SRAM Circuit-Failure Modeling and Reliability Simulation With SPICE

Abstract

Based on some new accelerated lifetime models and failure equivalent circuit modeling techniques for the common semiconductor wear out mechanisms, simulation program with integrated circuit emphasis (SPICE) can be used to characterize CMOS VLSI circuit failure behaviors and perform reliability simulation. This paper used a simple SRAM circuit as an example to demonstrate how to apply SPICE to circuit reliability modeling, simulation, analysis, and design. The SRAM circuit, implemented with a commercial 0.25-mum technology, consists of functional blocks of 1-bit six-transistor cell, precharge, read/write control, and sense amplifier. The SRAM operation sequence of "write 0, read 0, write 1, read 1" was first simulated in SPICE to obtain the terminal voltage and current stress profiles of each transistor. Then, normalized lifetimes of all transistors in terms of each failure mechanism were calculated with the corresponding accelerated lifetime models. These lifetime values were sorted to single out the most damaged transistors. Finally, the selected transistors were substituted with failure equivalent circuit models, and SPICE simulations were performed again to characterize the circuit performance, functionality, and failure behaviors. The simulation shows that the 0.25-mum technology, hot-carrier injection (HCI), and time-dependent dielectric breakdown (TDDB) had significant effects on SRAM-cell stability and voltage-transfer characteristics, while negative bias temperature instability (NBTI) mainly degraded the cell transition speed when the cell state flipped. This illustrative SRAM simulation work proves that, with SPICE and the failure equivalent circuit models, circuit designers can better understand the damage effects of HCI/TDDB/NBTI on the circuit operation, quickly estimate the circuit lifetime, make appropriate performance/reliability tradeoffs, and formulate practical design guidelines to improve the circuit reliability