A true low voltage class-ab current mirror



Similar documents
Laboratory 4: Feedback and Compensation

Current-Controlled Slew-Rate Adjustable Trapezoidal Waveform Generators for Low- and High-Voltage Applications

Efficient Interconnect Design with Novel Repeater Insertion for Low Power Applications

Op-Amp Simulation EE/CS 5720/6720. Read Chapter 5 in Johns & Martin before you begin this assignment.

Baseband delay line QUICK REFERENCE DATA

EECS 240 Topic 7: Current Sources

TDA W Hi-Fi AUDIO POWER AMPLIFIER

LM386 Low Voltage Audio Power Amplifier

Use and Application of Output Limiting Amplifiers (HFA1115, HFA1130, HFA1135)

TS321 Low Power Single Operational Amplifier

CHARGE pumps are the circuits that used to generate dc

Harmonics and Noise in Photovoltaic (PV) Inverter and the Mitigation Strategies


Homework Assignment 03

PIN CONFIGURATION FEATURES ORDERING INFORMATION ABSOLUTE MAXIMUM RATINGS. D, F, N Packages

Application Note SAW-Components

AN-837 APPLICATION NOTE

ISSCC 2003 / SESSION 13 / 40Gb/s COMMUNICATION ICS / PAPER 13.7

TDA W Hi-Fi AUDIO POWER AMPLIFIER

Design and analysis of flip flops for low power clocking system

100V - 100W DMOS AUDIO AMPLIFIER WITH MUTE/ST-BY THERMAL SHUTDOWN STBY-GND

Fundamentals of Microelectronics

LM1084 5A Low Dropout Positive Regulators

CHAPTER 10 OPERATIONAL-AMPLIFIER CIRCUITS

DATA SHEET. TDA8560Q 2 40 W/2 Ω stereo BTL car radio power amplifier with diagnostic facility INTEGRATED CIRCUITS Jan 08

L4970A 10A SWITCHING REGULATOR

What Does Rail-to-Rail Operation Really Mean?

Digital to Analog Converter. Raghu Tumati

Fully Differential CMOS Amplifier

S. Venkatesh, Mrs. T. Gowri, Department of ECE, GIT, GITAM University, Vishakhapatnam, India

CAN Bus Transceivers Operate from 3.3V or 5V and Withstand ±60V Faults

1ED Compact A new high performance, cost efficient, high voltage gate driver IC family

ENEE 307 Electronic Circuit Design Laboratory Spring A. Iliadis Electrical Engineering Department University of Maryland College Park MD 20742

Design of a Fully Differential Two-Stage CMOS Op-Amp for High Gain, High Bandwidth Applications

RF data receiver super-reactive ASK modulation, low cost and low consumption ideal for Microchip HCS KEELOQ decoder/encoder family. 0.

Programmable Single-/Dual-/Triple- Tone Gong SAE 800

CMOS, the Ideal Logic Family

COMMON-SOURCE JFET AMPLIFIER

PAM8403. Description. Pin Assignments. Features. Applications. Typical Applications Circuit. A Product Line of. Diodes Incorporated

DESIGNING high-performance analog circuits is becoming

Small Signal Analysis of a PMOS transistor Consider the following PMOS transistor to be in saturation. Then, 1 2

MITSUBISHI RF MOSFET MODULE RA07H4047M

LM2576R. 3.0A, 52kHz, Step-Down Switching Regulator FEATURES. Applications DESCRIPTION TO-220 PKG TO-220V PKG TO-263 PKG ORDERING INFORMATION

Understanding the Terms and Definitions of LDO Voltage Regulators

TS34119 Low Power Audio Amplifier

SIGNAL GENERATORS and OSCILLOSCOPE CALIBRATION

RLC Resonant Circuits

VARIABLE-frequency oscillators (VFO s) phase locked

AN1991. Audio decibel level detector with meter driver

LAB 7 MOSFET CHARACTERISTICS AND APPLICATIONS

The CARIOCA Front End Chip for the LHCb muon chambers

unit : mm With heat sink (see Pd Ta characteristics)

LM mW Stereo Cell Phone Audio Amplifier

International Journal of Electronics and Computer Science Engineering 1482

Electronics for Analog Signal Processing - II Prof. K. Radhakrishna Rao Department of Electrical Engineering Indian Institute of Technology Madras

Design of a TL431-Based Controller for a Flyback Converter

CHAPTER 2 POWER AMPLIFIER

CMOS Thyristor Based Low Frequency Ring Oscillator

Description. 5k (10k) - + 5k (10k)

*For stability of the feedback loop, the differential gain must vary as

Wide Band Tunable Filter Design Implemented in CMOS

SG2525A SG3525A REGULATING PULSE WIDTH MODULATORS

Application Note 58 Crystal Considerations with Dallas Real Time Clocks

Designing Stable Compensation Networks for Single Phase Voltage Mode Buck Regulators

TDA4605 CONTROL CIRCUIT FOR SWITCH MODE POWER SUPPLIES USING MOS TRANSISTORS

High Speed, Low Power Monolithic Op Amp AD847

1.1 Silicon on Insulator a brief Introduction

Transistor Amplifiers

Analysis of Common-Collector Colpitts Oscillator

High Common-Mode Rejection. Differential Line Receiver SSM2141. Fax: 781/ FUNCTIONAL BLOCK DIAGRAM FEATURES. High Common-Mode Rejection

RF Power LDMOS Transistors Enhancement--Mode Lateral MOSFETs

Lecture 060 Push-Pull Output Stages (1/11/04) Page ECE Analog Integrated Circuits and Systems II P.E. Allen

On the Design and Characterization of Femtoampere Current-Mode Circuits

Audio Power Amplifier Design Handbook

Reading: HH Sections , (pgs , )

LABORATORY 2 THE DIFFERENTIAL AMPLIFIER

Objectives The purpose of this lab is build and analyze Differential amplifiers based on NPN transistors (or NMOS transistors).

SWITCH-MODE POWER SUPPLY CONTROLLER PULSE OUTPUT DC OUTPUT GROUND EXTERNAL FUNCTION SIMULATION ZERO CROSSING INPUT CONTROL EXTERNAL FUNCTION

ICS SPREAD SPECTRUM CLOCK SYNTHESIZER. Description. Features. Block Diagram DATASHEET

CMOS Power Consumption and C pd Calculation

UNDERSTANDING POWER FACTOR AND INPUT CURRENT HARMONICS IN SWITCHED MODE POWER SUPPLIES

Reducing EMI and Improving Signal Integrity Using Spread Spectrum Clocking

DRM compatible RF Tuner Unit DRT1

DATA SHEET. TDA1518BQ 24 W BTL or 2 x 12 watt stereo car radio power amplifier INTEGRATED CIRCUITS

CO2005: Electronics I (FET) Electronics I, Neamen 3th Ed. 1

A MULTILEVEL INVERTER FOR SYNCHRONIZING THE GRID WITH RENEWABLE ENERGY SOURCES BY IMPLEMENTING BATTERY CUM DC-DC CONERTER

DS2187 Receive Line Interface

Equivalent Circuit. Operating Characteristics at Ta = 25 C, V CC = ±34V, R L = 8Ω, VG = 40dB, Rg = 600Ω, R L : non-inductive load STK4181V

LM833 LOW NOISE DUAL OPERATIONAL AMPLIFIER

Quad, Rail-to-Rail, Fault-Protected, SPST Analog Switches

Transistor Characteristics and Single Transistor Amplifier Sept. 8, 1997

Analysis on the Balanced Class-E Power Amplifier for the Load Mismatch Condition

Loop Stability Analysis Differential Opamp Simulation

Making Accurate Voltage Noise and Current Noise Measurements on Operational Amplifiers Down to 0.1Hz

Selected Filter Circuits Dr. Lynn Fuller

Frequency Response of Filters

Precision Diode Rectifiers

Bipolar Transistor Amplifiers

Transcription:

A true low voltage class-ab current mirror A. Torralba, 1a) R. G. Carvajal, 1 M. Jiménez, 1 F. Muñoz, 1 and J. Ramírez-Angulo 2 1 Departamento de Ingeniería Electrónica, Escuela Superior de Ingenieros, Universidad de Sevilla, Spain. 2 Klipsch School of Electrical and Computer Engineering, New Mexico State University, Las Cruces, NM (USA). a) torralba@gte.esi.us.es Abstract: Class-AB circuits, which are able to deal with currents which are orders of magnitude larger than their quiescent current, are good candidates for low-power analog design. This paper presents a new, simple, class-ab current-mirror, based on the Flipped Voltage Follower [1]. In the authors knowledge this is the first class-ab currentmirror which operates with a supply voltage smaller than two transistor threshold voltages without an additional clock signal or voltage doubler. Experimental results are provided which show proper operation at 1.5 V in a 0.5 µm standard CMOS technology. Keywords: analog CMOS integrated circuits, class-ab current mirrors, low-voltage analog design Classification: Integrated circuits References [1] J. Ramírez-Angulo, R. G. Carvajal, A. Torralba, J. Galan, A. P. Vega-Leal, and J. Tombs, The Flipped Voltage Follower: A useful cell for low-voltage low-power circuit design, Proc. Int. Symp. Circuits Syst., vol. 3, pp. 615 618, 2002. [2] R. Gray and R. G. Meyer, Analysis and Design of Analog Integrated Circuits, New York: John Wiley, 3rd. Ed., 1993. [3] G. Palmisano and S. Pennisi, A true low-voltage CMOS class-ab current mirror, Proc. Int. Symp. Circuits Syst., vol. 4, pp. 249 252, 2000. 1 Introduction The proliferation of portable and mobile devices has made low power a key requirement in electronic designs. In addition, for digital systems, power consumption is tightly related to voltage supply, so that low power digital systems have a low supply voltage. Although different supply voltages can be used for the analog and the digital parts in a mixed signal design, this is not a convenient solution, as special interface circuits between them are required, and it also complicates the (on-chip and off-chip) design and layout 103

of the supply sources. Class-AB circuits are characterized by low quiescent power consumption and high driving capability, taking power from the supply sources only when the load requires it, making class-ab circuits good candidates for low-power analog design. Class-AB current mirrors have been widely used in analog and digital designs. The classical class-ab current mirror is based on a four transistor translinear loop (Figure 1 a) [2] which accurately determines the bias voltage at the input terminal and the quiescent current through transistors M1 to M4. Unfortunately, this circuit requires a high supply voltage, as two gate-to-source voltages (and two current sources) are stacked between the supply rails. In [3], a true low-voltage CMOS class-ab current mirror (Figure 1 b) was proposed. However, this circuit requires a switched capacitor biasing network with a high voltage clock (the authors claimed that, for low voltage operation, a clock booster could be necessary to properly drive the switches in the biasing network). Fig. 1. a) Conventional class-ab current mirror. b) Lowvoltage class-ab current mirror in reference [3]. 2 Proposed Current Mirror Figure 2 shows the proposed class-ab current mirror. Suppressing transistors M 1,M 5 and M 6 in the circuit of Figure 2, the resulting circuit constitutes a low-voltage current mirror based on the FVF [1]. To be able to copy a large positive input current I in =I MAX, the biasing current sources I b should be greater or equal than I MAX, precluding a class-ab operation. However, transistor M 1 is able to sink a large current, allowing I b to have a small value. The current through transistor M 1 can be copied to the output by means of the current mirror M 5 M 6. The resulting circuit is a low-voltage class-ab current mirror. 104

Fig. 2. Proposed class-ab current mirror. Assuming a capacitive load and an ideal input voltage source, the stability of the proposed current-mirror is determined by the stability of the FVF section [1]. If the current source I b is implemented by means of a simple current mirror, the stability condition for the FVF section leads to C X /C Y < g m2 /(4g m3 ), where C X and C Y are the equivalent capacitances at nodes X and Y, and g mi is the small-signal transconductance of transistor M i. This condition is easily achieved by proper sizing of the relative W/L ratio of transistors M 2 and M 3. Obviously, the output resistance of the circuit in Figure 2 can be increased by means of cascode transistors with normal or active biasing. These techniques are proposed elsewhere and we will not insist on them here. 3 Experimental results The circuit in Figure 2 has been designed using a 0.5 µm CMOS standard technology. Transistor sizes and biasing currents are shown in the figure. Figure 3 a shows the chip microphotograph. The samples were measured using a 10 KΩ resistor tied to 0.75 V in parallel with an equivalent 18 pf capacitor. Figure 3 b shows the transient response for a 1 MHz, 100 µa peak-topeak sinusoidal input signal, showing that the current mirror is able to copy alternate currents with a maximum value which is one order of magnitude superior to its quiescent current. The measured THD for a 100 khz, 100 µa peak-to-peak sinusoidal input signal was 61 db, dominated by the third harmonic (Figure 3 c). The 3 db frequency was located beyond 10 MHz. 105

Fig. 3. a) Chip microphotograph. b)transient response for the proposed class-ab current mirror (1 MHz, 100 µa peak sinusoidal input signal). c) Output signal spectrum for a 100 khz, 100 µa peak-topeak sinusoidal input signal. 106

4 Conclusion A new simple low-voltage class-ab current mirror has been shown, based on the Flipped Voltage Follower cell. Experimental results show that this circuit is able to copy currents up to one order of magnitude superior to its biasing current with a 1.5 V supply using a 0.5 µm CMOS process. The current mirror presents a good linearity with a large bandwidth. 5 Acknowledgments Authors would like to acknowledge financial support from the Spanish CI- CYT under projects TIC2002-04323-C03-01 and TIC2003-07307-C02-01. 107

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information