Abstract

As transistors shrink in size, the integration density of memory circuits like Static Random Access Memory (SRAM) cells rises, making them increasingly susceptible to Single Event Effects (SEE). In the space environment, memory circuits face stability and reliability challenges due to the presence of various charged particles such as α-particles, neutrons, electrons, heavy ions, and photons. These high-energy particles create ion tracks when they strike the memory device, leading to upsets in the storage bits. Conventional 6 T SRAM cells are susceptible to these upsets. As a solution this paper proposes a new Radiation Tolerable (RT 13 T) SRAM cell that is better suited for deep-space applications compared to other memory cell. RT13T has been validated to withstand radiation hazards through Critical Charge (QCrit) analysis, which shows that it exhibits 1.17×, 1.1×, 1.94× and 1.06× highest QCritthan QUCCE 10 T/12 T,traditional 6 T and LIOR 13 T memory cells, respectively. As the comparison made, our Proposed RT 13 T saved by5.1 %,9.9 %, 20.1 % and 7 % of the power consumption compared to QUCCE10T/12 T/LIOR 13 T/SERSC-16 T SRAM cells at a nominal supply voltage of 0.7 V. It also exhibits shorter read delay (TRA) 10.6 %, 1.34 %, 9.6 %, 22.16 %compared to QUCCE 10 T/12 T,6T, SERSC-16Tmemory cells, respectively. In terms of stability,our proposed RT13T SRAM cell exhibits 2.32×/2.05×/2.9×/1.05×/1.01 × higher read stability as compared with QUCCE10T/12 T/6T/LIOR 13 T/SERSC-16 T memory cells during the read operation. The our proposed RT13T shows improvements in design metrics are at the expense of a longer write delay. To characterize the performances of the proposed RT13T, 16-nm CMOS predictive technology model and validated through extensive simulation with licensed PrimeSim HSPICE of Synopsys. The results of our proposed RT13T cell are compared with some other previously proposed memory cells such as 6 T, QUCCE 10 T, QUCCE 12 T, LIOR 13 T and SERSC-16 T memory cells. The obtained results are tabulated and plotted for graphical analysis. In terms of area consumption our proposed 13 T consumes 0.9×/0.6 × lesser area than QUCCE 12 T/SERSC-16 T memory cells but our proposed circuit consumes 3.1×/1.08×/1.05 × more area than QUCCE10T/conventional 6 T/LIOR 13 T because QUCCE10T and 6 T consist of less number of transistors in memory cells.The cell proposed in this paper demonstrates strong radiation-hardened capabilities and excellent overall performance, making it well-suited for aerospace electronic devices and ensuring stable operation in space radiation environments.

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