CHAPTER 4 LARGE SIGNAL S-PARAMETERS

Similar documents
915 MHz Power Amplifier. EE172 Final Project. Michael Bella

Design and Performance Analysis of 1.8 GHz Low Noise Amplifier for Wireless Receiver Application

Silicon-Carbide High Efficiency 145 MHz Amplifier for Space Applications

Application Note 5057

(a) Current-controlled and (b) voltage-controlled amplifiers.

Design and simulation of Parallel circuit class E Power amplifier

T he noise figure of a

A Simulation-Based Flow for Broadband GaN Power Amplifier Design

Designing a 960 MHz CMOS LNA and Mixer using ADS. EE 5390 RFIC Design Michelle Montoya Alfredo Perez. April 15, 2004

Basic Electronics Prof. Dr. Chitralekha Mahanta Department of Electronics and Communication Engineering Indian Institute of Technology, Guwahati

High Gain Low Noise Amplifier Design Using Active Feedback

Direct-Conversion I-Q Modulator Simulation by Andy Howard, Applications Engineer Agilent EEsof EDA

IENGINEERS-CONSULTANTS QUESTION BANK SERIES ELECTRONICS ENGINEERING 1 YEAR UPTU ELECTRONICS ENGINEERING EC 101 UNIT 3 (JFET AND MOSFET)

MEASUREMENT OF LARGE SIGNAL DEVICE INPUT IMPEDANCE DURING LOAD PULL

Application Note 1285

Recent Advances in the Measurement and Modeling of High-Frequency Components

6. Field-Effect Transistor

Basic Electronics Prof. Dr. Chitralekha Mahanta Department of Electronics and Communication Engineering Indian Institute of Technology, Guwahati

A Survey of Load Pull Simulation Capabilities How do they Help You Design Power Amplifiers?

Microwave Oscillator Design. Application Note A008

The Method of Measuring Large-Signal S-Parameters of High Power Transistor With Normal Condition

Application Note 1373

Electronic PRINCIPLES

Low Noise Amplifier for 3.5 GHz using the Avago ATF Low Noise PHEMT. Application Note 1271

Case Study: Amp5. Design of a WiMAX Power Amplifier. WiMAX power amplifier. Amplifier topology. Power. Amplifier

Negative Input Resistance and Real-time Active Load-pull Measurements of a 2.5GHz Oscillator Using a LSNA

BIAS DEPENDANT NOISE WAVE MODELLING PROCEDURE OF MICROWAVE FETS

QPR No. 93 SOLID-STATE MICROWAVE ELECTRONICS" IV. Academic and Research Staff. Prof. R. P. Rafuse Dr. D. H. Steinbrecher.

IVCAD VNA Base Load Pull with Active/Hybrid Tuning. Getting Started v3.5

Electron Devices and Circuits

Pulsed IV analysis. Performing and Analyzing Pulsed Current-Voltage Measurements PULSED MEASUREMENTS. methods used for pulsed

High-Frequency Transistor Primer Part IV. GaAs FET Characteristics

EE 330 Laboratory 7 MOSFET Device Experimental Characterization and Basic Applications Spring 2017

The Design & Simulation of LNA for GHz Using AWR Microwave Office

Microelectronics Exercises of Topic 5 ICT Systems Engineering EPSEM - UPC

A new nonlinear HEMT model allowing accurate simulation of very low IM 3 levels for high-frequency highly linear amplifiers design

1 of 7 12/20/ :04 PM

LABORATORY #3 QUARTZ CRYSTAL OSCILLATOR DESIGN

LINEARIZED CMOS HIGH EFFECIENCY CLASS-E RF POWER AMPLIFIER

Highly Linear GaN Class AB Power Amplifier Design

Application Note 5379

Load Pull Validation of Large Signal Cree GaN Field Effect Transistor (FET) Model

KOM2751 Analog Electronics :: Dr. Muharrem Mercimek :: YTU - Control and Automation Dept. 1 6 FIELD-EFFECT TRANSISTORS

Application Note 1299

University of Pittsburgh

High Efficiency Classes of RF Amplifiers

DETECTOR. Figure 1. Diode Detector

Electronics Prof. D. C. Dube Department of Physics Indian Institute of Technology, Delhi

This novel simulation method effectively analyzes a 2-GHz oscillator to better understand and optimize its noise performance.

A New Topology of Load Network for Class F RF Power Amplifiers

Application Note A008

RF2334. Typical Applications. Final PA for Low Power Applications Broadband Test Equipment

ATF High Intercept Low Noise Amplifier for the MHz PCS Band using the Enhancement Mode PHEMT

Design Challenges and Performance Parameters of Low Noise Amplifier

DOUBLE-SIDEBAND MIXER CIRCUITS

A High Efficiency and Wideband Doherty Power Amplifier for 5G. Master s thesis in Wireless, Photonics and Space Engineering HALIL VOLKAN HUNERLI

RF3375 GENERAL PURPOSE AMPLIFIER

Using a Linear Transistor Model for RF Amplifier Design

Chapter 8. Field Effect Transistor

Simulations of High Linearity and High Efficiency of Class B Power Amplifiers in GaN HEMT Technology

4 Transistors. 4.1 IV Relations

Simulation of GaAs MESFET and HEMT Devices for RF Applications

UNIVERSITY OF NORTH CAROLINA AT CHARLOTTE. Department of Electrical and Computer Engineering

6.976 High Speed Communication Circuits and Systems Lecture 8 Noise Figure, Impact of Amplifier Nonlinearities

The Design of A 125W L-Band GaN Power Amplifier

Digital Electronics. By: FARHAD FARADJI, Ph.D. Assistant Professor, Electrical and Computer Engineering, K. N. Toosi University of Technology

Surface Mount Package SOT-343. Pin Connections and Package Marking. 4Px GATE

INTRODUCTION TO ELECTRONICS EHB 222E

Field - Effect Transistor

Three Terminal Devices

FET. FET (field-effect transistor) JFET. Prepared by Engr. JP Timola Reference: Electronic Devices by Floyd

Common-Source Amplifiers

The New Load Pull Characterization Method for Microwave Power Amplifier Design

Field Effect Transistors

EE432/532 Microwave Circuit Design II: Lab 1

EE70 - Intro. Electronics

TSEK03 LAB 1: LNA simulation using Cadence SpectreRF

Name: Date: Score: / (75)

Chapter 5. Operational Amplifiers and Source Followers. 5.1 Operational Amplifier

SAS-2 Transmitter/Receiver S- Parameter Measurement (07-012r0) Barry Olawsky Hewlett Packard (1/11/2007)

Design of High Efficiency Class E Amplifiers

Homework Assignment 07

CHAPTER 3 CMOS LOW NOISE AMPLIFIERS

Application Note 1320

Leveraging High-Accuracy Models to Achieve First Pass Success in Power Amplifier Design

Design and Layout of a X-Band MMIC Power Amplifier in a Phemt Technology

Experiment 5 Single-Stage MOS Amplifiers

ATF-531P8 900 MHz High Linearity Amplifier. Application Note 1372

Gechstudentszone.wordpress.com

Microelectronics Circuit Analysis and Design

Load-Pull Analysis Using NI AWR Software

JFET Noise. Figure 1: JFET noise equivalent circuit. is the mean-square thermal drain noise current and i 2 fd

Phy 335, Unit 4 Transistors and transistor circuits (part one)

Many applications. Mismatched Load Characterization for High-Power RF Amplifiers PA CHARACTERIZATION. This article discusses the

FET, BJT, OpAmp Guide

ECE 255, MOSFET Basic Configurations

Each question is worth 2 points, except for problem 3, where each question is worth 5 points.

ETI , Good luck! Written Exam Integrated Radio Electronics. Lund University Dept. of Electroscience

ECE 3274 MOSFET CD Amplifier Project

Efficiently simulating a direct-conversion I-Q modulator

Transcription:

CHAPTER 4 LARGE SIGNAL S-PARAMETERS 4.0 Introduction Small-signal S-parameter characterization of transistor is well established. As mentioned in chapter 3, the quasi-large-signal approach is the most accurate way to measure the large-signal S-parameters for transistors, especially S 1 S. Attempts to obtain accurate large-signal S-parameters for transistors using the direct extension of small-signal measurements methods have been of limited success, especially in cases where the non-linearity is severe such as in class-c. Of course one of the main advantages of the direct extension of the small-signal measurement method is its simplicity. The objective of this chapter is to study the design accuracy of class-a power amplifier based on small-signal S-parameters. 40

41 4.1 Large-Signal S-Parameters Measurement The MESFET transistor used in this work is the ATF-46100, manufactured by Hewlett Packard (HP). The ATF-46100 is a gallium arsenide Schottky-barrier-gate field effect transistor designed for medium power, and linear amplification. The simulation shown in this work is obtained using the ATF-46100 s EEFET3 nonlinear model [HP Advance Design System Manual]. 4.1.1 Large-Signal S-parameters for Class A As mentioned earlier, the class-a amplifier has a higher linearity than the other classes of amplifiers. This makes the design of the large signal class-a amplifier possible using the small-signal S-parameters. However, for class-ab, B, or C, the small-signal S- parameters are not suitable for design purposes. The DC Simulation component of the HP-ADS is used to determine the proper biasing point. Figure.4.1 shows the dc simulation setup. The curve tracer for the ATF-46100 as shown in Fig.4. is obtained by varying V GS and V DS. From Fig.4., for the ATF-46100 to be in Class-A, V GS and V DS are chosen to be 3.5 V and 6 V, respectively. The next step is to find the dependence of the S-parameters on the input power. Figure.4.3 shows the S-parameters simulation setup for the ATF- 46100. Figure.4.4 shows that over wide range of power, with exception of the magnitudes of S 1 and S, the S-parameters are not a strong function of the applied power. Also, the large-signal S-parameters start deviating from the small-signal S- parameters when the applied power exceeded a certain level (P in =10 dbm for 50Ω load).

Figure 4.1 ATF-46100 DC simulation setup. 4

Figure 4. DC curve tracer for the ATF-46100 43

Figure 4.3 S-parameters simulation setup for the ATF-46100. 44

45 For every load value there is an input power level above, which the large signal S-parameters will start to deviate way from the small signal S-parameters. The power gain can be used as an indicator for the linearity and, in consequently, the accuracy of the design using the small-signal S-parameters at the desired input power level. Figure.4.5 shows the simulation setup used to calculate the power gain of the transistor ATF-46100 versus the input power for different load values. One db, and 0. db compression points for the gain at different input power levels are shown in figures.4.6, and 4.7 respectively. Before the small-signal S-parameter technique can be used in designing a large signal amplifier, its limitation needs to be known. The accuracy required for the design can be used to find this limitation. Knowing the acceptable gain compression value (XdB) is the first step in the design. The device data sheet showing the XdB compression gain versus the input power is needed. One important need to be noticed is that the XdB compression gain varies with the biasing point. Therefore, the data sheet should include the XdB compression gain at the desired input power and biasing point. The next step is to find the proper load and source impedance. This can be done based on the operating power gain G P procedure.

46 Figure 4.4 (a) S-parameters in db vs. the input power.

47 Figure 4.4 (b) Angle of S-parameters in degree vs. the input power.

48 Figure 4.5 Harmonic balance simulation setup for the gain.

49 13 dbm.

. 50

51 The operating power gain G P is defined as the ratio of the power delivered to the load to the amplifier input power. G P can be defined in terms of the S-parameters, as shown in Equation 4.1 [G. Gonzalez, 1984]. G P S1 = S Γ 11 L 1 1 S Γ ( 1 Γ ) L L 1 S. (4.1) Different values of G P can be obtained; every value forms a circle in the Smith chart. Equations 4. and 4.3 give the radius and center of the constant operating power gain circles, respectively [G. Gonzalez, 1984]: Γ L [1 K S1 S R = 1+ g 1 P g P ( S + S 1 S 1 ) g ] 1/ P (4.) C = 1+ g P g P ( S C ) (4.3) Where, g P = 1 S ( 1 Γ ) L Γ L S 11 Γ L (4.4) C = S 11 S. (4.5)

5 For a specific value of G P, the operating gain circle can be drawn using Equations 4. and 4.3. The proper load is obtained using the data sheet and G P circle. The maximum output power can be obtained with the conjugate matching at the input. As mentioned earlier, the XdB compression gain varies with the biasing point. Although the XdB compression gain data sheet allows the use of small- signal S- parameters to the limit, the XdB compression gain information needs to be provided at different biasing points. An interesting relation between the XdB compression gain curve and the drain biasing voltage (V DS ) can be noticed by comparing Figures.4.6 and 4.7, where V DS is 6V, with Fig.4.8, where V DS is 7V. Varying V DS affects the XdB compression gain of the amplifier with any load by the same amount. This observation will reduce the information needed. Therefore, knowing the XdB compression gain at a certain value of V DS, and the effect of the change of V DS on the XdB compression gain with 50 Ω load is enough to obtain the XdB compression gain at other V DS values.

53

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback