A/D Converter Calculations for RF Applications

henerychan

hese equations predict the RF electrical performance of Analog-to-Digital Converters. Since A/D converters are often the last stage in a receiver chain, it is extremely useful to be able to predict the contribution for noise figure, jitter, dynamic range, etc., since those values are needed for a complete cascade analysis. Be sure to note units both for the input parameters and for the equations, or you will end up with really bad results.
An A/D Converter Calculator is included in RF Cafe Calculator Workbook for FREE.
A/D input full-scale power equation   A/D input full-scale power
Power of one "q" level equation  Power of one "q" level
Dynamic range equation  Dynamic range
A/D input full-scale rms voltage equation  A/D input full-scale rms voltage
One “q” level at peak voltage equation  One “q” level at peak voltage
One “q” level at peak voltage in rms equation  Same as above, in rms
Voltage level at “n” quantization (“q”) levels equation  Voltage level at “n” quantization (“q”) levels
Voltage level at “n” quantization (“q”) levels in rms equation  Same as above, in rms
Power of “n” quantization (“q”) levels equation  Power of “n” quantization (“q”) levels
Input dynamic range for “N” bits equation  Input dynamic range for “N” bits
Jitter power equation  Jitter power
Signal-to-noise ratio equation  Signal-to-noise ratio

Variable        Definition
VFS        Full-scale peak input voltage
Jitter        Aperture jitter time
"q" Levels        Number of "q" levels
FAnalog        Sampled analog input signal frequency
PFS        Full-scale input power
P1q        Power of one "q" level
DR        Dynamic range
VFS        Full scale input voltage
V1q        Input voltage at one "q" levels
Vnq        Input voltage at "n" quantization ("q") levels
# of bits        Total number of bits
PJitter        Power in aperture jitter
SNR        Signal-to-noise ratio
Related Pages on RF Cafe
- A/D Converter Calculations for RF Applications
- A/D & D/A Converter Vendors

henerychan

A/D & D/A Converter Design
These websites contain information relating to A/D and D/A converter design including white papers, datasheets, tutorials, and online write-ups.

A/D & D/A Manufacturers & Services

The ABCs of ADCs | national.com/appinfo/adc/files/ABCs_of_ADCs.pdf
A nice application note by National Semiconductor that covers parameters needed for RF systems.
A Cascaded Sigma–Delta Pipeline A/D Converter with 1.25 MHz Signal Bandwidth and 89 dB SNR | sscs.org/jssc/97bp.pdf
Article by Todd L. Brooks, David H. Robertson, Daniel F. Kelly, Anthony Del Muro, and Stephen W. Harston.
A/D and D/A conversion of PC graphics and component video signals, Part 1: Hardware | focus.ti.com/lit/an/slyt138/slyt138.pdf
By Bart DeCanne, Texas Instruments Incorporated.
A/D Converters for Telecommunications | imse.cnm.es/esd-msd/WORKSHOPS/ETHZ-1/presentations.htm
Workshop presentations.
A/D and D/A Design | circuitsage.com/a2dd2a.html
Links to software, design articles, books on general analog design and layout, from Circuit Sage.
A/D, D/A Conversion for HDTV | commsdesign.com/main/multsupp/0005/0005hdtv.htm
Article from CommsDesign, by Bart DeCanne.
ADC/DAC Design IP | engr.sjsu.edu/dparent/ICGROUP/a2d5bit.pdf
From San Jose State University, Electrical Engineering Department.
Analog I/O Functionality | omega.com/literature/transactions/volume2/analogio2.html | 800-848-4286 | Stamford, CT
A/D conversion literature by Omega Engineering.
Analog-to-Digital Converter | answers.com/topic/analog-to-digital-converter
Information from answers.com.
Analog-to-Digital Converter Design Guide | microchip.com/downloads/en/DeviceDoc/21841A.pdf
High-Performance, Stand-Alone A/D Converters for a Variety of Embedded Systems Applications - by Microchip, in .PDF format.
Analog to Digital Converter Resolution Extension Using a Pressure Sensor | freescale.com/files/sensors/doc/app_note/AN1100.pdf
Application note from Freescale Semiconductor.
Audio A/D Conversion with an Asynchronous Decimation Filter | cirrus.com/en/pubs/appNote/AN270REV1.pdf
Application note from Cirrus Logic, in .PDF format.
Calculating the Error Budget in Precision Digital-to-Analog Converter (DAC) Applications | pdfserv.maxim-ic.com/en/an/AN4300.pdf
This application note analyses the parameters that affect the errors in precision digital-to-analog converter (DAC) applications. From Maxim Integrated Products, by David Fry.
D/A-Converter ASIC Uses Stochastic Logic | edn.com/archives/1996/102496/di_05.htm
Article by J Quero, C Janer, J Ortega, and L Franquelo, University of Seville, Seville, Spain.
D/A Converters | analog.com/en/technical-library/application-notes/design-center/products/digital-to-analog-converters/da-converters/resources/index.html
Application notes in .PDF format from Analog Devices.
Data Conversion Calculator | national.com/appinfo/adc
A/D converters - From National Semiconductor Corporation.
Digital-Analog Conversion | faqs.org/docs/electric/Digital/DIGI_13.html
Lessons In Electric Circuits - free series of textbooks on the subjects of electricity and electronics by Tony R. Kuphaldt.
Digital to Analog Converters | focus.ti.com/analog/docs/analogtechdoc.tsp?familyId=392&navSection=app_notes&templateId=4
Application notes from Texas Instruments.
Good bones: Architecture Counts in Converter Selection | eetimes.com/news/design/showArticle.jhtml?articleID=166401393
EE Times article by Skip Osgood.
MAX1407 Complete Data Acquisition System Simplifies Your System Designs | pdfserv.maxim-ic.com/en/an/AN830.pdf | 408-737-7600 | Sunnyvale, CA
Application note from Maxim Integrated Products.
Setup and Hold Times for High-Speed Digital-to-Analog Converters (DACs) Demystified | pdfserv.maxim-ic.com/en/an/AN4053.pdf
This application note defines setup and hold times for high-speed digital-to-analog converters (DACs) and identifies their proper interpretation. From Maxim Integrated Products.

henerychan

Technical Abbreviations and Acronyms
Where would the government, business, medicine, the technical world, an the military be without an ample lexicon of abbreviations and acronyms? The government and military have entire departments dedicated to creating clever (or not so clever) acronyms for programs and systems.

While this list is by no means exhaustive, it does include many of the abbreviations and acronyms that I have run up against in my career. If you have any that should be added, please send me an e-mail.
A        Ampere
AC        Alternating Current
ACK        Acknowledge
ACIA        Asynchronous Communication Interface Adapter
ACL        Advanced CMOS Logic
A/D        Analog to Digital
AF        Audio Frequency
AFC        Automatic Frequency Control
AGC        Automatic Gain Control
AH        Ampere-Hour
AI        Artificial Intelligence
AKA        Also Known As
ALC        Automatic Level Control
ALU        Arithmetic Logic Unit
A/N        Alphanumeric
ANSI        American National Standards Institute
ARRL        American Radio Relay League
AS        Advanced Schottky
ASCII        American Standard Code for Information Interchange
ASIC        Application Specific Integrated Circuit
ASK        Amplitude Shift Keying
ATC        Air Traffic Control
AV        Audio/Visual
AVC        Automatic Volume Control
Back to Top
B
BASIC        Beginners All-purpose Symbolic Instruction Code
BBD        Bucket Brigade Device
BCE        Binary Coded Decimal
BEV        Billion Electron Volts
BIFET        Bipolar Field-Effect Transistor
BJT        Bipolar Junction Transistor
BNC        Bayonet Neill-Concelman (connector)
BPI        Bits Per Inch
BPS        Bits Per Second
BTW        By The Way
B&W        Black & White
BW        BandWidth
Back to Top
C
C        Capacitance
CAD        Computer Assisted Design or Computer Aided Drafting
CADA        Computer Assisted Design and Analysis
CADD        Computer Assisted Design and Development
CAE        Computer Assisted Engineering
CAM        Computer Assisted Manufacturing
CAN        CANcel
CAS        Column Address Strobe
CATV        CAble TeleVision
CB        Citizens Band
CBI        Complementary BInary or Computer Based Instruction
CBT        Computer Based Training
CC        Constant Current
CCD        Charge Coupled Device
CCITT        International Telegraphy and Telephony Consultative Committee
CCTV        Closed Circuit TeleVision
CCW        Counter Clock Wise
CD        Compact Disk
CD-I        Compact Disk - Interactiv
CDR        Compact Disk Recordable
CDROM        Compact Disk Read Only Memory
CDRW        Compact Disk ReWriteable
CECL        Cascode Emitter Coupled Logic
CEMA        Consumer Electronics Manufacturers Association
CEMF        Counter ElectroMotive Force
CERDIP        CERamic Dual Inline Package
CES        Consumer Electronics Show
CF        Center Frequency or Cubic Feet
CFM        Cubic Feet per Minute
CIM        Computer Integrated Manufacturing
CISC        Complex Instruction Set Computer
CL        Current Loop
CMOS        Complementary Metal Oxide Semiconductor
CP/M        Control Program for Microcomputers
CPI        Characters Per Inch
CPU        Central Processing Unit
CRC        Cyclic Redundancy Check
CRT        Cathode Ray Tube
CS        Control Strobe (logic signal)
CSA        Canadian Standards Association
CTC        Counter/Timer Circuit
CTS        Clear To Send (protocol signal)
CV        Constant Voltage
CVT        Constant Voltage Transformer
CW        ClockWise, Continuous Wave, Carrier Wave (for old-timers)
CYMK        Cyan Yellow Magenta blacK
Back to Top
D
D/A        Digital to Analog
DAC        Digital to Analog Converter or Data Acquisition and Control
DARPA        Defense Advanced Research Projects Agency
DAV        Data AValiable or DatA Valid
DB        Data Base
dB        DeciBel
dBA        DeciBel - Adjusted
dBK        DeciBel (1 kilowatt ref)
DBM        Data Base Management
dBm        DeciBel (1 milliwatt ref)
dBV        DeciBel (1 volt ref)
dBX        DeciBel - above reference
DC        Direct Current
DCD        Data Carrier Detect (protocol signal)
DDS        Direct Digital Synthesis
DES        Data Encryption Standard
DIAC        Bilateral trigger diode
DIL        Dual In Line
DIN        Deutsche Industrie Normenausschuss
DIP        Dual Inline Package
DLC        Dual Layer Capacitor
DMA        Direct Memory Access
DMM        Digital MultiMeter
DOD        Department of Defense
DOS        Disk Operating System
DOT        Department of Transportation
DP        Data Processing
DPDT        Double Pole Double Throw
DPI        Dots Per Inch
DPST        Double Pole Single Throw
DRAM        Dynamic Random Access Memory
DS        Data Strobe
DSO        Digital Storage Oscilloscope
DSP        Digital Signal Processing
DSR        Data Set Ready
DTL        Diode Transistor Logic
DTMF        Dual Tone Multi Frequency
DTR        Data Terminal Ready
DVM        Digital Volt-Meter
Back to Top
E
E2PROM        Electrically Erasable Programmable Read Only Memory
EAROM        Electrically Alterable Read Only Memory
EBCDIC        Extended Binary Coded Decimal Interchange Code
ECC        Error Checking and Correction
ECL        Emitter Coupled Logic
EEPROM        Electrically Erasable Programmable Read Only Memory
EGA        Enhanced Graphics Adapter
EHF        Extremely High Frequency
EIA        Electronics Industries Association
EL        ElectroLuminescent
ELF        Extremely Low Frequency
EMF        ElectroMotive Force
EMI        ElectroMagnetic Interference
EMP        ElectroMagnetic Pulse
ENIAC        Electronic Numerical Integrator and Calculator
EOT        End Of Transmission
EPLD        Electrically Programmable Logic Device
EPROM        Electrically Programmable Read Only Memory
EQ        EQualizer
ESA        European Space Agency
ESD        Electrostatic Sensitive Device or ElectroStatic Discharge
ESR        Equivalent Series Resistance
EV        Electron Volt
Back to Top
F
F        Farad
FAA        Federal Aviation Administration
FAST        Fairchild Advanced Schottky
FAX        Facsimile
FCC        Federal Communications Commission
FDC        Floppy Disk Controller
FDX        Full DupleX
FET        Field Effect Transistor
FF        Flip Flop
FFT        Fast Fourier Transform
FIFO        First In First Ou
FILO        First In Last Out
FM        Frequency Modulation
FORTRAN        FORmula TRANslato
FP        Floating Point
FPGA        Field Programmable Gate Array
FPLA        Field Programmable Logic Array
FPP        Floating Point Processor
FPU        Floating Point Unit
FSK        Frequency Shift Keying
FTP        File Transfer Protocol
FUBAR        Fouled Up Beyond Any Repair
FVC        Frequency to Voltage Converter
Back to Top
G
GA        Gate Array
GAL        Generic Array Logic
GCS        Gate Controlled Switch
GFCI        Ground Fault Circuit Interrupter
GFI        Ground Fault Interrupter
GFLOPS        Billions of FLOating Point operations per Second
GIGO        Garbage In Garbage Out
GND        GrouND
GPIB        General Purpose Interface Bus (evolved from HPIB by Hewlett Packard)
GPS        Global Positioning System
GUI        Graphical User Interface (software)
Back to Top
H
HAL        Hardwired Array Logic
HC        High speed CMOS
HCT        High speed CMOS with TTL thresholds
HD        High Density
HDC        Hard Disk Controller
HDTV        High Definition TeleVision
HDX        Half DupleX
HER        High Efficiency Red
HET        Heterodyne
HF        High Frequency
HFS        Hierarchical File System
HIC        Hybrid Integrated Circuit
HP        Hewlett Packard or Horse Power
HPIB        Hewlett Packard Interface Bus
HPIL        Hewlett Packard Interface Loop
HTL        High Threshold Logic
HVDC        High Voltage Direct Current
HVPS        High Voltage Power Supply
Hz        Hertz (frequency in cycles per second)
Back to Top
I
I2ICE        Integrated Instrumentation and In Circuit Emulation
I2R        Current (I) squared x Resistance
IA        Instrumentation Amplifier
IC        Integrated Circuit
ICE        In Circuit Emulation
IEEE        Institute of Electrical and Electronics Engineers
IF        Intermediate Frequency
IGFET        Insulated Gate Field Effect Transistor
IMHO        In My Humble Opinion
IMNHO        In My Not so Humble Opinion
I/O        Input/Output
IOP        Input/Output Processor
IP        Interface Processor or Internet Protocol
IR        Current-Resistance or InfraRed
IRED        InfraRed Emitting Diode
IRLED        InfraRed Light Emitting Diode
IRQ        Interrupt ReQuest
ISA        Instrument Society of America
ISN        Information Systems Network
ISO        In Search Of
Back to Top
J
JEDEC        Joint Electron Device Engineering Council
JFET        Junction Field Effect Transistor
JIS        Japanese Industrial Standard
JPL        Jet Propulsion Laboratory
JUG        Joint Users Group
Back to Top
K
k        Kilo (1000 units)
kA        Kilo Ampere (1000 A)
kbPS        Kilo bits Per Second
kEV        Kilo Electron Volts
kHz        Kilo Hertz (1000 cycles per second)
kVA        Kilo Volt Amperes
kW        Kilo Watts
kWH        Kilo Watt Hours
Back to Top
L
L        Inductance
L2FET        Logic Level Field Effect Transistor
LAN        Local Area Network
LASCR        Light Activated Silicon Controlled Rectifier
LASER        Light Amplification by Stimulated Emission of Radiation
LC        Inductance and Capacitance
LCD        Liquid Crystal Display
LCM        Least/Lowest Common Multiple
LD        Line Driver
LED        Light Emitting Diode
LF        Low Frequency
LIFO        Last In First Out
LISP        LISt Processing
LLFET        Logic Level Field Effect Transistor
LO        Local Oscillator
LORAN        LOng RAnge Navigation
LP        Low Pass
LPC        Linear Predictive Coding
LPM        Lines Per Minute
LPT        Line PrinTer
LSB        Least Significant Bit or Lower SideBand
LSD        Least Significant Digit
LSI        Large Scale Integration
LUT        Look Up Table
LW        Long Wave
Back to Top
M
mAH        milliAmpere-Hour
MB        MegaBytes
Mb        Megabits
MBPS        Million Bytes Per Second
MbPS        Million bits Per Second
MCA        Micro Channel Architecture
MCU        Micro Computer Unit
MDAC        Multiplying Digital to Analog Converter
MECL        Motorola Emitter Coupled Logic
MFLOPS        Millions of FLOating Point operations per Second
MFM        Modified Frequency Modulation
MHz        MegaHertz
MIDI        Music Instrument Digital Interface
MIL        MILitary
MILSPEC        MILitary SPECification
MIPS        Millions of Instructions Per Second
MMU        Memory Management Unit
MO        Master Oscillator
MOS        Metal Oxide Semiconductor
MOSFET        Metal Oxide Semiconductor Field Effect Transistor
MOV        Metal Oxide Varistor
MPU        Main Processing Unit
MR        Magnetic Resonance
MSDOS        MicroSoft Disk Operating System
MSB        Most Significant Bit
MSD        Most Significant Digit
MSDS        Material Safety Data Sheet
MSI        Medium Scale Integration
MTBF        Mean Time Between Failures
MTS        Multichannel Television Sound
MUF        Maximum Useable Frequency
MUX        Multiplexer
Back to Top
N
NASA        National Aeronautics and Space Administration
NC        Not Connected or Normally Closed
NCO        Numerically Controlled Oscillator
NEDA        National Electronics Distributors Association
NEG        NEGative
NEMA        National Electrical Manufacturers Association
nF        NanoFarad
NFS        Network File Server
NiCad        Nickel Cadmium
NiMH        Nickel Metal Hydride
NMOS        N-channel Metal Oxide Semiconductor
NMR        Nuclear Magnetic Resonance
NO        Normally Open
NOAA        National Oceanic and Atmospheric Administration
NORAD        NORth American Defense
NPN        Negative Positive Negative
NPO        Negative Positive 0 temperature coefficient
NPR        Noise Power Ratio
NRZ        Non Return to Zero
NRZI        Non Return to Zero Invert
NSB        National Science Board
NSF        National Science Foundation
NSPE        National Society of Professional Engineers
NT        Network Terminator
NTC        Negative Temperature Coefficient
NTSC        National Television Systems Committee
Back to Top
O
OBTW        Oh, By The Way
OC        Open Collector
OCR        Optical Character Recognition
OEM        Original Equipment Manufacturer
OO        Object Oriented
OOP        Object Oriented Programming
OPAMP        OPerational AMPlifier
OS        Operating System
OSCAR        Orbiting Satellite Carrying Amateur Radio
OSHA        Occupational Safety and Health Administration
OTDR        Optical Time Domain Reflectometry
OTOH        On The Other Hand
OTP        One Time Programmable
OVP        Over Voltage Protection
Back to Top
P
PA        Power Amplifier or Public Address
PAL        Programmable Array Logic
PBX        Private Branch eXchange
PC        Personal Computer or Printed Circuit or Program Counter
PCB        Printed Circuit Board
PCC        Plastic Chip Carrier
PCM        Pulse Code Modulation
PEC        PhotoElectric Cell
PEP        Peak Envelope Power
PF        Power Factor
PG        Power Gain
PGA        Pin Grid Array
PIA        Peripheral Interface Adapter
PIC        Priority Interrupt Controller or Parallax'es microcontroller name
PIV        Peak Inverse Voltage
PIXEL        PI(X)cture ELement
PLA        Programmable Logic Array
PLCC        Plastic Leaded Chip Carrier
PLD        Programmable Logic Device
PLL        Phase Locked Loop
PM        Phase Modulation or Pulse Modulation
PNP        Positive Negative Positive
POS        Point Of Sale or POSitive
POV        Peak Operating Voltage
PPI        Pixels Per Inch
PPM        Parts Per Million or Pulse Position Modulation
PPS        Pulses Per Second
PRN        Pseudo Random Noise
PROM        Programmable Read Only Memory
PRV        Peak Reverse Voltage or Peak Repetitive Voltage
PSG        Programmable Sound Generator
PSI        Pounds per Square Inch
PSK        Phase Shift Keying
PTC        Positive Temperature Coefficient
PTT        Push To Talk
PUT        Programmable Unijunction Transistor
PV        PhotoVoltaic
PWM        Pulse Width Modulation
PWR        PoWeR
Back to Top
Q
QA        Quality Assurance
QC        Quality Control
QIC        Quarter Inch Cartridge
QIP        Quad Inline Package
QSM        Quad Surface Mount
QWERTY        Standard keyboard layout
Back to Top
R
R        Resistance
R&D        Research and Development
RAD        Radiation Absorbed Dose
RADAR        RAdio Detection And Ranging
RAM        Random Access Memory
RAS        Row Address Strobe
RC        Radio Control or Resistance and Capacitance
RCV        ReCeiVe
RD        Receive Data or ReaD
RDA        Deceive Data
RDY        ReaDY
REM        Roentgen Equivalent Man
REP        Roentgen Equivalent Physical
RET        RETurn
RF        Radio Frequency
RFI        Radio Frequency Interference
RGB        Red Green Blue
RH        Relative Humidity
RHDP        Right Hand Decimal Point
RISC        Reduced Instruction Set Computer
RLC        Resistance Inductance Capacitance
RLG        Ring Laser Gyroscope
RMI        Radio Magnetic Interference
RMS        Root Mean Square
ROM        Read Only Memory
RPM        Revolutions Per Minute
RPN        Reverse Polish Notation
RPS        Revolutions Per Second
RS        Reed Solomon
RSSI        Received Signal Strength Indication
RT        Real Time or Rise Time
RTD        Resistance Temperature Detector
RTI        Real Time Interrupt
RTL        Resistor Transistor Logic
RTOS        Real Time Operating System
RTS        Request To Send
Back to Top
S
S/H        Sample and Hold
S/N        Signal to Noise
SAW        Surface Acoustic Wave
SBC        Single Board Computer
SCA        SubCarrier Adapter
SCI        Serial Communication Interface
SCL        Serial CLock
SCR        Silicon Controlled Rectifier
SCS        Silicon Controlled Switch
SCSI        Small Computer System Interface
SD        Standard Deviation
SDI        Strategic Defense Initiative
SDRAM        Synchronous Dynamic Random Access Memory
SEM        Scanning Electron Microscope
SEMI        Semiconductor Equipment and Materials Institute
SFC        polyStyrene Film Capacitor
SG        Signal Ground
SHF        Super High Frequency
SI        System International
SIMM        Single Inline Memory Module
SINAD        SIgnal-to-Noise-And-Distortion
SIO        Serial Input and Output
SIPO        Serial In Parallel Out
SLC        Single Layer Ceramic
SM        Surface Mount
SMD        Surface Mount Device
SNAFU        Situation Normal, All Fouled Up (other variations on F-word possible)
SNR        Signal to Noise Ratio
SMT        Surface Mount Technology
SO        Serial Output or Small Outline
SOIC        Small Outline Integrated Circuit
SOJ        Small Outline J-leaded
SOLV        SOLenoid Valve
SONAR        SOund NAvigation and Ranging
SOP        Small Outline Package
SP        Signal Processor or Stack Pointer
SPDT        Single Pole Double Throw
SPI        Serial to Parallel Interface
SPICE        Simulation Program with Integrated Circuit Emphasis
SPL        Sound Pressure Level
SPST        Single Pole Single Throw
SQL        Structured Query Language
SR        Shift Register
SRAM        Static Random Access Memory
SSB        Single SideBand
SSI        Small Scale Integration
SSIXS        Submarine Satellite Information eXchange System
SSR        Solid State Relay
SSTV        Slow Scan TeleVision
SVGA        Superior Versatile Graphics Adapter (800 x 600 pixels)
SW        Short Wave
Back to Top
T
T/H        Track and Hold
TC        Temperature Coefficient
TCP/IP        Transmission Control Protocol/Internet Protocol
TD        Tunnel Diode
TDD        Telecommunication Devices for the Deaf
TDR        Time Domain Reflectometry
TEM        Transverse ElectroMagnetic
TF        Transfer Function
TFD        Thin Film Detector
TFEL        Thin Film ElectroLuminescent
TFT        Thin Film Transistor
THD        Total Harmonic Distortion
THz        Terra Hertz
TI        Texas Instruments (a company)
TIG        Tungsten Inert Gas
TM        Transverse Magnetic (wave)
TR        Transient Response
TRIAC        TRIode AC switch (bilateral SCR)
TS        Time Sharing
TTL        Transistor Transistor Logic
TV        TeleVision
TWT        Traveling Wave Tube
Back to Top
U
UART        Universal Asynchronous Receiver/Transmitter
_F        micro Farad
UHF        Ultra High Frequency
UHV        Ultra High Vacuum
UJT        UniJunction Transistor
UL        Underwriters Laboratories
ULSI        Ultra Large Scale Integration
UPC        Universal Product Code
UPS        Uninterruptible Power Supply
USART        Universal Synchronous/Asynchronous Receiver/Transmitter
USB        Universal Serial Bus or Upper SideBand
UTC        Universal Time Code
UV        UltraViolet
UVA        UltraViolet Alpha
UVB        UltraViolet Beta
Back to Top
V
V        Volt
VA        Volt Ampere
VAC        Volts Alternating Current
VAR        VARiable or Volt Amperes Reactive
VARICAP        VARIable CAPacitance diode
VCC        Supply Voltage
VCD        Variable Capacitance Diode
VCO        Voltage Controlled Oscillator
VCR        Video Cassette Recorder
VDC        Volts Direct Current
VDD        Supply Voltage
VEE        Supply Voltage
VF        Vacuum Fluorescent
VFC        Voltage to Frequency Converter
VFO        Variable Frequency Oscillator
VGA        Versatile Graphics Adapter (640 x 480 pixels)
VHF        Very High Frequency
VLF        Very Low Frequency
VLSI        Very Large Scale Integration
VLT        Video Look up Table
VOL        VOLume
VOM        Volt OhmMeter
VOX        Voice Operated transmit
VR        Voltage Regulator or Virtual Reality
VRAM        Video Random Access Memory
VS        Vertical Sync
VSS        Supply Voltage
VT        Virtual Terminal
VTM        Voltage Tunable Magnetron
VTO        Voltage Tuned Oscillator
VTVM        Vacuum Tube Volt Meter
VXO        Variable crystal Oscillator
Back to Top
W
WACK        Wait before ACKnowledge
WDT        Watch Dog Timer
WH        Watt Hour
WHR        Watt HouR
WP        Word Processor
WPM        Words Per Minute
WR        WRite
WV        Working Voltage
WVDC        Working Volts DC
Ww        Wire Wound or Wire Wrap
Back to Top
X
XGA        eXtended Graphics Adapter
XMT        TransMiT
XOFF        Transmit OFF
XON        Transmit ON
XTAL        CrysTAL
Back to Top
Y
YAG        Yttrium Aluminum Garnet
YIG        Yttrium Iron Garnet
Back to Top
Z
ZD        Zero Defects
ZDT        Zero Defect Tolerance
ZIF        Zero Insertion Force
ZIP        Zigzag Inline Package

henerychan

S-, h-, T-, Y-, Z-, ABCD- Parameter Conversions
This table of conversion between various forms of 2-port network electrical parameters is difficult to find, so once I finally located a paper that included them1, I felt it was my duty to publish it for public access. The paper is available on the IEEE website by subscribers only. Other have published the full paper without permission of author Frickey. None that I found also include the correction paper2 published a year later that address some of the technicalities of the S- and T-parameter translations when complex impedance reference planes are used. In order to avoid those sticky issues, I have reproduced only the sets of translations that are unaffected. Many thanks to Mr. Frickey for his unique work.

One of the most sought-after sets of conversion is from s-parameters to T-parameters, and then back to s-parameters. This is because matrix multiplications can be performed directly on T-parameters in order to calculate cascaded component responses. That is, s-parameters matrices cannot be multiplied in series to obtain cascaded s-parameters, but T-parameters can be. So, convert your component s-parameters to T-parameters, multiply matrices, then convert the result back to s-parameters.

2-Port Network - RF Cafe
S-Parameters
S-parameters for 2-port networks - RF Cafe
Y-Parameters
Y-parameters for 2-port networks - RF Cafe
Z-Parameters
Z-parameters for 2-port networks - RF Cafe
h-Parameters
h-parameters for 2-port networks - RF Cafe
ABCD-Parameters3
ABCD-parameters for 2-port networks - RF Cafe The 2-port network shown to the left is representative of that implied in the application of these equations. Basic relationships of voltage and current are given in the table to the right. Many other sources exist on the particulars of 2-port network analysis, so it will not be covered here.

All of the parameter equations make use of complex values for all numbers of impedance and the resulting matrix parameters, i.e., Z = R ± jX.

Z01 and Z02 are the complex impedances of ports 1 and 2, respectively; similarly, Z*01 and Z*02 are the complex conjugates of the respective impedances.


The values R01 and R02 are the real parts of port impedances Z01 and Z02.

If you do not already know, here is the meaning of each type of parameter matrix: S (scattering),
Y (admittance), Z (impedance), h (hybrid), ABCD (chain), and T (chain scattering or chain transfer).

These are all I have, so please do not write to ask if I have others.

S-Parameters from Z-Parameters
S-Parameters from Z-Parameters - RF Cafe        S-Parameters from Z-Parameters - RF Cafe
S-Parameters from Z-Parameters - RF Cafe        S-Parameters from Z-Parameters - RF Cafe

S-Parameters from Y-Parameters
S-Parameters from Y-Parameters - RF Cafe        S-Parameters from Y-Parameters - RF Cafe
S-Parameters from Y-Parameters - RF Cafe        S-Parameters from Y-Parameters - RF Cafe

S-Parameters from h-Parameters
S-Parameters from h-Parameters - RF Cafe        S-Parameters from h-Parameters - RF Cafe
S-Parameters from h-Parameters - RF Cafe        S-Parameters from h-Parameters - RF Cafe

S-Parameters from ABCD-Parameters
S-Parameters from ABCD-Parameters - RF Cafe        S-Parameters from ABCD-Parameters - RF Cafe
S-Parameters from ABCD-Parameters - RF Cafe        S-Parameters from ABCD-Parameters - RF Cafe

T-Parameters from Z-Parameters
T-Parameters from Z-Parameters - RF Cafe        T-Parameters from Z-Parameters - RF Cafe
T-Parameters from Z-Parameters - RF Cafe        T-Parameters from Z-Parameters - RF Cafe

T-Parameters from Y-Parameters
T-Parameters from Y-Parameters - RF Cafe        T-Parameters from Y-Parameters - RF Cafe
T-Parameters from Y-Parameters - RF Cafe        T-Parameters from Y-Parameters - RF Cafe

T-Parameters from h-Parameters
T-Parameters from h-Parameters - RF Cafe        T-Parameters from h-Parameters - RF Cafe
T-Parameters from h-Parameters - RF Cafe        T-Parameters from h-Parameters - RF Cafe

T-Parameters from ABCD-Parameters
T-Parameters from ABCD-Parameters - RF Cafe        T-Parameters from ABCD-Parameters - RF Cafe
T-Parameters from ABCD-Parameters - RF Cafe        T-Parameters from ABCD-Parameters - RF Cafe

Y-Parameters from Z-Parameters
Y-Parameters from Z-Parameters - RF Cafe        Y-Parameters from Z-Parameters - RF Cafe
Y-Parameters from Z-Parameters - RF Cafe        Y-Parameters from Z-Parameters - RF Cafe

Y-Parameters from S-Parameters
Y-Parameters from S-Parameters - RF Cafe        Y-Parameters from S-Parameters - RF Cafe
Y-Parameters from S-Parameters - RF Cafe        Y-Parameters from S-Parameters - RF Cafe

Z-Parameters from T-Parameters
Z-Parameters from T-Parameters - RF Cafe        Z-Parameters from T-Parameters - RF Cafe
Z-Parameters from T-Parameters - RF Cafe        Z-Parameters from T-Parameters - RF Cafe

h-Parameters from S-Parameters
h-Parameters from S-Parameters - RF Cafe        h-Parameters from S-Parameters - RF Cafe
h-Parameters from S-Parameters - RF Cafe        h-Parameters from S-Parameters - RF Cafe

h-Parameters from T-Parameters
h-Parameters from T-Parameters - RF Cafe        h-Parameters from T-Parameters - RF Cafe
h-Parameters from T-Parameters - RF Cafe        h-Parameters from T-Parameters - RF Cafe

ABCD-Parameters from S-Parameters
ABCD-Parameters from S-Parameters - RF Cafe        ABCD-Parameters from S-Parameters - RF Cafe
ABCD-Parameters from S-Parameters - RF Cafe        ABCD-Parameters from S-Parameters - RF Cafe

ABCD-Parameters from T-Parameters
ABCD-Parameters from T-Parameters - RF Cafe        ABCD-Parameters from T-Parameters - RF Cafe
ABCD-Parameters from T-Parameters - RF Cafe        ABCD-Parameters from T-Parameters - RF Cafe

1. IEEE Transactions on Microwave Theory and Techniques. Vol 42, No 2. February 1994.
    Conversions Between S, Z, Y, h, ABCD, and T Parameters which are Valid for Complex Source
    and Load Impedances.
    By Dean A. Frickey, Member, IEEE

2. IEEE Transactions on Microwave Theory and Techniques. Vol 43, No 4. April 1995.
    A correction was printed by Roger B. Marks and Dylan F. Williams.

3. I1 formula corrected to use V2 rather than V1. Thanks to Christoph T. for noticing.

henerychan

Worldwide AC Voltage & Frequency Standards

Just as it seems unlikely that the world will anytime soon converge on a single, common language (Esperanto failed), it is also unlikely that 'last-mile' electrical distribution systems will agree on a common voltage and frequency standard. In both cases, local implementations are so entrenched that a wholesale realignment would be prohibitively expensive in terms of both resources and finances. The global nature of all aspects of industrial, commercial, and consumer products has necessitated that accommodation be made for all existing systems, and that object has largely been achieved. Generally, most of North and South America use 60 Hz, while nearly everyplace else uses 50 Hz. 60 Hz has the advantage of requiring smaller power supply filter capacitors that required at 50 Hz.
The following tables present a compilation of the plethora of voltages, frequencies, and plug/receptacle types to be dealt with. There are 12 plug types, 2 frequencies, and 14 voltage combinations. Fortunately, not all combinations are used (2 x 12 x 14 = 336).
Thomas Edison's DC distribution failed because it was not efficient over long distances, requiring many local generation sites. Maybe the growing number of local wind and solar PV cell sites will bring DC back into style. Doing so eliminates the hugely expensive requirement for AC inverters and distribution phase synchronization. The disgustingly large and rapidly growing amount of inverter EMI could be greatly reduced with DC.
The following information was obtained by the U.S. Department of Commerce International Trade Administration's open source publication titled, "Electric Current Abroad," dated February 2002. If you have a critical application, please seek the most up-to-date information from local electrical service utilities rather than relying on this information.
Introduction
AC Plug Types for Worldwide Voltage Standards (images) - RF Cafe

AC Plug Types for Worldwide Voltage Standards (list) - RF Cafe

AC Plug Types for Worldwide Voltage Standards

To assist U.S. manufacturers, exporters and individuals living or traveling abroad, this publication lists the characteristics of electric current available and the type of attachment plugs used in most countries. It is an update of a similar handbook published in 1991. The tables indicate the type of current (alternating or direct current), number of phases, frequency (hertz), and voltage, as well as the stability of the frequency and the number of wires to a commercial or residential installation. This information pertains to domestic and commercial service only. It does not apply to special commercial installations involving relatively high voltage requirements or to industrial installations.
For most countries listed here, two nominal voltages are given. The lower voltages are used primarily for lighting and smaller appliances, while the higher voltages are used primarily for air conditioners, heating, and other large appliances. Travelers planning to use or ship appliances abroad should acquaint themselves with the characteristics of the electric supply available in the area in which the appliance is to be used. In some cases, a transformer may be used to correct the voltage. However, if the appliance requires exact timing or speed and if the frequency of the foreign electricity supply differs from the one the appliance was designed for, it is advisable to use an appliance designed for the foreign frequency since auxiliary equipment to change frequency is bulky and expensive. Some foreign hotels have circuits providing approximately 120 volts which allow guests to use electric shavers and other low-wattage U.S. appliances.
The information presented here was compiled over a period of months from a large number of sources. Consequently, there is some possibility of errors or omissions for which the Department of Commerce cannot assume responsibility. In addition, this information should not be taken as final in the case of industrial or highly specialized commercial installations. It would 4 Electric Current Abroad be impossible for the Department to maintain complete data on every foreign industrial installation. For special equipment for commercial use or heavy equipment for industrial use, the current characteristics for the area of installation should be obtained from the end user.
The 1998 edition was prepared by the Trade Development unit in the International Trade Administration, U.S. Department of Commerce. The information was compiled by John J. Bodson, industry specialist in the Office of Energy, Infrastructure, and Machinery. Editing, desktop publishing, and production were done by Rebecca Krafft, of the Trade Information Division of the Office of Trade and Economic Analysis.
The cooperation of various government and private agencies in providing data is gratefully acknowledged. Special thanks go to the U.S. Foreign and Commercial Service of the U.S. Department of Commerce and the Foreign Service of the U.S. Department of State.
Questions about the content of this publication should be directed to the Energy Division in the Office of Basic Industries, (202) 482-4931.
See "Key to Terms"
Worldwide AC Voltage Standards - RF Cafe

Key to Terms
Type of current: a.c. indicates alternating current; d.c. indicates direct current. Frequency—Shown in number of hertz (cycles per second). Note that even if voltages are similar, a 60-hertz U.S. clock or tape recorder will not function properly on 50 hertz current.
Number of phases: 1 and 3 are the conventional phases that may be available.
Nominal voltage: The term nominal voltage is used to denote the reported voltage in use in the majority of residential and commercial establishments in the country or city. Direct current nominal voltages are 110/220 and 120/240. The lower voltage is always 1/2 of the higher voltage. On a direct current installation, the lower voltage requires two wires while the higher voltage requires three wires.
Alternating current is normally distributed either through 3 phase wye (“star”) or delta (“triangle”), 4-wire secondary distribution systems. In the wye or star distribution system the nominal voltage examples are 120/208, 127/220, 220/380, and 230/400. The higher voltage is 1.732 (the square root of 3) times the lower voltage. In a delta or triangle system, 110/220 and 230/460 are examples of nominal voltages. The higher voltage is always double the lower voltage. The higher voltage is obtained by using 2 or 3 phase wires and the neutral wire while the lower voltage is the voltage between the neutral wire and one phase wire. The higher voltage may be single or 3 phase while the lower voltage is always single phase and used primarily for lighting and for small appliances.
Type of attachment plug in use: Attachment plugs used throughout the world come in various forms, dimensions and configurations too numerous to describe in this report. This report does, however, attempt to point 6 Electric Current Abroad out the basic and most commonly used types of plugs by country. Adapters may be purchased to change from the American plug type to other types.
Number of wires to the consumer: The number of wires which may be used by the consumer is shown. Normally, a single phase, 220/380 volt system or 127/220 system will have two wires if only the lower voltage is available (one phase wire and the neutral). It will have three wires if both the higher and lower voltages are available (two phase wires and the neutral) and where three phase motors will be used, four wires will be available for the higher voltage (the three phase wires and the neutral wire).
Frequency stability: “Yes” indicates that the frequency is stable and that service interruptions are rare.

henerychan

henerychan 发表于 2016-10-25 09:18
Worldwide AC Voltage & Frequency Standards

Just as it seems unlikely that the world will anytime  ...

Impedance and Admittance Formulas for RLC Combinations
Here is an extensive table of impedance, admittance, magnitude, and phase angle equations (formulas) for fundamental series and parallel combinations of resistors, inductors, and capacitors. All schematics and equations assume ideal components, where resistors exhibit only resistance, capacitors exhibit only capacitance, and inductors exhibit only inductance.
For those unfamiliar with complex numbers, the "±j" operator signifies a phase of ±90°. Voltage across a capacitor lags the current through it by 90°, so -j is used along with its capacitive reactance (-j/ωC). Voltage across an inductor leads the current through it by 90°, so +j is used along with inductive reactance (jωL).
"M" is the mutual inductance between inductors.
"ω" is frequency in radians/second, and is equal to 2π times frequency in cycles/second.
This is probably one of the most comprehensive collections you will find on the Internet.
Z = R + jX           |Z| = (R2 + X2)½           ϕ = tan-1(X/R)           Y = 1/Z
Circuit
Configuration

henerychan

Introduction to Amplifiers
CHAPTER 1


AMPLIFIERS



LEARNING OBJECTIVES
Learning objectives are stated at the beginning of each chapter. These learning objectives serve as a preview of the information you are expected to learn in the chapter. The comprehensive check questions are based on the objectives. By successfully completing the OCC/ECC, you indicate that you have met the objectives and have learned the information. The learning objectives are listed below.
Upon completion of this chapter, you will be able to:

1. Define amplification and list several common uses; state two ways in which amplifiers are classified.

2. List the four classes of operation of, four methods of coupling for, and the impedance characteristics of the three configurations of a transistor amplifier.

3. Define feedback and list the two types of feedback.

4. Describe and state one use for a phase splitter.

5. State a common use for and one advantage of a push-pull amplifier.


INTRODUCTION

This chapter is a milestone in your study of electronics. Previous modules have been concerned more with individual components of circuits than with the complete circuits as the subject. This chapter and the other chapters of this module are concerned with the circuitry of amplifiers. While components are discussed, the discussion of the components is not an explanation of the working of the component itself (these have been covered in previous modules) but an explanation of the component as it relates to the circuit.

The circuits this chapter is concerned with are AMPLIFIERS. Amplifiers are devices that provide AMPLIFICATION. That doesn't explain much, but it does describe an amplifier if you know what amplification is and what it is used for.

WHAT IS AMPLIFICATION?
Just as an amplifier is a device that provides amplification, amplification is the process of providing an increase in AMPLITUDE. Amplitude is a term that describes the size of a signal. In terms of a.c., amplitude usually refers to the amount of voltage or current. A 5-volt peak-to-peak a.c.signal would be larger in amplitude than a 4-volt peak-to-peak a.c. signal. "SIGNAL" is a general term used to refer to any a.c. or d.c. of interest in a circuit; e.g., input signal and output signal. A signal can be large or small, ac. or d.c., a sine wave or nonsinusoidal, or even nonelectrical such as sound or light. "Signal" is a very general term and, therefore, not very descriptive by itself, but it does sound more technical than the word "thing". It is not very impressive to refer to the "input thing" or the "thing that comes out of this circuit."

1-1


Perhaps the concept of the relationship of amplifier-amplification-amplitude will be clearer if you consider a parallel situation (an analogy). A magnifying glass is a magnifier. As such, it provides magnification which is an increase in the magnitude (size) of an object. This relationship of magnifier- magnification-magnitude is the same as the relationship of amplifier-amplification-amplitude. The analogy is true in one other aspect as well. The magnifier does not change the object that is being magnified; it is only the image that is larger, not the object itself. With the amplifier, the output signal differs in amplitude from the input signal, but the input signal still exists unchanged. So, the object (input signal) and the magnifier (amplifier) control the image (output signal).
An amplifier can be defined as a device that enables an input signal to control an output signal. The output signal will have some (or all) of the characteristics of the input signal but will generally be larger than the input signal in terms of voltage, current, or power.

USES OF AMPLIFICATION

Most electronic devices use amplifiers to provide various amounts of signal amplification. Since most signals are originally too small to control or drive the desired device, some amplification is needed.
For example, the audio signal taken from a record is too small to drive a speaker, so amplification is needed. The signal will be amplified several times between the needle of the record player and the speaker. Each time the signal is amplified it is said to go through a STAGE of amplification. The audio amplifier shown connected between the turntable and speaker system in figure 1-1 contains several stages of amplification.

Amplifier as used with turntable and speaker
Figure 1-1.—Amplifier as used with turntable and speaker.

  
Notice the triangle used in figure 1-1 to represent the amplifier. This triangle is the standard block diagram symbol for an amplifier.
Another example of the use of an amplifier is shown in figure 1-2. In a radio receiver, the signal picked up by the antenna is too weak (small) to be used as it is. This signal must be amplified before it is sent to the detector. (The detector separates the audio signal from the frequency that was sent by the transmitter. The way in which this is done will be discussed later in this training series.)


1-2


Amplifiers as used in radio receiver
Figure 1-2.—Amplifiers as used in radio receiver.

  
The audio signal from the detector will then be amplified to make it large enough to drive the speaker of the radio.

Almost every electronic device contains at least one stage of amplification, so you will be seeing amplifiers in many devices that you work on. Amplifiers will also be used in most of the NEETS modules that follow this one.
  
Q-1. What is amplification?
  
Q-2. Does an amplifier actually change an input signal? Why or why not?
  
Q-3. Why do electronic devices use amplifiers?

CLASSIFICATION OF AMPLIFIERS

Most electronic devices use at least one amplifier, but there are many types of amplifiers. This module will not try to describe all the different types of amplifiers. You will be shown the general principles of amplifiers and some typical amplifier circuits.

Most amplifiers can be classified in two ways. The first classification is by their function. This means they are basically voltage amplifiers or power amplifiers. The second classification is by their frequency response. In other words what frequencies are they designed to amplify?

If you describe an amplifier by these two classifications (function and frequency response) you will have a good working description of the amplifier. You may not know what the exact circuitry is, but you will know what the amplifier does and the frequencies that it is designed to handle.

VOLTAGE AMPLIFIERS AND POWER AMPLIFIERS

All amplifiers are current-control devices. The input signal to an amplifier controls the current output of the amplifier. The connections of the amplifying device (electron tube, transistor, magnetic amplifier,


1-3


etc.) and the circuitry of the amplifier determine the classification. Amplifiers are classified as voltage or power amplifiers.
A VOLTAGE AMPLIFIER is an amplifier in which the output signal voltage is larger than the input signal voltage. In other words, a voltage amplifier amplifies the voltage of the input signal.
A POWER AMPLIFIER is an amplifier in which the output signal power is greater than the input signal power. In other words, a power amplifier amplifies the power of the input signal. Most power amplifiers are used as the final amplifier (stage of amplification) and control (or drive) the output device. The output device could be a speaker, an indicating device, an antenna, or the heads on a tape recorder. Whatever the device, the power to make it work (or drive it) comes from the final stage of amplification which is a power amplifier.
Figure 1-3 shows a simple block diagram of a voltage amplifier with its input and output signals and a power amplifier with its input and output signals. Notice that in view (A) the output signal voltage is larger than the input signal voltage. Since the current values for the input and output signals are not shown, you cannot tell if there is a power gain in addition to the voltage gain.

Block diagram of voltage and power amplifiers
Figure 1-3A.—Block diagram of voltage and power amplifiers.

Block diagram of voltage and power amplifiers
Figure 1-3B.—Block diagram of voltage and power amplifiers.

  
In view (B) of the figure the output signal voltage is less than the input signal voltage. As a voltage amplifier, this circuit has a gain of less than 1. The output power, however, is greater than the input power. Therefore, this circuit is a power amplifier.
The classification of an amplifier as a voltage or power amplifier is made by comparing the characteristics of the input and output signals. If the output signal is larger in voltage amplitude than the input signal, the amplifier is a voltage amplifier. If there is no voltage gain, but the output power is greater than the input power, the amplifier is a power amplifier.


1-4


FREQUENCY RESPONSE OF AMPLIFIERS

In addition to being classified by function, amplifiers are classified by frequency response. The frequency response of an amplifier refers to the band of frequencies or frequency range that the amplifier was designed to amplify.

You may wonder why the frequency response is important. Why doesn't an amplifier designed to amplify a signal of 1000 Hz work just as well at 1000 MHz? The answer is that the components of the amplifier respond differently at different frequencies. The amplifying device (electron tube, transistor, magnetic amplifier, etc.) itself will have frequency limitations and respond in different ways as the frequency changes. Capacitors and inductors in the circuit will change their reactance as the frequency changes. Even the slight amounts of capacitance and inductance between the circuit wiring and other components (interelectrode capacitance and self-inductance) can become significant at high frequencies. Since the response of components varies with the frequency, the components of an amplifier are selected to amplify a certain range or band of frequencies.

NOTE: For explanations of interelectrode capacitance and self-inductance see NEETS Modules 2— Introduction to Alternating Current and Transformers; 6—Introduction to Electronic Emission, Tubes, and Power Supplies; and 7—Introduction to Solid-State Devices and Power Supplies.
The three broad categories of frequency response for amplifiers are AUDIO AMPLIFIER, RF AMPLIFIER, and VIDEO AMPLIFIER.

An audio amplifier is designed to amplify frequencies between 15 Hz and 20 kHz. Any amplifier that is designed for this entire band of frequencies or any band of frequencies contained in the audio range is considered to be an audio amplifier.

In the term RF amplifier, the "RF" stands for radio frequency. These amplifiers are designed to amplify frequencies between 10 kHz and 100,000 MHz. A single amplifier will not amplify the entire RF range, but any amplifier whose frequency band is included in the RF range is considered an RF amplifier.

A video amplifier is an amplifier designed to amplify a band of frequencies from 10 Hz to 6 MHz. Because this is such a wide band of frequencies, these amplifiers are sometimes called WIDE-BAND AMPLIFIERS. While a video amplifier will amplify a very wide band of frequencies, it does not have the gain of narrower-band amplifiers. It also requires a great many more components than a narrow-band amplifier to enable it to amplify a wide range of frequencies.
  
Q-4. In what two ways are amplifiers classified?
  
Q-5. What type of amplifier would be used to drive the speaker system of a record player?
  
Q-6. What type of amplifier would be used to amplify the signal from a radio antenna?

TRANSISTOR AMPLIFIERS

A transistor amplifier is a current-control device. The current in the base of the transistor (which is dependent on the emitter-base bias) controls the current in the collector. A vacuum-tube amplifier is also a current-control device. The grid bias controls the plate current. These facts are expanded upon in NEETS Module 6, Introduction to Electronic Emission, Tubes and Power Supplies, and Module 7, Introduction to Solid-State Devices and Power Supplies.


1-5


You might hear that a vacuum tube is a voltage-operated device (since the grid does not need to draw current) while the transistor is a current-operated device. You might agree with this statement, but both the vacuum tube and the transistor are still current-control devices. The whole secret to understanding amplifiers is to remember that fact. Current control is the name of the game. Once current is controlled you can use it to give you a voltage gain or a power gain.

This chapter will use transistor amplifiers to present the concepts and principles of amplifiers. These concepts apply to vacuum-tube amplifiers and, in most cases, magnetic amplifiers as well as transistor amplifiers. If you wish to study the vacuum-tube equivalent circuits of the transistor circuits presented, an excellent source is the EIMB, NAVSEA 0967-LP-000-0120, Electronics Circuits.

The first amplifier concept that is discussed is the "class of operation" of an amplifier.

AMPLIFIER CLASSES OF OPERATION

The class of operation of an amplifier is determined by the amount of time (in relation to the input signal) that current flows in the output circuit. This is a function of the operating point of the amplifying device. The operating point of the amplifying device is determined by the bias applied to the device. There are four classes of operation for an amplifier. These are: A, AB, B and C. Each class of operation has certain uses and characteristics. No one class of operation is "better" than any other class. The selection of the "best" class of operation is determined by the use of the amplifying circuit. The best class of operation for a phonograph is not the best class for a radio transmitter.

Class A Operation
A simple transistor amplifier that is operated class A is shown in figure 1-4. Since the output signal is a 100% (or 360o) copy of the input signal, current in the output circuit must flow for 100% of the input signal time. This is the definition of a class A amplifier. Amplifier current flows for 100% of the input signal.

A simple class A transistor amplifier
Figure 1-4.—A simple class A transistor amplifier.

  
The class A amplifier has the characteristics of good FIDELITY and low EFFICIENCY. Fidelity means that the output signal is just like the input signal in all respects except amplitude. It has the same


1-6


shape and frequency. In some cases, there may be a phase difference between the input and output signal (usually 180o), but the signals are still considered to be "good copies." If the output signal is not like the input signal in shape or frequency, the signal is said to be DISTORTED. DISTORTION is any undesired change in a signal from input to output.
The efficiency of an amplifier refers to the amount of power delivered to the output compared to the power supplied to the circuit. Since every device takes power to operate, if the amplifier operates for 360o of input signal, it uses more power than if it only operates for 180o of input signal. If the amplifier uses more power, less power is available for the output signal and efficiency is lower. Since class A amplifiers operate (have current flow) for 360o of input signal, they are low in efficiency. This low efficiency is acceptable in class A amplifiers because they are used where efficiency is not as important as fidelity.

Class AB Operation

If the amplifying device is biased in such a way that current flows in the device for 51% - 99% of the input signal, the amplifier is operating class AB. A simple class AB amplifier is shown in figure 1-5.

A simple class AB transistor amplifier
Figure 1-5.—A simple class AB transistor amplifier.

  
Notice that the output signal is distorted. The output signal no longer has the same shape as the input signal. The portion of the output signal that appears to be cut off is caused by the lack of current through the transistor. When the emitter becomes positive enough, the transistor cannot conduct because the base- to-emitter junction is no longer forward biased. Any further increase in input signal will not cause an increase in output signal voltage.

Class AB amplifiers have better efficiency and poorer fidelity than class A amplifiers. They are used when the output signal need not be a complete reproduction of the input signal, but both positive and negative portions of the input signal must be available at the output.

Class AB amplifiers are usually defined as amplifiers operating between class A and class B because class A amplifiers operate on 100% of input signal and class B amplifiers (discussed next) operate on 50% of the input signal. Any amplifier operating between these two limits is operating class AB.


1-7


Class B Operation

As was stated above, a class B amplifier operates for 50% of the input signal. A simple class B
amplifier is shown in figure 1-6.

A simple class B transistor amplifier
Figure 1-6.—A simple class B transistor amplifier.

  
In the circuit shown in figure 1-6, the base-emitter bias will not allow the transistor to conduct whenever the input signal becomes positive. Therefore, only the negative portion of the input signal is reproduced in the output signal. You may wonder why a class B amplifier would be used instead of a simple rectifier if only half the input signal is desired in the output. The answer to this is that the rectifier does not amplify. The output signal of a rectifier cannot be higher in amplitude than the input signal. The class B amplifier not only reproduces half the input signal, but amplifies it as well.

Class B amplifiers are twice as efficient as class A amplifiers since the amplifying device only conducts (and uses power) for half of the input signal. A class B amplifier is used in cases where exactly 50% of the input signal must be amplified. If less than 50% of the input signal is needed, a class C amplifier is used.

Class C Operation

Figure 1-7 shows a simple class C amplifier. Notice that only a small portion of the input signal is present in the output signal. Since the transistor does not conduct except during a small portion of the input signal, this is the most efficient amplifier. It also has the worst fidelity. The output signal bears very little resemblance to the input signal.


1-8


A simple class C transistor amplifier
Figure 1-7.—A simple class C transistor amplifier.


Class C amplifiers are used where the output signal need only be present during part of one-half of the input signal. Any amplifier that operates on less than 50% of the input signal is operated class C.
  
Q-7. What determines the class of operation of an amplifier?
  
Q-8. What are the four classes of operation of a transistor amplifier?
  
Q-9. If the output of a circuit needs to be a complete representation of one-half of the input signal, what class of operation is indicated?
  
Q-10. Why is class C operation more efficient than class A operation?
  
Q-11. What class of operation has the highest fidelity?

henerychan

AMPLIFIER COUPLING

Earlier in this module it was stated that almost every electronic device contains at least one stage of amplification. Many devices contain several stages of amplification and therefore several amplifiers. Stages of amplification are added when a single stage will not provide the required amount of amplification. For example, if a single stage of amplification will provide a maximum gain of 100 and the desired gain from the device is 1000, two stages of amplification will be required. The two stages might have gains of 10 and 100, 20 and 50, or 25 and 40. (The overall gain is the product of the individual stages-10 x 100 = 20 x 50 = 25 x 40 = 1000.)

Figure 1-8 shows the effect of adding stages of amplification. As stages of amplification are added, the signal increases and the final output (from the speaker) is increased.


1-9


Adding stages of amplification
Figure 1-8.—Adding stages of amplification.


Whether an amplifier is one of a series in a device or a single stage connected between two other devices (top view, figure 1-8), there must be some way for the signal to enter and leave the amplifier. The process of transferring energy between circuits is known as COUPLING. There are various ways of coupling signals into and out of amplifier circuits. The following is a description of some of the more common methods of amplifier coupling.

Direct Coupling

The method of coupling that uses the least number of circuit elements and that is, perhaps, the easiest to understand is direct coupling. In direct coupling the output of one stage is connected directly to the input of the following stage. Figure 1-9 shows two direct-coupled transistor amplifiers.


1-10

Introduction to Matter, Energy, and Direct Current, Introduction to Alternating Current and Transformers, Introduction to Circuit Protection, Control, and Measurement, Introduction to Electrical Conductors, Wiring Techniques, and Schematic Reading, Introduction to Generators and Motors, Introduction to Electronic Emission, Tubes, and Power Supplies, Introduction to Solid-State Devices and Power Supplies, Introduction to Amplifiers, Introduction to Wave-Generation and Wave-Shaping Circuits, Introduction to Wave Propagation, Transmission Lines, and Antennas, Microwave Principles, Modulation Principles, Introduction to Number Systems and Logic Circuits, Introduction to Microelectronics, Principles of Synchros, Servos, and Gyros, Introduction to Test Equipment, Radio-Frequency Communications Principles, Radar Principles, The Technician's Handbook, Master Glossary, Test Methods and Practices, Introduction to Digital Computers, Magnetic Recording, Introduction to Fiber Optics

Direct-coupled transistor amplifiers - RF Cafe
Figure 1-9.—Direct-coupled transistor amplifiers.


Notice that the output (collector) of Q1 is connected directly to the input (base) of Q2. The network of R4, R5, and R6 is a voltage divider used to provide the bias and operating voltages for Q1 and Q2. The entire circuit provides two stages of amplification.

Direct coupling provides a good frequency response since no frequency-sensitive components (inductors and capacitors) are used. The frequency response of a circuit using direct coupling is affected only by the amplifying device itself.

Direct coupling has several disadvantages, however. The major problem is the power supply requirements for direct-coupled amplifiers. Each succeeding stage requires a higher voltage. The load and voltage divider resistors use a large amount of power and the biasing can become very complicated. In addition, it is difficult to match the impedance from stage to stage with direct coupling. (Impedance matching is covered a little later in this chapter.)

The direct-coupled amplifier is not very efficient and the losses increase as the number of stages increase. Because of the disadvantages, direct coupling is not used very often.

RC Coupling

The most commonly used coupling in amplifiers is RC coupling. An RC-coupling network is shown in figure 1-10.


1-11


RC-coupled transistor amplifier
Figure 1-10.—RC-coupled transistor amplifier.

  
The network of R1, R2, and C1 enclosed in the dashed lines of the figure is the coupling network. You may notice that the circuitry for Q1 and Q2 is incomplete. That is intentional so that you can concentrate on the coupling network.

R1 acts as a load resistor for Q1 (the first stage) and develops the output signal of that stage. Do you remember how a capacitor reacts to ac and dc? The capacitor, C1, "blocks" the dc of Q1's collector, but "passes" the ac output signal. R2 develops this passed, or coupled, signal as the input signal to Q2 (the second stage). This arrangement allows the coupling of the signal while it isolates the biasing of each stage. This solves many of the problems associated with direct coupling.

RC coupling does have a few disadvantages. The resistors use dc power and so the amplifier has low efficiency. The capacitor tends to limit the low-frequency response of the amplifier and the amplifying device itself limits the high-frequency response. For audio amplifiers this is usually not a problem; techniques for overcoming these frequency limitations will be covered later in this module.

Before you move on to the next type of coupling, consider the capacitor in the RC coupling. You probably remember that capacitive reactance (X C) is determined by the following formula:

Equation


This explains why the low frequencies are limited by the capacitor. As frequency decreases, XC increases. This causes more of the signal to be "lost" in the capacitor.

The formula for XC also shows that the value of capacitance (C) should be relatively high so that capacitive reactance (XC) can be kept as low as possible. So, when a capacitor is used as a coupling element, the capacitance should be relatively high so that it will couple the entire signal well and not reduce or distort the signal.

Impedance Coupling

Impedance coupling is very similar to RC coupling. The difference is the use of an impedance device
(a coil) to replace the load resistor of the first stage.


1-12


Figure 1-11 shows an impedance-coupling network between two stages of amplification. L1 is the load for Q1 and develops the output signal of the first stage. Since the d.c. resistance of a coil is low, the efficiency of the amplifier stage is increased. The amount of signal developed in the output of the stage depends on the inductive reactance of L1. Remember the formula for inductive reactance:

Impedance-coupled transistor amplifier
Figure 1-11.—Impedance-coupled transistor amplifier.

  
The formula shows that for inductive reactance to be large, either inductance or frequency or both must be high. Therefore, load inductors should have relatively large amounts of inductance and are most effective at high frequencies. This explains why impedance coupling is usually not used for audio amplifiers.

The rest of the coupling network (C1 and R1) functions just as their counterparts (C1 and R2) in the RC-coupling network. C1 couples the signal between stages while blocking the d.c. and R1 develops the input signal to the second stage (Q2).

Transformer Coupling

Figure 1-12 shows a transformer-coupling network between two stages of amplification. The transformer action of T1 couples the signal from the first stage to the second stage. In figure 1-12, the primary of T1 acts as the load for the first stage (Q1) and the secondary of T1 acts as the developing impedance for the second stage (Q2). No capacitor is needed because transformer action couples the signal between the primary and secondary of T1.


1-13


Transformer-coupled transistor amplifier
Figure 1-12.—Transformer-coupled transistor amplifier.


The inductors that make up the primary and secondary of the transformer have very little dc resistance, so the efficiency of the amplifiers is very high. Transformer coupling is very often used for the final output (between the final amplifier stage and the output device) because of the impedance-matching qualities of the transformer. The frequency response of transformer-coupled amplifiers is limited by the inductive reactance of the transformer just as it was limited in impedance coupling.
  
Q-12. What is the purpose of an amplifier-coupling network? Q-13. What are four methods of coupling amplifier stages?

Q-14. What is the most common form of coupling?
  
Q-15. What type coupling is usually used to couple the output from a power amplifier?
  
Q-16. What type coupling would be most useful for an audio amplifier between the first and second stages?
  
Q-17. What type of coupling is most effective at high frequencies?


IMPEDANCE CONSIDERATIONS FOR AMPLIFIERS

It has been mentioned that efficiency and impedance are important in amplifiers. The reasons for this may not be too clear. You have been shown that any amplifier is a current-control device. Now there are two other principles you should try to keep in mind. First, there is no such thing as "something for nothing" in electronics. That means every time you do something to a signal it costs something. It might mean a loss in fidelity to get high power. Some other compromise might also be made when a circuit is designed. Regardless of the compromise, every stage will require and use power. This brings up the second principle-do things as efficiently as possible. The improvement and design of electronic circuits is an attempt to do things as cheaply as possible, in terms of power, when all the other requirements (fidelity, power output, frequency range, etc.) have been met.

This brings us to efficiency. The most efficient device is the one that does the job with the least loss of power. One of the largest losses of power is caused by impedance differences between the output of one circuit and the input of the next circuit. Perhaps the best way to think of an impedance difference (mismatch) between circuits is to think of different-sized water pipes. If you try to connect a one-inch water pipe to a two-inch water pipe without an adapter you will lose water. You must use an adapter. An


1-14


impedance-matching device is like that adapter. It allows the connection of two devices with different impedances without the loss of power.

Figure 1-13 shows two circuits connected together. Circuit number 1 can be considered as an a.c. source (ES) whose output impedance is represented by a resistor (R1). It can be considered as an a.c. source because the output signal is an a.c. voltage and comes from circuit number 1 through the output impedance. The input impedance of circuit number 2 is represented by a resistor in series with the source. The resistance is shown as variable to show what will happen as the input impedance of circuit number 2 is changed.


Effect of impedance matching in the coupling of two circuits
Figure 1-13.—Effect of impedance matching in the coupling of two circuits.

  
The chart below the circuit shows the effect of a change in the input impedance of circuit number 2 (R2) on current (I), signal voltage developed at the input of circuit number 2 (ER2), the power at the output of circuit number 1 (PR1), and the power at the input to circuit number 2 (PR2).

Two important facts are brought out in this chart. First, the power at the input to circuit number 2 is greatest when the impedances are equal (matched). The power is also equal at the output of circuit number 1 and the input of circuit number 2 when the impedance is matched. The second fact is that the largest voltage signal is developed at the input to circuit number 2 when its input impedance is much larger than the output impedance of circuit number 1. However, the power at the input of circuit number 2


1-15


is very low under these conditions. So you must decide what conditions you want in coupling two circuits together and select the components appropriately.

Two important points to remember about impedance matching are as follows. (1) Maximum power transfer requires matched impedance. (2) To get maximum voltage at the input of a circuit requires an intentional impedance mismatch with the circuit that is providing the input signal.

Impedance Characteristics of Amplifier Configurations

Now that you have seen the importance of impedance matching the stages in an electronic device, you may wonder what impedance characteristics an amplifier has. The input and output impedances of a transistor amplifier depend upon the configuration of the transistor. In Module 7, Introduction to

Solid-State Devices and Power Supplies, you were introduced to the three transistor configurations; the common emitter, the common base, and the common collector. Examples of these configurations and their impedance characteristics are shown in figure 1-14.


Transistor amplifier configurations and their impedance characteristics
Figure 1-14.—Transistor amplifier configurations and their impedance characteristics.

  
NOTE: Only approximate impedance values are shown. This is because the exact impedance values will vary from circuit to circuit. The impedance of any particular circuit depends upon the device (transistor) and the other circuit components. The value of impedance can be computed by dividing the signal voltage by the signal current. Therefore:


11-16


Formulas


The common-emitter configuration provides a medium input impedance and a medium output impedance. The common-base configuration provides a low input impedance and a high output impedance. The common-collector configuration provides a high input impedance and a low output impedance. The common-collector configuration is often used to provide impedance matching between a high output impedance and a low input impedance.

If the amplifier stage is transformer coupled, the turns ratio of the transformer can be selected to provide impedance matching. In NEETS Module 2, Introduction to Alternating Current and Transformers, you were shown the relationship between the turns ratio and the impedance ratio in a transformer. The relationship is expressed in the following formula:


Formulas


As you can see, impedance matching between stages can be accomplished by a combination of the amplifier configuration and the components used in the amplifier circuit.
  
Q-18. What impedance relationship between the output of one circuit and the input of another circuit will provide the maximum power transfer?
  
Q-19. If maximum current is desired at the input to a circuit, should the input impedance of that circuit be lower than, equal to, or higher than the output impedance of the previous stage?

Q-20. What are the input- and output-impedance characteristics of the three transistor configurations?
  
& Q-21. What transistor circuit configuration should be used to match a high output impedance to a low input impedance?
  
Q-22. What type of coupling is most useful for impedance matching?

1-17


AMPLIFIER FEEDBACK

Perhaps you have been around a public address system when a squeal or high-pitched noise has come from the speaker. Someone will turn down the volume and the noise will stop. That noise is an indication that the amplifier (at least one stage of amplification) has begun oscillating. Oscillation is covered in detail in NEETS Module 9, Introduction to Wave-Generation and Wave-Shaping Circuits. For now, you need only realize that the oscillation is caused by a small part of the signal from the amplifier output being sent back to the input of the amplifier. This signal is amplified and again sent back to the input where it is amplified again. This process continues and the result is a loud noise out of the speaker. The process of sending part of the output signal of an amplifier back to the input of the amplifier is called FEEDBACK.

There are two types of feedback in amplifiers. They are POSITIVE FEEDBACK, also called REGENERATIVE FEEDBACK, and NEGATIVE FEEDBACK, also called DEGENERATIVE FEEDBACK. The difference between these two types is whether the feedback signal is in phase or out of phase with the input signal.

Positive feedback occurs when the feedback signal is in phase with the input signal. Figure 1-15 shows a block diagram of an amplifier with positive feedback. Notice that the feedback signal is in phase with the input signal. This means that the feedback signal will add to or "regenerate" the input signal. The result is a larger amplitude output signal than would occur without the feedback. This type of feedback is what causes the public address system to squeal as described above.


Positive feedback in an amplifier
Figure 1-15.—Positive feedback in an amplifier.

  
Figure 1-16 is a block diagram of an amplifier with negative feedback. In this case, the feedback signal is out of phase with the input signal. This means that the feedback signal will subtract from or "degenerate" the input signal. This results in a lower amplitude output signal than would occur without the feedback.


1-18


Negative feedback in an amplifier
Figure 1-16.—Negative feedback in an amplifier.


Sometimes feedback that is not desired occurs in an amplifier. This happens at high frequencies and limits the high-frequency response of an amplifier. Unwanted feedback also occurs as the result of some circuit components used in the biasing or coupling network. The usual solution to unwanted feedback is a feedback network of the opposite type. For example, a positive feedback network would counteract unwanted, negative feedback.

Feedback is also used to get the ideal input signal. Normally, the maximum output signal is desired from an amplifier. The amount of the output signal from an amplifier is dependent on the amount of the input signal. However, if the input signal is too large, the amplifying device will be saturated and/or cut off during part of the input signal. This causes the output signal to be distorted and reduces the fidelity of the amplifier. Amplifiers must provide the proper balance of gain and fidelity.

Figure 1-17 shows the way in which feedback can be used to provide the maximum output signal without a loss in fidelity. In view A, an amplifier has good fidelity, but less gain than it could have. By adding some positive feedback, as in view B, the gain of the stage is increased. In view C, an amplifier has so much gain and such a large input signal that the output signal is distorted. This distortion is caused by the amplifying device becoming saturated and cutoff. By adding a negative feedback system, as in view D, the gain of the stage is decreased and the fidelity of the output signal improved.


Feedback uses in amplifiers
Figure 1-17A.-Feedback uses in amplifiers.


1-19


Feedback uses in amplifiers
Figure 1-17B.—Feedback uses in amplifiers.


Feedback uses in amplifiers
Figure 1-17C.—Feedback uses in amplifiers.


Feedback uses in amplifiers
Figure 1-17D.—Feedback uses in amplifiers.

  
Positive and negative feedback are accomplished in many ways, depending on the reasons requiring the feedback. A few of the effects and methods of accomplishing feedback are presented next.

Positive Feedback

As you have seen, positive feedback is accomplished by adding part of the output signal in phase with the input signal. In a common-base transistor amplifier, it is fairly simple to provide positive feedback. Since the input and output signals are in phase, you need only couple part of the output signal back to the input. This is shown in figure 1-18.


1-20