Since Moore’s law driven scaling of planar MOSFETs faces formidable challenges in the nanometer regime, FinFETs and Trigate FETs have emerged as their successors. Owing to the presence of multiple (two/three) gates, FinFETs/Trigate FETs are able to tackle short-channel effects (SCEs) better than conventional planar MOSFETs at deeply scaled technology nodes and thus enable continued transistor scaling. In this paper, we review research on FinFETs from the bottommost device level to the topmost architecture level. We survey different types of FinFETs, various possible FinFET asymmetries and their impact, and novel logic-level and architecture-level tradeoffs offered by FinFETs. We also review analysis and optimization tools that are available for characterizing FinFET devices, circuits, and architectures.
Content addressable memories (CAMs) enable highspeed parallel search operations in table lookup-based applications, such as Internet routers and processor caches. Traditional CAM design has always suffered from the high dynamic power consumption associated with its large and active parallel hardware. However, deeply scaled technology nodes, with multigate devices replacing planar MOSFETs, are expected to bring new tradeoffs to CAM design. FinFET, a vertical-channel gate-wraparound double-gate device, has emerged as the best alternative to planar MOSFET. In this brief, for the first time, we explore the design space of symmetric and asymmetric gate-workfunction FinFET CAMs. We propose several design alternatives and evaluate them in terms of their dc and transient metrics for different mismatch probabilities using technology computeraided design simulations with 22-nm FinFET devices. We also propose two orthogonal layout styles for CAM design and show that one of them (vertical-search line) outperforms the other (vertical-match line) in terms of total power (22.3%) and search delay (5.8%).
Index Terms-Content addressable memories (CAMs),FinFET, parasitic extraction, technology computer-aided design (TCAD).
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.