4 interfacing
TRANSCRIPT
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Interface Circuits:
Hooking Up To TheOutside World
Prof. Greg Kovacs
Department of Electrical Engineering
Stanford University
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EE122, Stanford University, Prof. Greg Kovacs 2
Design Note: The Design Process
• Definition of function - what you want.
• Block diagram - translate into circuit functions.
• First Design Review.
• Circuit design - the details of how functions areaccomplished.
– Component selection– Schematic– Simulation– Prototyping of critical sections
• Second Design Review.
• Fabrication and Testing.
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EE122, Stanford University, Prof. Greg Kovacs 3
Interface Circuits
• Interface circuits “connect” between conventionalelectronic circuits (op-amps, logic, etc.) to theoutside world.
• They include circuits to buffer, amplify, andprocess sensor signals - INPUT of information.
• Also, they can include circuits to drive actuators,relays, etc. - OUTPUT of information.
• In general, they translate between the “volts andmilliamps” of conventional circuits and theirequivalents within several orders of magnitude.
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EE122, Stanford University, Prof. Greg Kovacs 4
Power Driver Circuits
• There are a variety of devices that one might wantto drive that require more current or highervoltages than inexpensive op-amps can produce.
• Of course, one solution is to purchase “specialty”op-amps with high current or high voltageoutputs.
• However, it is very useful to know how to extendthe capabilities of op-amp (and logic circuit)outputs to avoid this, particularly when the moreexpensive approach is not warranted.
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EE122, Stanford University, Prof. Greg Kovacs 5
Power Transistors/Heatsinks
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EE122, Stanford University, Prof. Greg Kovacs 6
Unipolar Power Switches
• For many output devices, one simply needs toswitch a drive voltage on and off.
• In this case, one can use a bipolar powertransistor with sufficient current gain (or aDarlington configuration) or a power MOSFET.
• Today, the most efficient choice is usually theMOSFET.
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EE122, Stanford University, Prof. Greg Kovacs 7
Basic Switch• Can use BJT or
MOSFET.
• If loads areinductive, needflyback protectdiode.
• Can drive directlyfrom TTL/CMOSlogic instead(want logic-driveMOSFET or BJT).
• Use current-limitresistor for BJT.
V1
V
V-
+
V2
FlybackProtectDiode
Rg
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EE122, Stanford University, Prof. Greg Kovacs 8
Example Flyback CircuitV+
High voltagepulses out!
2N34401 kΩ
30 mH
Pulse Source
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EE122, Stanford University, Prof. Greg Kovacs 9
IRLZ-34 Logic-Level MOSFET60V, 30A, 0.05
5V VGS
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Relay
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EE122, Stanford University, Prof. Greg Kovacs 11
Pulse-Width Modulation• Pulse-width modulation, or
PWM, offers a simple,DIGITAL output way ofmodulating power.
• The idea is to vary the dutycycle of pulses from zeroto 100% and if the timeconstants of the devicebeing driven are muchlonger than the pulsetimes, a low-pass filteredequivalent power isobtained.
10%
50%
90%
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EE122, Stanford University, Prof. Greg Kovacs 12
Random PWM Ideas
SG3525A/SG3527A
LM3524
Dedicated PWM Chips
Source:NationalSemiconductorLinear 3Databook
TriangleWave
GeneratorV
V-
+
VMOD
VOUT
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DC Motors
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Bipolar Power Switches
V+
LoadDrive Drive
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Modern Vacuum Tube Audio
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Power Inverters
• Digital drive totransformer togenerate higher orlower voltage.
• Can use to powerfluorescent lights, ACappliances, or togenerate higher DCvoltages (needrectifier and filter).
• Can make negativesupply rail.
V+
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MOSFET Power Driver
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HV Inverter
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FashionStatement
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Power Voltage Sources
• In some cases, a “beefy” and variable voltagesource is needed (e.g., audio power amplifiers,signal generator outputs, power supplies, etc.)
• In this case, one can either purchase power op-amps and use them in the standardconfigurations, or use power booster circuits withconventional, low-cost op-amps.
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EE122, Stanford University, Prof. Greg Kovacs 21
THE COMPLEMENTARY EMITTERFOLLOWER AMPLIFIER
("PUSH-PULL")• A COMPLEMENTARY PAIR OF
TRANSISTORS ARRANGED ASTWO EMITTER FOLLOWERS CANPROVIDE LOTS OF POWER WITHINEXPENSIVE PARTS!
• VERY EFFICIENT(APPROXIMATELY 80%)
• CAN ALSO PROVIDE ADISTORTED SIGNAL DUE TOCROSSOVER DISTORTION…
• CAN DO THE SAME WITHMOSFETS
-VCC
+VCC
Vin
Vout
THIS IS A "CLASS B" CIRCUIT
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CROSSOVER DISTORTION
-VCC
+VCC
Vin
Vout
• THERE IS A +/- 0.7 V"DEADBAND"WITHIN WHICH THENEITHERTRANSISTOR ISCONDUCTING...
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A CLOSE LOOK AT THE DISTORTION
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OUTPUT SPECTRUM OF CLASS AAMPLIFIER WITH CROSSOVER DISTORTION
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REDUCING CROSSOVER DISTORTIONWITH BIASING DIODES...
-VCC
+VCC
Vin
Vout THIS IS A "CLASS AB" CIRCUIT
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BETTER PERFORMANCE WITHFEEDBACK!
MAGIC SWITCH
R1
R2
-VCC
+VCC
Vin
Vout
• THE +/- 0.7V DEADBAND ISREDUCED TO
• THE SLEW-RATE LIMITATIONS OFTHE OP-AMP MEAN THAT THISDEADBAND WILL STILL BEAPPARENT AT HIGHFREQUENCIES....
± 0.7AVO
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HAYES & HOROWITZ SAY....
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SEE ANY DISTORTION?
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OUTPUT SPECTRUM OF THE SAMEPUSH-PULL AMPLIFIER WITH FEEDBACK
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Peltier Devices
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BeerCooler
#2
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The Bridge Configuration
Source: NationalSemiconductor LM12Application Note.
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High Voltage Amplifiers• For high voltage op-
amp applications,recent pricereductions in HV op-amps make itpossible to usestandardconfigurationseasily.
• www.apexmicrotech.com is a goodsource of chips andapplication notes.
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Current Sources/Sinks/Pumps
• Many transducers require current sources to drivethem (e.g., electromagnetic coils in some settings,lasers, LEDs, etc.).
• There are several simple current driver circuitsthat use op-amps to provide closed-loop control,and the high output impedances required.
• The basic principle is to sense the sourced (orsunk) current and convert it into a signal forfeedback purposes.
• If the desired currents exceed the capabilities ofthe op-amp, external “pass” transistors are used.
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Classic Op-Amp Current Sink
V+
VIN
RF
Load
IL
IL =VIN
RF
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Beer-Locked-Loop
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Types of Sensors
• Electromagnetic Coils
• Strain Gauges
• Accelerometers
• Microphones
• Optical (covered elsewhere)
• Temperature Sensors
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Sensor Signal Processing
• Typical sensor signal processing involves(pre)amplification, filtering and sometimes somedownstream functions.
• Downstream functions may include a comparator(decision) or A/D converter, sometimes precededby a sample-and-hold circuit.
• In some cases (not covered in EE122), the sensorsignal (before or after digitization) is transmittedto another location using telemetry.
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LM334 Temperature Sensor
Source: Linear TechnologyLM334 Datasheet.
Note that current-output sensors allow quite longwire lengths, since they are pretty muchinsensitive to cable resistance.
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EE122, Stanford University, Prof. Greg Kovacs 41
Transresistance Amplifiers
• Transresistanceamplifiers simplytranslate currentfrom a sensor into anoutput voltage.
• They are justinverting amplifierswithout the inputresistor. Thetransresistance gainis given in OHMS.
Rf
V
V-
+
V+
Vout
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Transresistance Frequency Response
• Quite often, high DCgain is desiredwithout much ACgain or controlledroll-off.
• These are twoexample approachesto achieve suchcharacteristics.
• In practice the topcircuit is most oftenused.
RF
C1
VOUT
V
V-
+iin
RP
RF
C1
VOUT
V
V-
+i in
AR = −R f
1
R f CS + 1
AR = −RPR fCS + R f
CS R f + RP( ) +1
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EE122, Stanford University, Prof. Greg Kovacs 43
New Concepts to Enhance Productivity
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More on Instrumentation Amplifiers
LT1167AD620
Buffered voltagedivider to set“ground.”
Source: Analog Devices andLinear TechnologyDatasheets.
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Nerve Impulse Amplifier
This circuit amplifies the low levelnerve impulse signals received from a patient at Pins 2and 3. RG and the parallel combination of R3 and R4 seta gain of ten. The potential on LT1112’s Pin 1 creates aground for the common mode signal. C1 was chosen tomaintain thestabilityofthe patientground.TheLT1167’shigh CMRR ensures that the desired differential signal isamplified and unwanted common mode signals are at-tenuated. Since the DC portion of the signal is notimportant, R6 and C2 make up a 0.3Hz highpass filter.The AC signal at LT1112’s Pin 5 is amplified by a gain of101 set by (R7/R8) +1. The parallel combination of C3and R7 form a lowpass filter that decreases this gain atfrequencies above 1kHz. The ability to operate at ±3V on0.9mA of supply current makes the LT1167 ideal forbattery-powered applications. Total supply current forthis application is 1.7mA. Proper safeguards, such asisolation, must be added to this circuit to protect thepatient from possible harm.
Source: Linear TechnologyDatasheet.
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EE122, Stanford University, Prof. Greg Kovacs 46
Switched Capacitor Filters
• It is possible to buildanalog filters where insteadof resistors to make RCtime constants, analogswitches and capacitorsare used to “simulate”resistances.
• In some filter types (state-variable or biquad), builtwith integrators, theintegrator gain controls thecutoff frequency -therefore, you can sweepthe cutoff frequency withthe clock frequency!
R1
C1
VOUT
V
V-
+
VIN
iin
C2
VOUT
V
V-
+
VIN
C1
Clock
Vout = −1
R1C1
Vindt∫
Vout = − fclock
C1
C2
Vindt∫
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LTC1064 Switched Capacitor Filter
Source: Linear TechnologyLTC1064 Datasheet.
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Analog Multipliers
• These devices can be usedfor modulation (AM), basicmultiplication, and a varietyof other functions.
• The AD633 is a particularlyeasy to use chip.
Source: Analog DevicesDatasheet.
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More AD633 StuffSquaring Circuit
Square Root Circuit
(Note errors!)
Source: Analog DevicesDatasheet.
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Squarer
sin2 t( ) =1
21− cos 2 t( )( )
AD 633
Vsupply = ± 15V
Input f = 200 kHz
Output f = 400 kHz
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Triangle Wave Input
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More AD633 Stuff
Amplitude Modulator
Divider Circuit
Source: Analog DevicesDatasheet.
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TremoloBox
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Multipliersin Filters
Voltage ControlledFilter Circuits
Divider Circuit
Source: Analog DevicesDatasheet.
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Example:Cheesy
Accelerometer
Gluing a 6-32 nutonto aninexpensivepiezoelectricbuzzer yields acheesy, butfunctionalaccelerometer.
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Cheesy Peak-Reading Accelerometer
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Voltage-to-Frequency Converters
Source: NationalSemiconductorLM331 Datasheet.
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Voltage-to-Frequency Converters
Source: NationalSemiconductorLM331 Datasheet.
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Temperature-To-Frequency
Source: NationalSemiconductorLM331 Datasheet.
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Frequency-to-Voltage Converters
Source: NationalSemiconductorLM331 Datasheet.