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Converter Fundamentals
James Bryant
University of Leicester
March 2003
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Converters
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The Size of an LSB
THE SIZE OF AN LSBRESOLUTION
(N) 2N Voltage
(10 V FS)ppm FS % FS dB FS
2-bit 4 2.5 V 250,000 25 -124-bit 16 625 mV 62,500 6.25 -246-bit 64 156 mV 15,625 1.56 -368-bit 256 39.1 mV 3,906 0.39 -48
10-bit 1,024 9.77 mV (10 mV) 977 .098 -6012-bit 4,096 2.44 mV 244 .024 -7214-bit 16,384 610 µV 61 .0061 -8416-bit 65,536 153 µV 15 .0015 -9618-bit 262,144 38 µV 4 .0004 -10820-bit 1,048,576 9.54 µV (10 µV) 1 .0001 -12022-bit 4,194,304 2.38 µV .24 .000024 -13224-bit 16,777,216 596 nV (.6 µV)* .06 .000006 -144
*600 nV is the Johnson noise in a 10 KHz bandwidth of a 2.2 K resistor at room temperature (300 K)
(A simple technique to memorise this table is to remember that at10-bits and 10 V FS an lsb is approximately 10 mV, 1,000 ppm or 0.1%.
All other values may be calculated by powers of 2.)
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Ideal Transfer Characteristics
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Quantization Uncertainty
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Unipolar & Bipolar Converters
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Offset & Gain Error
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Linearity Error Measurement
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Differential Non-Linearity (DNL)
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Combined Effects of Transition Noise & DNL
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Sampled Data Systems
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DAC Settling Time
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DAC Transitions
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Harmonic Distortion
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Intermodulation Distortion
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Third Order Intercept Point
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Quantization Noise
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Large Signal Bandwidth
With small signals, the bandwidth of a circuit is limited by its overall frequency response.
At high levels of signal, the slew rate of some stage (generally the output stage) may control the upper frequency limit.
In amplifiers, there are so many variables that “Large Signal Bandwidth” needs to be redefined in every individual case and “slew rate” is a more useful parameter for a data sheet.
In ADCs, the maximum signal swing is the ADC’s full-scale span, and is therefore defined so “Full Power Bandwidth may appear on the datasheet.
HOWEVER, the “Full Power Bandwidth” specification says nothing about distortion levels. ENOB is much more useful in practical applications
(If “Full Power Bandwidth” is specified and ENOB is not, somebody is probably trying to hide something!)
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ENOB
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SNR Due to Sampling Clock Jitter
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Components for Data Converters
Data Converters require: Good logic Good switches Good analog circuitry (amplifiers, comparators and
references) Good resistors
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Hybrid Converters
Early Data Converters used hybrid technology to achieve performance unavailable from any single monolithic technology.
Even today, some of the best converters cannot use any available monolithic technology and are hybrid
“Compound Monolithic” is a marketer’s term for a simpler (and cheaper) hybrid technology where two monolithic chips from different technologies are mounted together in a single package, but without a ceramic substrate or other components.
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Monolithic Converter Processes
Bipolar processes have good analog performance but less good logic and switches.
CMOS processes make excellent logic and switches but relatively poor amplifiers and lousy references.
Processes combining the two (BIMOS , LCCMOS, etc.) tend to be more complex and expensive and have slightly less performance than the sum of the two but are very convenient.
Good designers choose the best process for the circuit to be designed.
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Thin Film Resistors
One of the key technologies for making many types of monolithic data converters is the ability to deposit accurate, stable SiCr resistors on monolithic chips.
Some converters use these resistors as fabricated; others require the additional accuracy and economy of laser trimming.
Parameters include matching to 0.005%, TC<20 ppm, Diff TC<0.2 ppm, and long term stability of the order of
1 ppm/1000 hours (drunkard’s walk).
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Changeover Switches
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Kelvin Dividers
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Simplest Current OP DAC
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Segmented Voltage DACs
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Current Segment 4-Bit DAC
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Binary Weighted DAC
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DAC Using Cascaded Binary Quads
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4-Bit R-2R Ladder Network
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Voltage-Mode Ladder Network DAC
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Current-Mode Ladder Network DAC
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Multiplying DACs (MDACs)
In all DACs, the output is the product of the reference voltage and the digital code.
Most DACs work only over a limited range of reference voltages
DACs which work with reference voltages which include zero volts are known as multiplying DACs
Many MDACs work with bipolar and AC references
DACs which work with a large range of reference voltages, but not down to zero, are not true MDACs but are sometimes called MDACs. It is better to use the term “semi-multiplying DACs.”
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“Segmented Ladder” DAC
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Audio DAC with Offset MSB Transition
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Sigma-Delta DAC
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Double-Buffered DAC
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Serial DACs
If data is loaded serially into a DAC, it requires fewer data pins.
This saves space and also reduces capacitive noise coupling from data lines to the analog output .
If the shift register of a serial DAC has an output pin, a number of DACs may be connected in series (“daisy-chained”) to a single serial data port
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Types of Analog-to-Digital Converters
Comparator: 1-bit ADC
Flash: Fast, low-resolution, power-hungry
Magamp: A new architecture with lower power and complexity but speed approaching that of
a flash ADC
Subranging: Quite fast, high-resolution, complex
Integrating: Slow, accurate, low-power
VFC: High-resolution, low-power, ideal fortelemetry
Tracking: Fast and slow, high-resolution
Successive Approximation: Versatile, general purpose
Sigma Delta: Complex, low-power, very accurate
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Beware of ADC Logic Pitfalls!
After power-up, one or two conversions may be necessary before the ADC runs right. EOC cannot always be trusted at this time. An ADC may not behave the same way every time it starts.
EOC says conversion is finished. DRDY says that data is valid. There may be tens of nS difference between the two.
CS may not just enable the data--it may reset things for the next conversion. In some converters, you can’t not read the data. In some converters you can’t read the data twice. In some converters, you can’t strap CS and forget it. FIND OUT WHAT SORT YOU’RE USING.
ALWAYS READ THE DATASHEET, OR ELSE...ALWAYS READ THE DATASHEET, OR ELSE...
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Comparators
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Flash or Parallel ADCs
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Flash ADC Input Model and Its Effect on ENOB
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OUTPUT
-FS +FS0
INPUT
+FS
0
-FS
Fig. 1. TRANSFER CHARACTERISTIC OF X1 AMPLIFIER
Mag Amps 1
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Mag Amps 1b
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Fig. 2. TRANSFER CHARACTERISTIC OF FULL WAVE RECTIFIER
FULL-WAVE RECTIFIER
X2
-FS
OUTPUT
-FS +FS0
INPUT
+FS
0
-FS
PLUS X2 AMPLIFIERPLUS HALF-SCALE OFFSETPLUS COMPARATORTHIS ARRANGEMENT IS KNOWN AS A MAGNITUDE AMPLIFIEROR MAGAMP
Mag Amps 2
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OUTPUT
-FS +FS0
INPUT
+FS
0
-FS
Fig. 3A. TRANSFER CHARACTERISTICS OF CASCADED MAGAMPSIf we cascade several magamps, connecting the analog OP of each to the IP of the next, the transfercharacteristic between the first input and the various analog outputs will be as shown.
Mag Amps 3
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OUTPUT
-FS +FS0
INPUT
+FS
0
-FS
Fig. 3B. TRANSFER CHARACTERISTICS OF CASCADED MAGAMPSIf we cascade several magamps, connecting the analog OP of each to the IP of the next, the transfercharacteristic between the first input and the various analog outputs will be as shown.
Mag Amps 4
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OUTPUT
-FS +FS0
INPUT
+FS
0
-FS
Fig. 3C. TRANSFER CHARACTERISTICS OF CASCADED MAGAMPSIf we cascade several magamps, connecting the analog OP of each to the IP of the next, the transfercharacteristic between the first input and the various analog outputs will be as shown.
Mag Amps 5
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OUTPUT
-FS +FS0
INPUT
+FS
0
-FS
Fig. 3D. TRANSFER CHARACTERISTICS OF CASCADED MAGAMPSIf we cascade several magamps, connecting the analog OP of each to the IP of the next, the transfercharacteristic between the first input and the various analog outputs will be as shown.
Mag Amps 6
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OUTPUT
-FS +FS0
INPUT
+FS
0
-FS
Fig. 4. AN A.D.C. USING CASCADED MAGAMPSIf we look at the digital (comparator) outputs of cascaded magamps(and the output of a comparator on the original input line) we findthat we have an ADC with a Gray Code output representing thevalue of the voltage on this original input line.
Mag Amps 7
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Fig. 5A. AN A.D.C. USING CASCADED MAGAMPSWITH DIGITAL DELAYS TO SYNCHRONISE O/P DATA.Fig. 4 did not consider timing. There is a delay through each magamp.The timing problems arising from these delays may be addressed inseveral different ways. In this diagram digital delays in the data linesgive a parallel digital output with minimal data skew.
DLA x1
DLA x 2
DLA x 3
DLA x 4
Mag Amps 8
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Fig. 5B. AN A.D.C. USING CASCADED MAGAMPSWITH PIPELINED SHA's AND SHIFT REGISTERSTOSYNCHRONISE O/P DATA.Fig. 4 did not consider timing. There is a delay through each magamp.The timing problems arising from these delays may be addressed inseveral different ways. In this diagram clocked digital delays in the datalines (shift registers) and SHAs between the MAGAMPS give a paralleldigital output with no data skew, but a pipeline delay of N-1 clock cyclesfor an N-bit converter.
SHA SHA SHA
S/R
S/R
S/RS/R
S/R
S/R
MAG-AMP
MAG-AMP
MAG-AMP
CONVERSIONCLOCK
Mag Amps 9
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Subranging (Half-Flash) ADC
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Subranging ADC with Digital Error Correction
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Integrating ADC
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Integrating ADC
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VFCs
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Current-Steering VFC
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Charge-Balance VFC
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Synchronous VFC
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VFC & SVFC Waveforms
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SVFC Non-Linearity
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VFCs
It is possible to use the PERIOD of a VFC, rather than its frequency, to measure its input
VFCs have other applications than as ADC elements: these include isolation and use as FVCs
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Tracking ADCs
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Successive Approximation ADCs
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Successive Approximation ADCs
In modern successive approximation, ADCs the DAC is frequently constructed from capacitors (this is called a charge redistribution DAC).
The architecture is smaller, cheaper, faster and easier to manufacture than traditional resistive DACs but capacitor leakage may (not always) necessitate a minimum clock rate
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Sigma-Delta ADCs have a very high resolution, and they’re very cheap.
But the theory of the operation is hard.
Their bandwidth is not marvellous either.
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Sampling ADC Quantization Noise
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Oversampling and Filtering Improves ENOB
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First-Order ADC
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Modulators Shape Quantization Noise
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Second-Order ADC
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Bandpass ADCs
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Sample-Hold Amplifiers (SHAs)
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MicroConverterTM Definition
High Performance Analog I/O
+
FLASH Memory
+
Microcontroller
=
MicroConverterMicroConverterTMTMMicroConverterMicroConverterTMTM
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Introducing the ADuC812
12bit,8ch ADC & dual 12bit DAC
+
8Kbyte Program & 640byte Data FLASH
+
Industry Standard 8052
=
ADuC812ADuC812ADuC812ADuC812
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ADuC812 - Analog I/O
8channel, 12bit, 5µs, Autocalibrating ADC DMA Controller for High Speed Capture True 12bit Performance (INL, SNR, etc.)
Two 12bit, 4µs, Voltage Output DACs Guaranteed 12bit Monotonicity
On-Chip 2.5V Precision Bandgap Reference
On-Chip Temperature Sensor
Simple ADC & DAC Control Through Software or Hardware
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ADuC812 - Flash Memory
RETAIN DATA WITHOUT POWER!
8Kbytes Nonvolatile Program Memory Stores Program and Fixed Lookup Tables In-Circuit Serial Programmable or External Parallel
Programmable
640bytes Nonvolatile Data Memory User “Scratch Pad” for Storing Data During Program Execution Simple Read/Write Access Through SFR Space
Built-In Security Features for Both Program & Data FLASH
Programming Voltage (VPP) Generated On-Chip
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ADuC812 - Microcontroller
Industry Standard 8052 Core 12 Clock Machine Cycle w/ up to 16MHz Clock 32 Digital I/O Pins Three 16bit Counter/Timers UART Serial Port
...Plus Some Useful Extras SPI or I2C Compatible Serial Interface WatchDog Timer Power Supply Monitor
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References
[1] "HIGH SPEED SEMINAR" ANALOG DEVICES INC. 1990 $20
[2] "MIXED SIGNAL SEMINAR" ANALOG DEVICES INC. 1991 $20
[3] "1992 AMPLIFIER APPLICATIONS GUIDE" ANALOG DEVICES INC. 1992 $20
[4] "DATA CONVERTER REFERENCE MANUAL (VOL II)" ANALOG DEVICES INC. (FREE)
[5] APPLICATION NOTE: "FREQUENCY-VOLTAGE CONVERTERS" BY JAMES M. BRYANT (IN PREPARATION)
ANALOG DEVICES INC. (FREE WHEN AVAILABLE - TYPESCRIPT ALREADY AVAILABLE FROM JAMES BRYANT)
[6] "A 4TH-ORDER BANDPASS SIGMA-DELTA MODULATOR" S.A.JANTZI, M.SNELGROVE & P.F.FERGUSON JR.
PROCEEDINGS OF THE IEEE 1992 CUSTOM INTEGRATED CIRCUITS CONFERENCE. PP 16.5.1-4
[7] "ANALOG-DIGITAL CONVERSION HANDBOOK" DANIEL H. SHEINGOLD (ED.) PRENTICE-HALL, 3RD EDITION. 1986