Book contents
- Frontmatter
- Contents
- Preface
- 1 Introduction to analog CMOS design
- 2 Advanced MOS transistor modeling
- 3 CMOS technology, components, and layout techniques
- 4 Temporal and spatial fluctuations in MOSFETs
- 5 Current mirrors
- 6 Current sources and voltage references
- 7 Basic gain stages
- 8 Operational amplifiers
- 9 Fundamentals of integrated continuous-time filters
- 10 Fundamentals of sampled-data circuits
- 11 Overview of MOSFET models and parameter extraction for design
- Index
- References
5 - Current mirrors
Published online by Cambridge University Press: 17 December 2010
- Frontmatter
- Contents
- Preface
- 1 Introduction to analog CMOS design
- 2 Advanced MOS transistor modeling
- 3 CMOS technology, components, and layout techniques
- 4 Temporal and spatial fluctuations in MOSFETs
- 5 Current mirrors
- 6 Current sources and voltage references
- 7 Basic gain stages
- 8 Operational amplifiers
- 9 Fundamentals of integrated continuous-time filters
- 10 Fundamentals of sampled-data circuits
- 11 Overview of MOSFET models and parameter extraction for design
- Index
- References
Summary
The current mirror is one of the most useful building blocks for analog integrated circuits. It is largely employed as a biasing element and as a load device for amplifier stages. It can also find other uses such as arrays of current sources in D/A converters and current amplifiers in current-mode filters. Basically, a current mirror is a circuit that copies a current flowing through one active device (input) to another active device (output) of a circuit, keeping the output current independent of loading. Current mirrors, from their simplest version to more elaborate circuits, together with analysis of their characteristics, are the subject of this chapter.
A simple MOS current mirror
The ideal current mirror
The simplest configuration of the ideal current mirror is shown in Figure 5.1. Ideally, the current gain AI is independent of the input frequency, and the output current is independent of the output voltage; in other words, the output impedance is infinite. Additionally, the input impedance is zero, i.e., the voltage drop across the input device is zero for any input current. The ideal current mirror is equivalent to a two-port current-controlled current source having a common terminal that connects the input and output ports.
In the section that follows, we will present a first-order analysis of the current mirror implemented with a pair of MOS transistors.
- Type
- Chapter
- Information
- CMOS Analog Design Using All-Region MOSFET Modeling , pp. 177 - 198Publisher: Cambridge University PressPrint publication year: 2010