件技术文件进行了工艺变化公差、读功率和读电流分析。
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