While Resistive RAM (RRAM) are seen as an alternative to NAND Flash, their variability and cycling understanding remain a major roadblock. Extensive characterizations of multi-kbits RRAM arrays during Forming, Set, Reset and cycling operations are presented allowing to investigate the relationships between programming conditions, memory window and endurance features. The experimental results are then used to perform variability-aware simulations of a RRAM-based ternary content-addressable-memory (TCAM) 128 bit macro with different operating conditions.
While standalone Flash memories (NAND) are facing their physical limitations, the emergence of resistive switching memories (RRAM) is seen as a solution for high density, low cost and low energy NAND replacement candidate. However, it has been shown that deeply scaled, high density RRAM architectures, such as crosspoint, suffer of voltage drop effects (IR drop) in metal lines, periphery overhead and metal line charging time due to injected current during programming operations and sneaking currents through unselected bitcells. In this work, we first propose several innovative models for IRdrop, periphery overhead and array-line charging time accounting for in-array multiple bit-write operation. Then, we introduce a new methodology for crosspoint memory design to determine IRdrop, periphery overhead and timing associated with the optimal characteristics of 1 selector-1 resistance (1S1R) device. We apply the proposed methodology to various half metal pitch memory technology nodes (from 50nm to 15nm) and to several written word sizes (from 1 to 32 bits). We show that for 1 bit programmed per array, the RRAM programming current has to be lower than 30µA and the selector leakage current lower than 10nA and that limitations increase as soon as multiple bits are written simultaneously in the same array. This, suggests massively parallel multi-bank write of a small number of bits per array, as the best solution for the RRAM memories to be competitive with NAND memories
New CMOS technologies such as SOI or FinFET are expected to enhance SRAM radiation-induced soft error rates thanks to a reduction on the charge collected as the devices get smaller. In this work we analyze how the radiation hardening capabilities of SRAMs are affected when process variations are considered by simulating cells using a predictive FinFET technology.The results show that even if the average critical charge to which SRAM cells are vulnerable is enhanced by process variations, its widened spread leads to an increase of the soft error rate by more than 40% as the technology node is scaled down to 7nm.
Abstract-Resistive switching memories (RRAM) are an attractive alternative to non-volatile storage and non-conventional computing systems, but their behavior strongly depends on the cell features, driver circuit and working conditions. In particular, the circuit temperature and the writing voltage scheme become critical issues, determining resistive switching memories performance. These dependencies usually force a design time trade-off among reliability, device endurance and power consumption, and therefore imposing non-flexible functioning schemes and limiting the system performance. In this paper we present a writing architecture that ensures the correct operation no matter the working temperature, and allows the dynamic load of application oriented writing profiles. Thus, taking advantage of more efficient configurations, the system can be dynamically adapted to overcome RRAM intrinsic challenges. Several profiles are analyzed regarding power consumption, temperature-variations protection and operation speed, showing speed-ups near to 700 x compared against other published drivers.
Resistive Random Access Memories (RRAMs) are a promising solution to implement Ternary Content Addressable Memories (TCAMs) that are more area-and energy-efficient with respect to Static Random Access Memory (SRAM)-based TCAMs. However, RRAM-based TCAMs are limited in the number of bits per word due to the low ratio between the resistances of the high and low resistance states (HRS/LRS) and resistance variability of RRAM. Such a limitation on the word length hinders the parallel search of a very large number of data bits for data-intensive applications. To overcome this issue, for the first time, we propose a new TCAM cell composed of two transistors and two RRAMs in a 1T2R1T configuration, where a RRAM voltage divider (2R) biases a transistor gate (1T) and an additional transistor is used to program the RRAMs (1T). A 3x128bits 1T2R1T TCAM macro were designed, integrated and extensively characterized. We experimentally demonstrate that the sensing margin of the proposed structure is insensitive to HRS/LRS RRAM resistance ratio and variability. With respect to the most common type of 2T2R RRAM-based TCAM [1-3], the proposed circuit improves the sensing margin by >5000x while reaching search times of 0.93ns. This allows the search of large volumes of data in parallel. In addition, the proposed structure improves programming and search endurance by 100x and >10x, respectively.
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