Abstract :
Summary form only given. The scaling of the CMOS channel length to below 0.5 μm and increase of the chip density to the ULSI range have placed power dissipation on an equal footing with performance as a figure of merit in digital circuit design. Portability and reliability have also played a major role in the emergence of low-power, low-voltage, digital circuit designs. The need to extend the battery life, to have inexpensive packaging and cooling systems, and to reduce the weight and size of the equipment were the driving forces in this regard. Reducing the power dissipation of arithmetic operations while keeping the performance unaffected, is indispensable for digital signal processing (DSP), reduced instruction set computers (RISCs), microprocessors, etc. In this presentation, several novel high performance digital circuit designs that emphasize low-power and low-voltage operation are introduced. These circuits utilize a wide range of techniques that are used in state-of-the-art VLSI systems and hence serve as good examples for low-power design. In addition, important features of submicron VLSI technologies that support low-power operation of digital systems are discussed
Keywords :
CMOS digital integrated circuits; VLSI; cooling; digital arithmetic; digital signal processing chips; integrated circuit design; integrated circuit packaging; integrated circuit reliability; low-power electronics; microprocessor chips; reduced instruction set computing; thermal management (packaging); CMOS channel length scaling; DSP; IC performance; RISCs; ULSI range; VLSI systems; arithmetic operations; battery life; chip density; cooling systems; digital circuit design; digital signal processing; digital systems; equipment size; equipment weight; figure of merit; low power VLSI CMOS circuit design; low-power design; low-power low-voltage digital circuit design; low-power operation; low-voltage operation; microprocessors; packaging; portability; power dissipation; reduced instruction set computers; reliability; Batteries; CMOS digital integrated circuits; Circuit synthesis; Digital circuits; Digital signal processing; Packaging machines; Power dissipation; Power system reliability; Ultra large scale integration; Very large scale integration;
