Comparison of NBTI aging on adder architectures and ring oscillators in the downscaling technology nodes

Negative Bias Temperature Instability (NBTI) is one of the major time-dependent degradation mechanisms that impact the reliability of advanced deeply scaled CMOS technologies. NBTI can cause workload-dependent shifts on a transistor’s threshold voltage (VTHVTH), and performance during its lifetime. This study presents a comparison of the NBTI aging on adder architectures and ring oscillators in the downscaling technology nodes. The first part of the study focuses on the NBTI-induced performance degradation of 32-bit adders (one of the most fundamental block of a processor’s arithmetic logic unit) from the points of architectural topology and workload dependency in the planar technologies (i.e. commercial 28,45,6528,45,65 nm nodes), while the second part investigates the energy-delay product degradation of ring oscillators beyond the planar nodes (i.e. research-grade 14,10,714,10,7 nm FinFET technology nodes for several FET channel materials, e.g. Si, SiGe, Ge, InGaAs). Results show the tight coupling between the NBTI aging and the architectural topology, run-time workload, and technology choice.