Low Voltage Circuit Design Techniques for Cubic-Millimeter Computing.

Abstract

Cubic-millimeter computers complete with microprocessors, memories, sensors, radios and power sources are becomingly increasingly viable. Power consumption is one of the last remaining barriers to cubic-millimeter computing and is the subject of this work. In particular, this work focuses on minimizing power consumption in digital circuits using low voltage operation. Chapter 2 includes a general discussion of low voltage circuit behavior, specifically that at subthreshold voltages. In Chapter 3, the implications of transistor scaling on subthreshold circuits are considered. It is shown that the slow scaling of gate oxide relative to the device channel length leads to a 60% reduction in Ion/Ioff between the 90nm and 32nm nodes, which results in sub-optimal static noise margins, delay, and power consumption. It is also shown that simple modifications to gate length and doping can alleviate some of these problems. Three low voltage test-chips are discussed for the remainder of this work. The first test-chip implements the Subliminal Processor (Chapter 4), a sub-200mV 8-bit microprocessor fabricated in a 0.13µm technology. Measurements first show that the Subliminal Processor consumes only 3.5pJ/instruction at Vdd=350mV. Measurements of 20 dies then reveal that proper body biasing can eliminate performance variations and reduce mean energy substantially at low voltage. Finally, measurements are used to explore the effectiveness of body biasing, voltage scaling, and various gate sizing techniques for improving speed. The second test-chip implements the Phoenix Processor (Chapter 5), a low voltage 8-bit microprocessor optimized for minimum power operation in standby mode. The Phoenix Processor was fabricated in a 0.18µm technology in an area of only 915x915µm2. The aggressive standby mode strategy used in the Phoenix Processor is discussed thoroughly. Measurements at Vdd=0.5V show that the test-chip consumes 226nW in active mode and only 35.4pW in standby mode, making an on-chip battery a viable option. Finally, the third test-chip implements a low voltage image sensor (Chapter 6). A 128x128 image sensor array was fabricated in a 0.13µm technology. Test-chip measurements reveal that operation below 0.6V is possible with power consumption of only 1.9µW at 0.6V. Extensive characterization is presented with specific emphasis on noise characteristics and power consumption.