DVFS Considering Spatial Correlation Timing and Process-Voltage-Temperature Variations
Journal
International System on Chip Conference
Journal Volume
2020-September
Pages
141-146
Date Issued
2020
Author(s)
Lin T.-L
Abstract
A novel scheme, spatially-correlated Design Dependent Critical-Path Monitor (DDCPM), is proposed, which can provide valuable references in deriving application-specific, process- and temperature-aware DVFS for aggressive power saving during runtime. Such DDCPM utilizes its unique spatial correlation feature and real-time sampling techniques to precisely sense the unexpected behavior introduced by over-scaled voltage under the operating conditions with random and mutually dependent Process-Voltage-Temperature (PVT) variations in each individual chip. Our experimental results obtained in two IPs implemented in TSMC 28 nm process node respectively show average step-wise 7.80% and 8.19% power could be reduced at a smaller granular level of voltage scaling, which corresponding maximum power reductions, 55.6% and 57.5% in Typical Corner could be finally achieved. © 2020 IEEE.
Subjects
Design Dependent Critical-Path Monitor (DDCPM); System Control and Management Interface (SCMI)
Other Subjects
Dynamic frequency scaling; Timing circuits; Uninterruptible power systems; Control and management; Control interfaces; Critical path monitor; Design dependent critical-path monitor; Management interfaces; Spatial correlations; System control; System control and management interface; Systems management; Temperature variation; Voltage scaling
Type
conference paper