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Chapter 1: Introduction to Analog Design

The idea of placing multiple electronic devices on the same substrate was conceived in the late 1950s. In 40 years, the technology has evolved from producing simple chips containing a handful of components to fabricating memories accommodating more than one billion transistors as well as microprocessors comprising more than 10 million devices. As Gordon Moore (one of the founders of Intel) predicted in the early 1970s, the number of transistors per chip has continued to double approximately every one and a half years. At the same time, the minimum dimension of transistors has dropped from about 25 um in 1960 to about 0.18 F, m in the year 2000, resulting in a tremendous improvement in the speed of integrated circuits.

Driven by primarily the memory and microprocessor market, integrated-circuit technologies have also embraced analog design extensively, affording a complexity, speed, and precision that would be impossible to achieve using discrete implementations. Analog and mixed analog/digital integrated circuits containing tens of thousands of devices now routinely appear in consumer products. We can no longer build a discrete prototype to predict the behavior and performance of modern analog circuits.

1.3 Why CMOS?

The idea of metal-oxide-silicon field-effect transistors (MOSFETs) was patented by J. E. Lilienfeld in the early 1930s-well before the invention of the bipolar transistor. Owing to fabrication limitations, however, MOS technologies became practical much later, in the early 1960s, with the first several generations producing only n-type transistors. It was in the mid-1960s thatcomplementary MOS (CMOS) devices (i.e., both n-type and p-type transistors) were introduced, initiating a revolution in the semiconductor industry.

CMOS technologies rapidly captured the digital market: CMOS gates dissipated power only during switching and required very few devices, two attributes in sharp contrast to their bipolar or GaAs counterparts. It was also soon discovered that the dimensions of MOS devices could be scaled down more easily than those of other types of transistors. Furthermore, CMOS circuits proved to have a lower fabrication cost.

The next obvious step was to apply CMOS technology to analog design. The low cost of fabrication and the possibility of placing both analog and digital circuits on the same chip so as to improve the overall performance and/or reduce the cost of packaging made CMOS technology attractive. However, MOSFETs were quite slower and noisier than bipolar transistors, finding limited application.

How did CMOS technology come to dominate the analog market as well? The principal force was device scaling because it continued to improve the speed of MOSFETs. The intrinsic speed of MOS transistors has increased by more than three orders of magnitude in the past 30 years, becoming comparable with that of bipolar devices even though the latter have also been scaled (but not as fast). Multi-gigahertz analog CMOS circuits are now in production.

1.4 Why This Book?

The design of analog circuits itself has evolved together with the technology and the performance requirements. As the device dimensions shrink, the supply voltage of integrated circuits drops, and analog and digital circuits are fabricated on one chip, many design issues arise that were unimportant only a decade ago. Such trends demand that the analysis and design of circuits be accompanied by an in-depth understanding of their advantages and disadvantages with respect to new technology-imposed limitations.

Good analog design requires intuition, rigor, and creativity. As analog designers, we must wear our engineer's hat for a quick and intuitive understanding of a large circuit, our mathematician's hat for quantifying subtle, yet important effects in a circuit, and our artist's hat for inventing new circuit topologies.

This book describes modern analog design from both intuitive and rigorous angles. It also fosters the reader's creativity by carefully guiding him/her through the evolution of each circuit and presenting the thought process that occurs during the development of new circuit techniques.

1.5 General Concepts

1.5.1 Levels of Abstraction

Analysis and design of integrated circuits often require thinking at various levels of abstraction. Depending on the effect or quantity of interest, we may study a complex circuit at device physics level, transistor level, architecture level, or system level. In other words, we may consider the behavior of individual devices in terms of their internal electric fields and charge transport [Fig. 1.8(a)], the interaction of a group of devices according to their electrical characteristics [Fig. 1.8(b)], the function of several building blocks operating as a unit [Fig. 1.8(c)], or the performance of the system in terms of that of its constituent subsystems [Fig. 1.8(d)]. Switching between levels of abstraction becomes necessary in both understanding the details of the operation and optimizing the overall performance. In fact, in today's IC industry, the interaction between all groups, from device physicists to system designers, is essential to achieving a high performance and a low cost. In this book, we begin with device physics and develop increasingly more complex circuit topologies.

1.5.2 Robust Analog Design

Many device and circuit parameters vary with the fabrication process, supply voltage, and ambient temperature. We denote these effects by PVT and design circuits such that their performance remains in an acceptable range for a specified range of PVT variations. For example, the supply voltage may vary from 2.7 V to 3.3 V and the temperature from 0° to 70°. Robust analog design in CMOS technology is a challenging task because device parameters vary significantly from wafer to wafer...