Title :
The design and implementation of a low-power clock-powered microprocessor
Author :
Athas, William ; Tzartzanis, Nestoras ; Mao, Weihua ; Peterson, Lena ; Lal, Rajat ; Chong, Kisup ; Moon, Joong-Seok ; Svensson, Lars ; Bolotski, Michael
Author_Institution :
House Ear Inst., Los Angeles, CA, USA
Abstract :
We describe the design and implementation of a 16-bit clock-powered microprocessor that dissipates only 2.9 mW at 15.8 MHz based on laboratory measurements. Clock-powered logic (CPL) has been developed as a new approach for designing and building low-power VLSI systems that exploit the benefits of supply-voltage-scaled static CMOS and energy-recovery CMOS techniques. In CPL, the clock signals are a source of ac power for the other large on-chip capacitive loads. Clock amplitude and waveform shape combine to reduce power. By exploiting energy recovery and an energy-conserving clock driver, it is possible to build ultra-low-power CMOS processors with this approach. We compare the CPL approach with a conventional, fully dissipative approach for a processor with a similar ISA and VLSI architecture which was designed using the same set of VLSI CAD tools. The simulation results indicate that the CPL microprocessor would dissipate 40% less power than the conventional design.
Keywords :
CMOS digital integrated circuits; VLSI; circuit CAD; circuit simulation; clocks; integrated circuit design; low-power electronics; microprocessor chips; 15.8 MHz; 16 bit; 2.9 mW; VLSI CAD tools; clock amplitude; clock-powered logic; energy recovery; energy-conserving clock driver; energy-recovery CMOS; low-power VLSI system design; low-power clock-powered microprocessor; power dissipation; simulation results; supply-voltage-scaled static CMOS; ultra-low-power CMOS processors; waveform shape; Buildings; CMOS logic circuits; CMOS process; CMOS technology; Clocks; Laboratories; Logic design; Microprocessors; Shape; Very large scale integration;
Journal_Title :
Solid-State Circuits, IEEE Journal of
