Title :
Resonant-Clock Design for a Power-Efficient, High-Volume x86-64 Microprocessor
Author :
Sathe, V.S. ; Arekapudi, S. ; Ishii, A. ; Ouyang, Chunmei ; Papaefthymiou, Marios C. ; Naffziger, Samuel
Author_Institution :
Adv. Micro Devices, Fort Collins, CO, USA
Abstract :
AMD´s 32-nm x86-64 core code-named “Piledriver” features a resonant global clock distribution to reduce clock distribution power while maintaining a low clock skew. To support a wide range of operating frequencies expected of the core, the global clock system operates in two modes: a resonant-clock (rclk) mode for energy-efficient operation over a desired frequency range and a conventional, direct-drive mode (cclk) to support low-frequency operation. This dual-mode feature was implemented with minimal area impact to achieve both reduced average power dissipation and improved power-constrained performance. In Piledriver, resonant clocking achieves a peak 25% global clock power reduction at 75 °C, which translates to a 4.5% reduction in average application core power.
Keywords :
clocks; integrated circuit design; microprocessor chips; AMD x86-64 core code; Piledriver; average power dissipation reduction; direct-drive mode; dual-mode feature; energy-efficient operation; frequency range; global clock system; high-volume x86-64 microprocessor; low clock skew; low-frequency operation; power-constrained performance improvement; rclk mode; resonant global clock distribution; resonant-clock design; size 32 nm; temperature 75 degC; Capacitance; Clocks; Couplings; Inductors; Microprocessors; Programming; Resonant frequency; Clocks; high-performance computing; low-power electronics; microprocessors;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2012.2218068
