An Accurate Process Induced Variability Aware Compact Model-based Circuit Performance Estimation for Design-Technology Co-optimization

Abstract

In sub-10nm FinFETs, Line-edge-roughness (LER) and metal-gate granularity (MGG) are the two most dominant sources of variability and are mostly modeled semi-empirically. In this work, compact models of LER and MGG are used. We show an accurate process-induced variability (PIV) aware compact model-based circuit performance estimation for Design-Technology Co-optimization (DTCO). This work is carried out using an experimentally validated BSIM-CMG model on a 7nm FinFET node. First, we have shown performance bench-marking of LER and MGG models with the state-of-the-art and shown 4x(2.3x) accuracy improvement for NMOS(PMOS) in the estimation of device figure of merits (DFoMs). Second, RO and SRAM circuits performance estimation is carried out for LER and MGG variability. Further, 22\% more optimistic estimate of (σ/μ)SHM (Static Hold Margin) compared to the state-of-the-art model with VDD variation is shown. Finally, we demonstrate our improved DFoMs accuracy translated to more accurate circuits figure of merits (CFoMs) performance estimation. For worst-case SHM (3(σ/μ)SHM@VDD=0.75 V) compared to state-of-the-art, dynamic(standby) power reduction by 73\%(61\%) is shown. Thus, our enhanced variability model accuracy enables more credible DTCO with significantly better performance estimates.