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引用次数: 8
摘要
本文提出了一种可编译的SRAM,增强了休眠模式,以实现低待机功耗。休眠晶体管和源线自偏置被添加到阵列中,它们的布局适合重复单元放置。面积开销被最小化,从而使占用空间保持不变。由两家不同的代工厂生产的0.18 μ m 512 Kb测试芯片验证了其有效性。待机电流测量结果显示,在1.8 V时可分别节省69%和77%的电流。如果电源电压降低,节省的电能会更大。这有助于在低电压下睡觉。研究了改变虚地电压以达到进一步降低的设计选择。权衡的是数据保持电压,其测量值至少高出0.1 V。电池稳定性在睡眠模式下被破坏的事实是在低电压下操作SRAM的主要问题。
Standby Current Reduction of Compilable SRAM Using Sleep Transistor and Source Line Self Bias
This paper presents a compilable SRAM augmented with a sleep mode to achieve low standby power. Sleep transistor and source line self bias are added to the array, and their layouts fit to the repetitive cell placement. The area overhead is minimized in such a way that the footprint remains the same. A 0.18 mum 512 Kb test chip manufactured by two different foundries is used to demonstrate its effectiveness. The standby current measurements show substantial savings of 69% and 77%, respectively, at 1.8 V. The savings can be greater if the supply voltage is lowered. This encourages sleeping at low voltage. Design choices to vary the virtual ground voltage to attain further reduction are investigated. The tradeoff is with the data retention voltage which is measured at least 0.1 V higher. The fact that the cell stability is undermined in the sleep mode is the main concern to operate the SRAM at low voltage.
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