A Low-Latency, Energy-Efficient L1 Cache Based on a Self-Timed Pipeline

Abstract: The design of a low latency, energy-efficient selftimed L1 cache is presented. The pipeline integrates Octasic's token-based architecture and a two-phase handshake protocol derived from Click elements. Only standard flip-flops are used as state-holding elements for the pipeline control and datapath. Simulations and post-layout static timing analysis were based on a commercial 28nm bulk process. Power analysis indicates a 20% improvement in energy efficiency when compared to the previous synchronous cache for t… Show more

“…The AnARM was fabricated with a 28 nm technology, as reported in [9]. It first served as a proof of concept to be compared with other general-purpose processors and provided a context for a novel self-timed cache architecture [10], a new model for dynamic voltage scaling [11], and original test methods [12]. We revisit the original Octasic self-timed design style using circuits and methods coming from the asynchronous literature, with the objective of lowering the barrier with timing-driven EDA flows.…”

Introducing KeyRing self‐timed microarchitecture and timing‐driven design flow

“…The AnARM was fabricated with a 28 nm technology, as reported in [9]. It first served as a proof of concept to be compared with other general-purpose processors and provided a context for a novel self-timed cache architecture [10], a new model for dynamic voltage scaling [11], and original test methods [12]. We revisit the original Octasic self-timed design style using circuits and methods coming from the asynchronous literature, with the objective of lowering the barrier with timing-driven EDA flows.…”

Introducing KeyRing self‐timed microarchitecture and timing‐driven design flow