Design of SEU and DNU-resistant SRAM cells based on polarity reinforcement feature

As the scale of the integrated circuit increases, the distance between transistors decreases, a trend that reduces the critical charge of the sensitive nodes of the memory cell. Consequently, Static Random Access Memory cells in high radiation environments are very prone to soft errors. A novel radiation-hardened memory cell, the Polarity Reinforcement Feature (PRF)-18T, is proposed in this paper, which uses the polarity reinforcement feature to reduce the number of sensitive nodes in the memory cell and can entirely and effectively tolerate single event upset and double node upset. A comparison is made in this paper with DICE-12T, Quatro-10T, SEA-14T, RHBD-14T, NASA-13T, and SCCS-18T memory cells in a simulation environment with Semiconductor Manufacturing International Corporation 55 nm process, the supply voltage of 1.2 V, and temperature of 25 degrees C. In comparison, the PRF-18T proposed in this paper has the highest critical charge value, improving by more than 15x and 3.1x compared to the DICE-12T and RHBD-14T, respectively, and by more than 79% and 17.6% compared to the Quatro-10T and SEA-14T, respectively. In the high hold static noise margin comparison, the improvement over the SEA-14T, DICE-12T, RHBD-14T, and Quatro-10T is 26.7%, 3.8x, 1.5x, and 1.2x, respectively. In the write static noise margin comparison, the results were similar to the Quatro-10T, DICE-12T, and SEA-14T, with a 68.5% improvement compared to the RHBD-14T. Finally, the robustness of the proposed cell to process, voltage, and temperature variations is verified by temperature change experiments and 2000 Monte Carlo model simulations.