Design and investigation of stability‐ and power‐improved 11T SRAM cell for low‐power devices
Erfan Abbasian, Shilpi Birla, Emad Mojaveri Moslem
Abstract
Abstract The modern system‐on‐chips require stable and low‐power SRAM cells due to technology scaling and limited sources of energy. Therefore, a stability‐ and power‐improved 11T SRAM cell is proposed in this study. The proposed cell core is composed of a strong cross‐coupled structure of a conventional inverter with a N‐type stacked transistor and a Schmitt‐trigger (ST) with a double channel‐length pull‐up network. This coupled with a separate read path enhances the read static noise margin (RSNM). Moreover, a feedback‐cutting N‐type transistor is placed inside the cell core to improve the write static noise margin (WSNM)/write margin (WM). Though the presence of stacked transistors in access paths increases read delay ( T R A )/write delay ( T W A ), it reduces leakage. This metric further minimizes with the aid of a stacked structure of latch core and double channel‐length of pull‐up transistor in the ST inverter. The moderate read/write frequency and single‐ended structure of the suggested cell result in low dynamic power. Simulated results by using 16‐nm CMOS at V D D = 0.7 V show that the proposed cell has the second‐best RSNM/WSNM, which is 4.65/1.44 times higher than that of the fully differential 8T (FD8T) cell, as the basic cell. Moreover, it reduces leakage power by at least 2.01 times and consumes moderate read/write power, nearly 1.44/1.81 times lower than that of FD8T cell, at the cost of 1.61 times area overhead. The proposed cell can eliminate read/write‐half‐select‐disturbance issues to support bit‐interleaving architecture to increase soft error immunity.