Analysis of static noise margin and power-gating efficiency of a new nonvolatile SRAM cell using pseudo-spin-MOSFETs

Abstract

Static noise margins (SNMs) and power-gating efficiency were computationally analyzed for our proposed nonvolatile SRAM (NV-SRAM) cell based on pseudo-spin-MOSFET (PS-MOSFET) architecture using spin-transfer-torque MTJs (STT-MTJs). The NV-SRAM cell has the same SNMs as an optimized 6T-SRAM cell. SNMs for other recently-proposed NV-SRAM cells using STT-MTJs were also evaluated, and we showed that their SNMs were deteriorated owing to the effect of the constituent STT-MTJs. Break-even time (BET) and power efficiency were analyzed for the NV-SRAM cell using PS-MOSFETs. The BET can be successfully minimized by controlling the bias of the cell. The average power dissipation can be effectively reduced by power-gating (PG) executions, and the further reduction is made possible by introducing a sleep mode.