AD AD9203-EB

a
FEATURES
CMOS 10-Bit 40 MSPS Sampling A/D Converter
Power Dissipation: 74 mW (3 V Supply, 40 MSPS)
17 mW (3 V Supply, 5 MSPS)
Operation Between 2.7 V and 3.6 V Supply
Differential Nonlinearity: ⴞ0.25 LSB
Power-Down (Standby) Mode, 0.65 mW
ENOB: 9.55 @ fIN = 20 MHz
Out-of-Range Indicator
Adjustable On-Chip Voltage Reference
IF Undersampling up to fIN = 130 MHz
Input Range: 1 V to 2 V p-p Differential or Single-Ended
Adjustable Power Consumption
Internal Clamp Circuit
APPLICATIONS
CCD Imaging
Video
Portable Instrumentation
IF and Baseband Communications
Cable Modems
Medical Ultrasound
PRODUCT DESCRIPTION
The AD9203 is a monolithic low power, single supply, 10-bit,
40 MSPS analog-to-digital converter, with an on-chip voltage
reference. The AD9203 uses a multistage differential pipeline
architecture and guarantees no missing codes over the full operating temperature range. Its input range may be adjusted between 1 V and 2 V p-p.
The AD9203 has an onboard programmable reference. An
external reference can also be chosen to suit the dc accuracy and
temperature drift requirements of an application.
An external resistor can be used to reduce power consumption
when operating at lower sampling rates. This yields power savings for users who do not require the maximum sample rate.
This feature is especially useful at sample rates far below 40
MSPS. Excellent performance is still achieved at reduced power.
For example, 9.7 ENOB performance may be realized with only
17 mW of power, using a 5 MHz clock.
A single clock input is used to control all internal conversion
cycles. The digital output data is presented in straight binary or
twos complementary output format by using the DFS pin. An
out-of-range signal (OTR) indicates an overflow condition that
can be used with the most significant bit to determine over or
under range.
10-Bit, 40 MSPS, 3 V, 74 mW
A/D Converter
AD9203
FUNCTIONAL BLOCK DIAGRAM
CLK
AVDD
DRVDD
CLAMP
AD9203
CLAMPIN
AINP
STBY
A/D
AINN
SHA
A/D
GAIN
D/A
SHA
A/D
REFTF
GAIN
3 STATE
D/A
CORRECTION LOGIC
REFBF
BANDGAP
REFERENCE
OTR
OUTPUT BUFFERS
10
D9 (MSB)
VREF
REFSENSE
0.5V
+
–
AVSS
D0 (LSB)
PWRCON
DFS
DRVSS
The AD9203 is specified over industrial (–40°C to +85°C)
temperature ranges and is available in a 28-lead TSSOP
package.
PRODUCT HIGHLIGHTS
Low Power
The AD9203 consumes 74 mW on a 3 V supply operating at
40 MSPS. In standby mode, power is reduced to 0.65 mW.
High Performance
Maintains better than 9.55 ENOB at 40 MSPS input signal
from dc to Nyquist.
Very Small Package
The AD9203 is available in a 28-lead TSSOP.
Programmable Power
The AD9203 power can be further reduced by using an external
resistor at lower sample rates.
Built-In Clamp Function
Allows dc restoration of video signals.
The AD9203 can operate with a supply range from 2.7 V to
3.6 V, attractive for low power operation in high speed portable applications.
REV. 0
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 1999
(AVDD = +3 V, DRVDD = +3 V, FS = 40 MSPS, input span from 0.5 V to 2.5 V, Internal 1 V
MIN to TMAX unless otherwise noted.)
AD9203–SPECIFICATIONS Reference, PWRCON = AVDD, 50% clock duty cycle, T
Parameter
Symbol
Min
RESOLUTION
MAX CONVERSION RATE
Typ
10
FS
40
ANALOG INPUT
Input Voltage Range
Input Capacitance
Aperture Delay
Aperture Uncertainty (Jitter)
Input Bandwidth (–3 dB)
Input Referred Noise
INTERNAL REFERENCE
Output Voltage (0.5 V Mode)
Output Voltage (1 V Mode)
Output Voltage Tolerance (1 V Mode)
Load Regulation
POWER SUPPLY
Operating Voltage
Analog Supply Current
Digital Supply Current
AIN
CIN
TAP
TAJ
BW
AVDD
DRVDD
IAVDD
IDRVDD
2.7
2.7
Power Consumption
Power-Down
Power Supply Rejection Ratio
DYNAMIC PERFORMANCE
(AIN = 0.5 dBFS)
Signal-to-Noise and Distortion
f = 4.8 MHz
f = 20 MHz
Effective Bits
f = 4.8 MHz
f = 20 MHz
Signal-to-Noise Ratio
f = 4.8 MHz
f = 20 MHz
Total Harmonic Distortion
f = 4.8 MHz
f = 20 MHz
Spurious Free Dynamic Range
f = 4.8 MHz
f = 20 MHz
Two-Tone Intermodulation Distortion
Differential Phase
Differential Gain
DIGITAL INPUTS
High Input Voltage
Low Input Voltage
Clock Pulsewidth High
Clock Pulsewidth Low
Clock Period2
5.5
Clock Cycles
± 0.7
± 1.4
± 2.8
± 4.0
LSB
LSB
% FSR
% FSR
2
1.4
2.0
1.2
390
0.3
V p-p
pF
ns
ps rms
MHz
mV
0.5
1
±5
0.65
± 30
1.2
V
V
mV
mV
3.0
3.0
20.1
4.4
9.5
74
88.8
0.65
0.04
3.6
3.6
22.0
6.0
14.0
84.0
108.0
1.2
± 0.25
V
V
mA
mA
mA
mW
mW
mW
% FS
1
VREF
VREF
PD
PSRR
Conditions
MSPS
± 0.25
± 0.65
± 0.6
± 0.7
DNL
INL
EZS
EFS
Units
Bits
PIPELINE DELAY
DC ACCURACY
Differential Nonlinearity
Integral Nonlinearity
Offset Error
Gain Error
Max
SINAD
Switched, Single-Ended
REFSENSE = VREF
REFSENSE = GND
1.0 mA Load
fIN = 4.8 MHz, Output Bus Load = 10 pF
fIN = 20 MHz, Output Bus Load = 20 pF
fIN = 4.8 MHz, Output Bus Load = 10 pF
fIN = 20 MHz, Output Bus Load = 20 pF
Note 1
57.2
59.7
59.3
dB
dB
9.2
9.6
9.55
Bits
Bits
57.5
60.0
59.5
dB
dB
–76.0
–74.0 –65.0
dB
dB
Note 1
80
78
68
0.2
0.3
dB
dB
dB
Degree
%
Note 1
ENOB
Note 1
SNR
THD
SFDR
67.8
IMD
DP
DG
VIH
VIL
2.0
0.4
11.25
11.25
25
–2–
f = 44.49 MHz and 45.52 MHz
NTSC 40 IRE Ramp
V
V
ns
ns
ns
REV. 0
AD9203
Parameter
Symbol
DIGITAL OUTPUTS
High-Z Leakage
Data Valid Delay
Data Enable Delay
Data High-Z Delay
IOZ
tOD
tDEN
tDHZ
LOGIC OUTPUT (with DRVDD = 3 V)
High Level Output Voltage (I OH = 50 µA)
High Level Output Voltage (IOH = 0.5 mA)
Low Level Output Voltage (IOL = 1.6 mA)
Low Level Output Voltage (IOL = 50 µA)
VOH
VOH
VOL
VOL
Min
Typ
Max
Units
Conditions
± 5.0
µA
ns
ns
ns
Output = 0 to DRVDD
CL = 20 pF
CL = 20 pF
CL = 20 pF
5
6
6
+2.95
+2.80
V
V
V
V
+0.3
+0.05
NOTES
1
Differential Input (2 V p-p).
2
The AD9203 will convert at clock rates as low as 20 kHz.
Specifications subject to change without notice.
N+1
N
ANALOG
INPUT
N+2
N–1
N+3
N+4
N+6
N+5
CLOCK
DATA
OUT
N–7
N–6
N–5
N–4
N–3
N–2
TOD = 3ns MIN
7ns MAX
(CLOAD = 20pF)
Figure 1. Timing Diagram
REV. 0
–3–
N–1
N
N+1
AD9203
ABSOLUTE MAXIMUM RATINGS*
Parameter
AVDD
DRVDD
AVSS
AVDD
REFCOM
CLK
Digital Outputs
AINP
VREF
REFSENSE
REFTF, REFBF
STBY
CLAMP
CLAMPIN
PWRCON
DFS
3-STATE
Junction Temperature
Storage Temperature
Lead Temperature
(10 sec)
With
Respect
to
Min
AVSS
DRVSS
DRVSS
DRVDD
AVSS
AVSS
DRVSS
AINN
AVSS
AVSS
AVSS
AVSS
AVSS
AVSS
AVSS
AVSS
AVSS
–0.3
–0.3
–0.3
–3.9
–0.3
–0.3
–0.3
AVSS – 0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–65
THERMAL CHARACTERISTICS
Max
Units
+3.9
+3.9
+0.3
+3.9
+0.3
AVDD + 0.3
DRVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
+150
+150
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
V
°C
°C
+300
°C
28-Lead TSSOP
θJA = 97.9°C/W
θJC = 14.0°C/W
ORDERING GUIDE
Model
Temperature
Range
AD9203ARU –40°C to +85°C
AD9203-EB
Package
Description
Package
Option
28-Lead Thin Shrink RU-28
Small Outline
Evaluation Board
*Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the
device at these or any other conditions above those indicated in the operational
sections of this specification is not implied. Exposure to absolute maximum ratings
for extended periods may affect device reliability.
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the AD9203 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.
–4–
WARNING!
ESD SENSITIVE DEVICE
REV. 0
AD9203
PIN CONFIGURATION
DRVSS 1
28 AVDD
DRVDD 2
27 AVSS
(LSB) D0 3
26 AINN
D1 4
25 AINP
D2 5
24 REFBF
D3 6
AD9203
23 VREF
D4 7
TOP VIEW 22 REFTF
D5 8 (Not to Scale) 21 PWRCON
D6 9
20 CLAMPIN
D7 10
19 CLAMP
D8 11
18 REFSENSE
(MSB) D9 12
17 STBY
OTR 13
16 3-STATE
DFS 14
15 CLK
PIN FUNCTION DESCRIPTIONS
Pin
Name
Description
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
DRVSS
DRVDD
D0
D1
D2
D3
D4
D5
D6
D7
D8
D9
OTR
DFS
CLK
3-STATE
STBY
REFSENSE
CLAMP
CLAMPIN
PWRCON
REFTF
VREF
REFBF
AINP
AINN
AVSS
AVDD
Digital Ground
Digital Supply
Bit 0, Least Significant Bit
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Bit 8
Bit 9, Most Significant Bit
Out-of-Range Indicator
Data Format Select. (HI: Twos Complement. LO: Straight Binary)
Clock Input
HI: High Impedance State Output. LO: Active Digital Output Drives
HI: Power-Down Mode. LO: Normal Operation
Reference Select
HI: Enable Clamp. LO: Open Clamp
Clamp Signal Input
Power Control Input
Top Reference Decoupling
Reference In/Out
Bottom Reference Decoupling
Noninverting Analog Input
Inverting Analog Input
Analog Ground
Analog Supply
REV. 0
–5–
AD9203
DEFINITIONS OF SPECIFICATIONS
SPURIOUS FREE DYNAMIC RANGE (SFDR)
INTEGRAL NONLINEARITY ERROR (INL)
The difference in dB between the rms amplitude of the input
signal and the peak spurious signal.
Linearity error refers to the deviation of each individual code
from a line drawn from “negative full scale” through “positive
full scale.” The point used as “negative full scale” occurs
1/2 LSB before the first code transition. “Positive full scale” is
defined as a level 1 1/2 LSB beyond the last code transition.
The deviation is measured from the middle of each particular
code to the true straight line.
OFFSET ERROR
First transition should occur for an analog value 1/2 LSB above
–full scale. Offset error is defined as the deviation of the actual
transition from that point.
GAIN ERROR
The first code transition should occur at an analog value
1/2 LSB above –full scale. The last transition should occur for
an analog value 1 1/2 LSB below the +full scale. Gain error is
the deviation of the actual difference between first and last code
transitions and the ideal difference between first and last code
transitions.
DIFFERENTIAL NONLINEARITY ERROR (DNL, NO
MISSING CODES)
An ideal ADC exhibits code transitions that are exactly 1 LSB
apart. DNL is the deviation from this ideal value. Guaranteed
no missing codes to 10-bit resolution indicates that all 1024
codes respectively, must be present over all operating ranges.
SIGNAL-TO-NOISE AND DISTORTION (S/N+D, SINAD)
RATIO
POWER SUPPLY REJECTION
The specification shows the maximum change in full scale from
the value with the supply at the minimum limit to the value with
the supply at its maximum limit.
S/N+D is the ratio of the rms value of the measured input signal
to the rms sum of all other spectral components below the
Nyquist frequency, including harmonics but excluding dc.
The value for S/N+D is expressed in decibels.
APERTURE JITTER
EFFECTIVE NUMBER OF BITS (ENOB)
Aperture jitter is the variation in aperture delay for successive
samples and is manifested as noise on the input to the A/D.
For a sine wave, SINAD can be expressed in terms of the number of bits. Using the following formula,
APERTURE DELAY
Aperture delay is a measure of the Sample-and-Hold Amplifier
(SHA) performance and is measured from the rising edge of the
clock input to when the input signal is held for conversion.
N = (SINAD – 1.76)/6.02
it is possible to get a measure of performance expressed as N,
the effective number of bits.
PIPELINE DELAY (LATENCY)
Thus, effective number of bits for a device for sine wave inputs
at a given input frequency can be calculated directly from its
measured SINAD.
The number of clock cycles between conversion initiation and
the associated output data being made available. New output
data is provided on every rising edge.
TOTAL HARMONIC DISTORTION (THD)
THD is the ratio of the rms sum of the first six harmonic
components to the rms value of the measured input signal and
is expressed as a percentage or in decibels.
SIGNAL-TO-NOISE RATIO (SNR)
SNR is the ratio of the rms value of the measured input signal
to the rms sum of all other spectral components below the
Nyquist frequency, excluding harmonics and dc. The value for
SNR is expressed in decibels.
–6–
REV. 0
Typical Performance Characteristics– AD9203
(AVDD = +3 V, DRVDD = +3 V, FS = 40 MSPS, 1 V Internal Reference, PWRCON = AVDD, 50% Duty Cycle, unless otherwise noted)
85
61
80
2V SINGLE-ENDED INPUT
59
75
2V DIFFERENTIAL INPUT
1V DIFFERENTIAL
INPUT
70
SFDR – dB
SNR – dB
57
55
53
1V DIFFERENTIAL INPUT
65
1V SINGLEENDED INPUT
60
55
2V DIFFERENTIAL
INPUT
50
51
2V SINGLEENDED INPUT
45
49
40
1V SINGLE-ENDED INPUT
47
35
0
20
40
60
80
INPUT FREQUENCY – MHz
120
100
20
40
60
80
INPUT FREQUENCY – MHz
–75
55
–70
8.8
1V DIFFERENTIAL
INPUT
8.0
1V DIFFERENTIAL INPUT
THD – dB
50
ENOB
SINAD – dB
–65
7.1
1V SINGLEENDED INPUT
20
40
60
80
INPUT FREQUENCY – MHz
–55
1V SINGLEENDED INPUT
–50
–40
6.3
2V SINGLEENDED INPUT
0
2V DIFFERENTIAL
INPUT
–60
–45
40
35
120
–80
9.0
2V DIFFERENTIAL
INPUT
45
100
Figure 5. SFDR vs. Input Frequency and Configuration
Figure 2. SNR vs. Input Frequency and Configuration
60
0
2V SINGLEENDED INPUT
–35
100
5.5
120
–30
Figure 3. SINAD vs. Input Frequency and Configuration
0
20
40
60
80
INPUT FREQUENCY – MHz
100
120
Figure 6. THD vs. Input Frequency and Configuration
–75
–75
–70
–0.5dB
–0.5dB
–65
–65
THD – dB
THD – dB
–6.0dB
–60
–6.0dB
–55
–55
–20dB
–50
–45
–20dB
–45
–40
0
20
40
60
80
INPUT FREQUENCY – MHz
100
–35
120
Figure 4. THD vs. Input Frequency and Amplitude (Differential Input VREF = 0.5 V)
REV. 0
0
20
40
60
80
INPUT FREQUENCY – MHz
100
120
Figure 7. THD vs. Input Frequency and Amplitude (Differential Input VREF = 1 V)
–7–
AD9203
1.2E+07
1.0
0.8
10000000
1.0E+07
0.6
0.4
8.0E+06
LSB
HITS
0.2
6.0E+06
0.0
–0.2
4.0E+06
–0.4
–0.6
2.0E+06
–0.8
4560
0.0E+00
10310
N–1
N
–1.0
N+1
0
100
200
300
400
500
600
700
800
900
1024
CODE
Figure 11. Typical DNL Performance
Figure 8. Grounded Input Histogram
10.0
80
SNR = 59.9dB
THD = –75dB
SFDR = 82dB
0.0
75
–10.0
–THD
–20.0
70
–40.0
dB
+SNR/–THD – dB
–30.0
65
60
SNR
–50.0
–60.0
–70.0
55
–80.0
50
–90.0
–100.0
45
–110.0
40
0
10
20
30
40
SAMPLE RATE – MSPS
50
–120.0
0E+0 2.5E+6 5E+6 7.5E+6 10E+6 12.5E+6 15E+6 17.5E+6 20E+6
60
Figure 9. SNR and THD vs. Sample Rate (fIN = 20 MHz)
Figure 12. Single Tone Frequency Domain Performance
(Input Frequency = 10 MHz, Sample Rate = 40 MSPS 2 V
Differential Input, 8192 Point FFT)
1.0
80
0.8
75
0.6
–THD
+SNR/–THD – dB
0.4
LSB
0.2
0.0
–0.2
–0.4
70
65
60
SNR
–0.6
55
–0.8
–1.0
0
100
200
300
400
500
600
700
800
900
50
2.5
1024
Figure 10. Typical INL Performance
3.0
3.5
SUPPLY VOLTAGE – V
4.0
Figure 13. THD vs. Power Supply (fIN = 20 MHz, Sample
Rate = 40 MSPS)
–8–
REV. 0
AD9203
APPLYING THE AD9203
0
THEORY OF OPERATION
–1
The AD9203 implements a pipelined multistage architecture to
achieve high sample rates while consuming low power. The
AD9203 distributes the conversion over several smaller A/D
subblocks, refining the conversion with progressively higher
accuracy as it passes the results from stage to stage. As a consequence of the distributed conversion, the AD9203 requires a
small fraction of the 1023 comparators used in a traditional
10-bit flash-type A/D. A sample-and-hold function within each
of the stages permits the first stage to operate on a new input
sample while the remaining stages operate on preceding samples.
–2
AMPLITUDE – dB
–3
–4
–5
–6
–7
–8
Each stage of the pipeline, excluding the last, consists of a low
resolution flash A/D connected to a switched capacitor DAC
and interstage residue amplifier (MDAC). The residue amplifier
magnifies the difference between the reconstructed DAC output
and the flash input for the next stage in the pipeline. One bit of
redundancy is used in each one of the stages to facilitate digital
correction of flash errors. The last stage simply consists of a
flash A/D.
–9
10
100
INPUT FREQUENCY – MHz
1000
Figure 14. Full Power Bandwidth
3500
The input of the AD9203 incorporates a novel structure that
merges the input sample and hold amplifier (SHA) and the first
pipeline residue amplifier into a single, compact switched capacitor circuit. This structure achieves considerable noise and
power savings over a conventional implementation that uses
separate amplifiers by eliminating one amplifier in the pipeline.
By matching the sampling network of the input SHA with the
first stage flash A/D, the AD9203 can sample inputs well beyond
the Nyquist frequency with no degradation in performance.
3000
1V REFERENCE
WAKE-UP TIME – ms
2500
2000
0.5V REFERENCE
1500
1000
Sampling occurs on the falling edge of the clock.
500
0
200
0
400
600
OFF-TIME – ms
800
OPERATIONAL MODES
1000
The AD9203 may be connected in several input configurations
(see Table I).
Figure 15. Wake-Up Time vs. Off Time (VREF Decoupling
= 10 µ F)
The AD9203 may be driven differentially from a source that
keeps the signal peaks within the power supply rails.
Alternatively, the input may be driven into AINP or AINN from
a single-ended source. The input span will be 2× the programmed
reference voltage. One input will accept the signal, while the
opposite input will be set to midscale by connecting it to the
internal or an external reference. For example, a 2 V p-p signal
may be applied to AINP while a 1 V reference is applied to AINN.
The AD9203 will then accept a signal varying between 2 V and
0 V. See Figures 17, 18 and 19 for more details.
0.2
VREF ERROR – %
0.1
0
0.5V
–0.1
The AD9203’s single-ended (ac-coupled) input may also be
clamped to ground by the AD9203’s internal clamp switch. This
is accomplished by connecting the CLAMP pin to AINN or AINP.
1V
–0.2
Digital output formats may be configured in binary and twos
complement. This is determined by the potential on the DFS
pin. If the pin is set to Logic “0,” the data will be in straight
binary format. If the pin is asserted to Logic “1,” the data will be in
twos complement format.
–0.3
–0.4
–40
–20
0
20
40
TEMPERATURE – 8C
60
80
100
Figure 16. Reference Voltage vs. Temperature
REV. 0
Power consumption may be reduced by placing a resistor between PWRCON and AVSS. This may be done to conserve
power when not encoding high speed analog input frequencies
or sampling at the maximum conversion rate. See Power Control section.
–9–
AD9203
Table I. Modes
Name
Figure Number
Advantages
1 V Differential
2 V Differential
1 V Single-Ended
Figure 26 with VREF Connected to REFSENSE
Figure 26 with REFSENSE Connected to AGND
Figure 18
2 V Single-Ended
Figure 17
Differential Modes Yield the Best Dynamic Performance
Differential Modes Yield the Best Dynamic Performance
Video and Applications Requiring Clamping Require
Single-Ended Inputs
Video and Applications Requiring Clamping Require
Single-Ended Inputs
INPUT AND REFERENCE OVERVIEW
Like the voltage applied to the top of the resistor ladder in a
flash A/D converter, the value VREF defines the maximum
input voltage to the A/D core. The minimum input voltage to the
A/D core is automatically defined to be –VREF.
The addition of a differential input structure gives the user an
additional level of flexibility that is not possible with traditional
flash converters. The input stage allows the user to easily configure the inputs for either single-ended operation or differential
operation. The A/D’s input structure allows the dc offset of the
input signal to be varied independently of the input span of the
converter. Specifically, the input to the A/D core is the difference of the voltages applied at the AINP and AINN input
pins. Therefore, the equation,
VCORE = AINP – AINN
ADC will equal the twice voltage at the reference pin for both
an internal or external reference.
Figure 17 illustrates the input configured with a 1 V reference.
This will set the single-ended input of the AD9203 in the 2 V
span (2 × VREF). This example shows the AINN input is tied
to the 1 V VREF. This will configure the AD9203 to accept a
2 V input centered around 1 V.
2V
0V
AINN
REFTF
ADC
CORE
(1)
The voltage, VCORE, must satisfy the condition,
0.1mF
10mF
+
0.5V
0.1mF
–
(2)
where VREF is the voltage at the VREF pin.
REFSENSE
The actual span (AINP – AINN) of the ADC is ± VREF.
AVSS – 0.3 V < AINP < AVDD + 0.3 V
AVSS – 0.3 V < AINN < AVDD + 0.3 V
10mF
0.1mF
REFBF
1V
VREF
While an infinite combination of AINP and AINN inputs exist
that satisfy Equation 2, an additional limitation is placed on the
inputs by the power supply voltages of the AD9203. The power
supplies bound the valid operating range for AINP and AINN.
The condition,
2V
0.1mF
defines the output of the differential input stage and provides
the input to the A/D core.
–VREF ≤ VCORE ≤ VREF
AINP
LOGIC
AD9203
Figure 17. Internal Reference Set for a 2 V Span
(3)
Figure 18 illustrates the input configured with a 0.5 V reference.
This will set the single ended input of the ADC in a 1 V span
(2 × VREF). The AINN input is tied to the 0.5 VREF. This will
configure the AD9203 to accept a 1 V input centered around
0.5 V.
where AVSS is nominally 0 V and AVDD is nominally +3 V,
defines this requirement. The range of valid inputs for AINP
and AINN is any combination that satisfies both Equations 2
and 3.
1V
0V
AINP
AINN
REFTF 1.75V
0.1mF
INTERNAL REFERENCE CONNECTION
A comparator within the AD9203 will detect the potential of the
VREF pin. If REFSENSE is grounded, the reference amplifier
switch will connect to the resistor divider (see Figure 17). That
will make VREF equal to 1 V. If resistors are placed between
VREF, REFSENSE and ground, the switch will be connected to
the REFSENSE position and the reference amplitude will depend on the external programming resistors (Figure 19). If
REFSENSE is tied to VREF, the switch will also connect to
REFSENSE and the reference voltage will be 0.5 V (Figure 18).
REFTF and REFBF will drive the ADC conversion core and
establish its maximum and minimum span. The range of the
ADC
CORE
10mF
0.1mF
REFBF
1.25V
0.1mF
VREF
10mF
–10–
+
0.5V
0.1mF
–
LOGIC
REFSENSE
AD9203
Figure 18. Internal Reference Set for a 1 V Span
REV. 0
AD9203
Figure 19 shows the reference programmed by external resistors
for 0.75 V. This will set the ADC to receive a 1.5 V span centered about 0.75 V. The reference is programmed according to
the algorithm
CLAMP OPERATION
The AD9203 contains an internal clamp. It may be used when
operating the input in a single-ended mode. The AD9203’s
clamp is very useful for clamping NTSC and PAL video signals
to ground. The clamp cannot be used in the differential input
mode.
VREF = 0.5 V × [1 + (RA/RB)]
1.5V
0V
AINP
REFSENSE
AD9203
REFTF 1.875V
AINN
VREF
0.1mF
ADC
CORE
10mF
0.1mF
AINN
REFBF
1.125V
CIN
0.1mF
10mF
1V p-p
+
VREF
0Vdc
50V TYP
0.5V
0.1mF
ADC
CORE
AINP
CLAMP
IN
–
RA
CLAMP
LOGIC
AD9203
REFSENSE
SW1
RB
Figure 19. Programmable Reference Configuration
Figure 21. Clamp Configuration (VREF = 0.5 V)
Figure 21 shows the internal clamp circuitry and the external
control signals needed for clamp operation. To enable the clamp,
apply a logic high “1” to the CLAMP pin. This will close the
internal switch SW1. SW1 is opened by asserting the CLAMP
pin low “0.” The capacitor holds the voltage across CIN constant until the next interval. The charge on the capacitor will
leak off as a function of input bias current (see Figure 22).
EXTERNAL REFERENCE OPERATION
Figure 20 illustrates the use of an external reference. An external reference may be necessary for several reasons. Tighter
reference tolerance will enhance the accuracy of the ADC and
will allow lower temperature drift performance. When several
ADC’s track one another, a single reference (internal or external) will be necessary. The AD9203 will draw less power when
an external reference is used.
250
When the REFSENSE pin is tied to AVDD, the internal reference will be disabled, allowing the use of an external reference.
The AD9203 contains an internal reference buffer. It will load
the external reference with an equivalent 10 kΩ load. The internal buffer will generate positive and negative full-scale references
for the ADC core.
In Figure 20, an external reference is used to set the midscale
set point for single-ended use. At the same time, it sets the input
voltage span through a resistor divider. If the ADC is being
driven differentially through a transformer, the external reference can set the center tap (common-mode voltage).
INPUT BIAS – mA
200
150
100
50
0
–50
0
3.0V
2.0V
1.0V
+5V
AINP
AD9203
EXTERNAL
REF (2V)
0.1mF
0.1mF
1.5kV
VREF
A3
1V
0.1mF
1.5kV
AVDD
REFSENSE
Figure 20. External Reference Configuration
REV. 0
1
1.5
2
INPUT VOLTAGE – Volts
2.5
Figure 22. Input Bias Current vs. Input Voltage
(FS = 40 MSPS)
AINN
10mF
0.5
–11–
3
AD9203
DRIVING THE ANALOG INPUT
C1
Figure 23 illustrates the equivalent analog input of the AD9203,
(a switched capacitor input). Bringing CLK to a logic high,
opens S3 and closes S1 and S2. The input source connected
to AIN and must charge Capacitor CH during this time. Bringing CLK to a logic low opens S2, and then S1 opens followed
by closing S3. This puts the input in the hold mode.
R1
VIN
AIN
C2
AVDD/2
R2
+
VBIAS
=
AD9203
Figure 25. AC-Coupled Input
The f–3 dB point can be approximated by the equation:
f–3 dB = 1/(2 π × [R2] CEQ )
AD9203
S1
where CEQ is the parallel combination of C1 and C2. Note that
C1 is typically a large electrolytic or tantalum capacitor that
becomes inductive at high frequencies. Add a small ceramic or
polystyrene capacitor (on the order of 0.01 µF) that is negligibly
inductive at higher frequencies while maintaining a low impedance over a wide frequency range.
CH
CP
S3
CP
S2
CH
Figure 23. Input Architecture
The structure of the input SHA places certain requirements on
the input drive source. The combination of the pin capacitance,
CP, and the hold capacitance, CH, is typically less than 5 pF.
The input source must be able to charge or discharge this capacitance to 10-bit accuracy in one half of a clock cycle. When
the SHA goes into track mode, the input source must charge or
discharge capacitor CH from the voltage already stored on CH to
the new voltage. In the worst case, a full-scale voltage step on
the input source must provide the charging current through the
RON (100 Ω) of Switch 1 and quickly (within 1/2 CLK period)
settle. This situation corresponds to driving a low input impedance. Adding series resistance between the output of the signal
source and the AIN pin reduces the drive requirements placed
on the signal source. Figure 24 shows this configuration. The
bandwidth of the particular application limits the size of this
resistor. To maintain the performance outlined in the data sheet
specifications, the resistor should be limited to 50 Ω or less. The
series input resistor can be used to isolate the driver from the
AD9203’s switched capacitor input. The external capacitor may
be selected to limit the bandwidth into the AD9203. Two input
RC networks should be used to balance differential input drive
schemes (Figure 24).
The input span of the AD9203 is a function of the reference
voltage. For more information regarding the input range, see the
Internal and External Reference sections of the data sheet.
<50V
AIN
VS
AD9203
Figure 24. Simple AD9203 Drive Configuration
In many cases, particularly in single-supply operation, ac coupling offers a convenient way of biasing the analog input signal
to the proper signal range. Figure 25 shows a typical configuration for ac-coupling the analog input signal to the AD9203.
Maintaining the specifications outlined in the data sheet requires careful selection of the component values. The most
important is the f–3 dB high-pass corner frequency. It is a function of R2 and the parallel combination of C1 and C2.
There are additional considerations when choosing the resistor
values for an ac-coupled input. The ac-coupling capacitors
integrate the switching transients present at the input of the
AD9203 and cause a net dc bias current, IB, to flow into the
input. The magnitude of the bias current increases as the signal
changes and as the clock frequency increases. This bias current
will result in an offset error of (R1 + R2) × IB. If it is necessary
to compensate for this error, consider modifying VBIAS to
account for the resultant offset. In systems that must use dc
coupling, use an op amp to level-shift ground-referenced signals
to comply with the input requirements of the AD9203.
OP AMP SELECTION GUIDE
Op amp selection for the AD9203 is highly application dependent. In general, the performance requirements of any given
application can be characterized by either time domain or frequency domain constraints. In either case, one should carefully
select an op amp that preserves the performance of the A/D.
This task becomes challenging when one considers the AD9203’s
high performance capabilities coupled with other system level
requirements such as power consumption and cost.
The ability to select the optimal op amp may be further complicated by either limited power supply availability and/or limited
acceptable supplies for a desired op amp. Newer, high performance op amps typically have input and output range limitations in accordance with their lower supply voltages. As a result,
some op amps will be more appropriate in systems where accoupling is allowed. When dc-coupling is required, op amps’
headroom constraints (such as rail-to-rail op amps) or ones
where larger supplies can be used, should be considered.
The following section describes some op amps currently available from Analog Devices. Please contact the factory or local
sales office for updates on Analog Devices latest amplifier product offerings.
AD8051: f–3 dB = 110 MHz.
Low cost. Best used for driving single-ended ac-coupled configuration. Operates on a 3 V power rail.
AD8052: Dual Version of above amp.
AD8138 is a higher performance version of AD8131. Its gain is
programmable and provides 14-bit performance.
–12–
REV. 0
AD9203
DIFFERENTIAL MODE OF OPERATION
Since not all applications have a signal preconditioned for differential operation, there is often a need to perform a single-endedto-differential conversion. In systems that do not need a dc
input, an RF transformer with a center tap is a method to generate differential inputs beyond 20 MHz for the AD9203. This
provides all the benefits of operating the A/D in the differential
mode without contributing additional noise or distortion. An RF
transformer also has the added benefit of providing electrical isolation between the signal source and the A/D.
An improvement in THD and SFDR performance can be realized by operating the AD9203 in differential mode. The performance enhancement between the differential and single-ended
mode is most considerable as the input frequency approaches
and goes beyond the Nyquist frequency (i.e., fIN > FS/2).
Transformers with other turns ratios may also be selected to
optimize the performance of a given application. For example,
selecting a transformer with a higher impedance ratio (e.g.,
Minicircuits T16–6T with a impedance ratio of 16) effectively
“steps up” the signal amplitude, thus further reducing the driving requirements of the signal source.
The AD9203 can be easily configured for either a 1 V p-p input
span or 2 V p-p input span by setting the internal reference.
Other input spans can be realized with two external gain setting
resistors as shown in Figure 19 of this data sheet. Figures 32
and 33 demonstrate the SNR and SFDR performance over a
wide range of amplitudes required by most communication
applications.
–80
1.0V REF
+3V
499V
0.1mF
10mF
10mF
0.1mF
0.1mF
10kV
499V
49.9V
AVDD
AINP
20pF
49.9V
523V
DRVDD
AD9203
AD8138
AINN
49.9V
DIGITAL
OUTPUTS
AVSS DRVSS
–60
–50
–40
20pF
0.1mF
0.5V REF
–70
THD – dB
+3V
499V
10kV
–30 0
Figure 26. AD8138 Driving an AD9203, a 10-Bit, 40 MSPS
A/D Converter
THD – dB
THD
SNR
–60
–40
40.0
42.5
45.0
47.5
50.0
52.5
DUTY CYCLE – %
55.0
57.5
60.0
Figure 29. THD and SNR vs. Clock Duty Cycle (fIN = 5 MHz
Differential, Clock = 40 MSPS)
AD9203
VREF
0.1mF
REFSENSE
Figure 27. Transformer Coupled Input
REV. 0
–70
–50
AINN
10mF
3.5
–80
The center tap of the transformer provides a convenient means
of level-shifting the input signal to a desired common-mode
voltage. Figure 28 illustrates the performance of the AD9203
over a wide range of common-mode levels.
1V
3.0
–90
Figure 27 shows the schematic of a suggested transformer
circuit. The circuit uses a Minicircuits RF transformer, model
number T4–1T, which has an impedance ratio of four (turns
ratio of 2).
AINP
1.0
1.5
2.0
2.5
COMMON-MODE VOLTAGE – Volts
Figure 28. THD vs. Common-Mode Voltage vs. THD (AIN =
2 V Differential) (fIN = 5 MHz, fS = 40 MSPS)
The AD8138 provides a convenient method of converting a
single-ended signal to a differential signal. This is an ideal
method for generating a direct coupled signal to the AD9203.
The AD8138 will accept a signal and shift it to an externally
provided common-mode level. The AD8138 configuration is
shown in Figure 26.
2V
0.5
–13–
AD9203
Table II. Power Programming Resistance
Clock
MHz
fIN
MHz
THD
dB
SNR
dB
SINAD
dB
SFDR
dB
IAVDD
mA
IDRVDD
mA
Total Power
Into 5 pF Load
mW
Power Control
Resistor
k⍀
5
10
15
20
30
2.5
2.5
2.5
5
5
–72
–74.3
–74
–75.1
–75
60.6
60.7
60.1
53.4
59.5
59.9
60.4
59.9
53.2
59.4
77.9
77.8
77.7
78.9
74.8
5.0
5.9
6.7
7.8
10
0.86
1.2
1.8
2.4
4.0
17
21.3
25
30
42
37
37
37
50
50
POWER CONTROL
Power consumed by the AD9203 may be reduced by placing a
resistor between the PWRCON pin and ground. This function
will be valuable to users who do not need the AD9203’s high
conversion rate, but do need even lower power consumption.
The external resistor sets the programming of the analog current
mirrors. Table II illustrates the relationship between programmed
power and performance.
At lower clock rates, less power is required within the analog
sections of the AD9203. Placing an external resistor on the
PWRCON pin will shunt control current away from some of the
current mirrors. This enables the ADC to convert low data rates
with extremely low power consumption.
INTERFACING TO 5 V SYSTEMS
The AD9203 can be integrated into +5 V systems. This is
accomplished by deriving a 3 V power supply from the existing
5 V analog power line through an AD3307-3 linear regulator.
Care must be maintained so that logic inputs do not exceed the
maximum rated values listed on the Specifications page.
CLOCK INPUT AND CONSIDERATIONS
The AD9203 internal timing uses the two edges of the clock
input to generate a variety of internal timing signals. Sampling
occurs on the falling edge. The clock input to the AD9203
operating at 40 MSPS may have a duty cycle between 45% to
55% to meet this timing requirement since the minimum specified tCH and tCL is 11.25 ns. For clock rates below 40 MSPS, the
duty cycle may deviate from this range to the extent that both
tCH and tCL are satisfied. See Figure 29 for dynamics vs. duty
cyle.
input frequency (fIN) due only to aperture jitter (tA) can be
calculated with the following equation:
SNR degradation = 20 log10 [1/2 π f IN tA]
In the equation, the rms aperture jitter, tA, represents the rootsum square of all the jitter sources, which include the clock input, analog input signal, and A/D aperture jitter specification.
Undersampling applications are particularly sensitive to jitter.
Clock input should be treated as an analog signal in cases where
aperture jitter may affect the dynamic range of the AD9203.
Power supplies for clock drivers should be separated from the
A/D output driver supplies to avoid modulating the clock signal
with digital noise. Low jitter crystal controlled oscillators make
the best clock sources. If the clock is generated from another
type of source (by gating, dividing or other method), it should
be retimed by the original clock at the last step.
The clock input is referred to the analog supply. Its logic threshold is AVDD/2.
DIGITAL INPUTS AND OUTPUTS
Each of the AD9203 digital control inputs, 3-STATE, DFS and
STBY are referenced to analog ground. CLK is also referenced
to analog ground. A low power mode feature is provided such
that for STBY = HIGH and the static power of the AD9203 drops
to 0.65 mW.
Asserting the DFS pin high will invert the MSB pin, changing
the data to a twos complement format.
The AD9203 has an OTR (out of range) function. If the input
voltage is above or below full scale by 1 LSB, the OTR flag will
go high. See Figure 30.
High speed high resolution A/Ds are sensitive to the quality of
the clock input. The degradation in SNR at a given full-scale
OTR
OTR
DATA OUTPUTS
1
0
0
11111
11111
11111
11111
11111
11110
0
0
1
00000
00000
00000
00001
00000
00000
+FS
–FS –FS + 1 LSB
+FS – 1 LSB
Figure 30. Output Data Format
–14–
REV. 0
AD9203
G1 = 20dB
SAW FILTER
OUTPUT
50V
BANDPASS MINI CIRCUITS
FILTER
T4-6T
1:4
G2 = 20dB
50V
50V
200V
AINP
200V
AINN
22.1V
93.1V
AD9203
AVDD/2
Figure 31. Simplified IF Sampling Circuit
Sampling IF signals above an ADC’s baseband region (i.e., dc
to FS/2) is becoming increasingly popular in communication
applications. This process is often referred to as Direct IF Down
Conversion or Undersampling. There are several potential benefits in using the ADC to alias (i.e., or mix) down a narrow
band or wide band IF signal. First and foremost is the elimination of a complete mixer stage with its associated amplifiers and
filters, reducing cost and power dissipation. Second is the ability
to apply various DSP techniques to perform such functions as
filtering, channel selection, quadrature demodulation, data
reduction, detection, etc. A detailed discussion on using this
technique in digital receivers can be found in Analog Devices
Application Notes AN-301 and AN-302.
In Direct IF Down Conversion applications, one exploits the
inherent sampling process of an ADC in which an IF signal
lying outside the baseband region can be aliased back into
the baseband region in a manner similar to a mixer downconverting an IF signal. Similar to the mixer topology, an image rejection filter is required to limit other potential interfering
signals from also aliasing back into the ADC’s baseband region.
A trade-off exists between the complexity of this image rejection
filter and the ADC’s sample rate as well as dynamic range.
The AD9203 is well suited for various IF sampling applications.
The AD9203’s low distortion input SHA has a full-power bandwidth extending to 130 MHz, thus encompassing many popular
IF frequencies. Only the 2 V span should be used for undersampling beyond 20 MHz. A DNL of ± 0.25 LSB combined
with low thermal input referred noise allows the AD9203 in the
2 V span to provide >59 dB of SNR for a baseband input sine
wave. Also, its low aperture jitter of 1.2 ps rms ensures minimum SNR degradation at higher IF frequencies. In fact, the
AD9203 is capable of still maintaining 58 dB of SNR at an IF
of 70 MHz with a 2 V input span.
To maximize its distortion performance, the AD9203 should be
configured in the differential mode with a 2 V span using a
transformer. The center-tap of the transformer is biased to the
reference output of the AD9203. Preceding the AD9203 and
transformer is an optional bandpass filter as well as a gain stage.
A low Q passive bandpass filter can be inserted to reduce out-ofband distortion and noise that lies within the AD9203’s 390 MHz
bandwidth. A large gain stage(s) is often required to compensate
for the high insertion losses of a SAW filter used for channel
selection and image rejection. The gain stage will also provide
adequate isolation for the SAW filter from the charge “kick
back” currents associated with the AD9203’s switched capacitor
input stage.
The distortion and noise performance of an ADC at the given
IF frequency is of particular concern when evaluating an ADC
REV. 0
for a narrowband IF sampling application. Both single tone and
dual tone SFDR vs. amplitude are very useful in assessing an
ADC’s dynamic and static nonlinearities. SNR vs. amplitude
performance at the given IF is useful in assessing the ADC’s
noise performance and noise contribution due to aperture jitter.
In any application, one is advised to test several units of the
same device under the same conditions to evaluate the given
applications sensitivity to that particular device. Figures 32 and
33 combine the dual tone SFDR as well as single tone SFDR and
SNR performances at IF frequencies of 70 MHz, and 130 MHz.
Note, the SFDR vs. amplitude data is referenced to dBFS while
the single tone SNR data is referenced to dBc. The performance
characteristics in these figures are representative of the AD9203
without any preceding gain stage. The AD9203 was operated in
the differential mode (via transformer) with a 2 V span and a
sample rate of 40 MSPS. The analog supply (AVDD) and the
digital supply (DRVDD) were set to 3.0 V.
90
SFDR 2 TONE
80
70
SNR/SFDR – dB
DIRECT IF DOWN CONVERSION USING THE AD9203
SFDR 1 TONE
60
50
SNR
40
30
20
10
0
0
5
10
15
20
25
INPUT POWER LEVEL – dB FULL SCALE
30
Figure 32. SNR/SFDR for IF @ 70 MHz (Clock = 40 MSPS)
80
SFDR 2 TONE
70
60
SFDR 1 TONE
SNR/SFDR – dB
APPLICATIONS
50
40
SNR
30
20
10
0
0
5
10
15
20
25
30
INPUT POWER LEVEL – dB FULL SCALE
35
Figure 33. SNR/SFDR for IF @ 130 MHz (Clock = 40 MSPS)
–15–
AD9203
The 74 mW power consumption gives the 40 MSPS AD9203
an order of magnitude improvement over older generation
components.
ULTRASOUND APPLICATIONS
The AD9203 provides excellent performance in 10-bit ultrasound applications. This is demonstrated by its high SNR with
analog input frequencies up to and including Nyquist. The
presence of spurs near the base of a fundamental frequency bin
is demonstrated by Figure 35. Note that the spurs near the noise
floor are more than 80 dB below fIN. This is especially valuable
in Doppler ultrasound applications where low frequency shifts
from the fundamental are important.
10
FUND
0
SNR = 59.9dB
THD = –75dB
SFDR = 82dB
–10
–20
–30
–40
dB
CONDITIONED
TRANSDUCER
SIGNAL
ANALOG
INPUT
SINGLEENDED
ANALOG
+3V
–60
AD9203
–70
AINP
AD604
TGC
AMPLIFIER
–50
–80
AD8138
–90
AINN
–100
GAIN
CONTROL
–110
4.5E+6
4.7E+6
4.9E+6
5.1E+6
5.3E+6
5.5E+6
FIN
1.5V
Figure 35. SFDR Performance Near the Fundamental
Signal (8192 Point FFT, fIN = 5 MHz, F S = 40 MSPS)
+3V
Figure 34. Ultrasound Connection for the AD9203
EVALUATION BOARD
Figure 34 illustrates the AD604 variable gain amplifier configured for time gain compensation (TGC). The low power
AD9203 is powered from a 3 V supply rail while the high performance AD604 is powered from 5 V supply rails. An AD8138
is used to drive the AD9203. This is implemented due to the
ability of differential drive techniques to cancel common mode
noise and input anomalies.
+3V
+
+3V
–
DRVDD
SYNTHESIZER
1MHz 1.9V p-p
HP8644
ANTIALIASING
FILTER
The AD9203 evaluation board is shipped wired for 2 V differential operation. The board should be connected to power and test
equipment as shown in Figure 36. It is easily configured for
single ended and differential operation as well as 1 V and 2 V
spans. Refer to schematic on next page.
–
GND
J1
ANALOG
INPUT
+3V
+
+
+3-5d
AVDD
+3V
–
GND
AD9203
EVALUATION BOARD
SYNTHESIZER
40MHz 1V p-p
HP8644
+
–
AVEE
OUTPUT
WORD
DSP
EQUIPMENT
J5
EXTERNAL
CLOCK
Figure 36. Evaluation Board Connection
–16–
REV. 0
REV. 0
J1
Figure 37. Evaluation Board (Rev. C)
–17–
2
1
R36
4.99kV
C30
0.1mF
R34
2kV
R4
49.9V
R1
49.9V
2
3
A 1
SW8 B
R35
4.99V
J4
2
1
J5
1 JP8 2
2
1
B
C2
4.7mF
10V
C1
0.1mF
TP2
3
1 A SW7
2
AVDD
1
4
2
JP52 2
JP26
6
4
P
74LVX14
TPB
1
2
74LVX14
U6
U6
R53
49.9V
3
1
6
C4
0.1mF
1
2
3
1
JP65 2
R54
200kV
C6
0.1mF
1 JP3 2
C12
0.1mF
C11
0.1mF
10V
C9
1mF
2
1+
AVDD
C5
10mF
10V
C3
0.1mF
C10
0.1mF
TP1
1 A SW6
2
3
B
1 JP64 2
R52
49.9V
74LVX14
U6
R2
100V
S
T1
5
TP12
R51
49.9V
R103
10V
R104
10V
1
JP54
JP53
2
2
B
A
C34
0.1mF
74LVX14
R101
TBD BY USER
1
8
74LVX14
U6
13
12
R102
TBD BY USER
CLK
U6
74LVX14
U6
11
10
9
TP3
1 JP1 2
1 JP2 2
AVDD
1
JP58
2
2
C100
20pF
AVDD
JP63
C33
10mF
10V
1
U6 BYPASS
C102
0.1mF
AVDD
JP50
15
16
17
19
21
22
23
24
25
26
20
1
U1
AVSS
1
DRVSS
R55
TBD
BY USER
27
DFS
REFSENSE
AD9203
13
C18
10mF
10V
18
14
2
2
C19
0.1mF
JP51
3
D0
4
D1
5
D2
6
D3
7
D4
8
D5
9
D6
10
D7
11
D8
12
D9
OTR
2
DRVDD
28
REFBF
AINP
AINN
CLAMP IN
1
1 +
AVDD
CLK
3 STATE
STBY
CLAMP
PWRCON
REFTF
VREF
JP59
2
2
+ 1
C17
10mF
10V
C101
20pF
2
C16
0.1mF
1
D0
D1
D2
D3
D4
D5
D6
D7
D8
D9
R56
JP60
JP61
2
2
TBD
BY USER
1
1
OTR
DRVDD
AVDD
AD9203
–18–
1
2
AGND3,4,5
1
J12
B4
1
TP4
TP20
R113
50V
C7
33mF
16V
L4
1
10mF
10V
+ C23
L1
1
R112
25V
R111
1V
FBEAD
2
FBEAD
2
C14
0.1mF
AVSS
R105
TBD
1
8
B
4
1
3
TP21
B
C45
0.1mF
33mF
16V
+ C25
L2
1
C26
10mF
10V
A
V+
AD8131 OUT 2
U3 V–
A 6
C13
0.1mF
5
AVDD
R106
TBD
C8
0.1mF
AVEE
C22
0.1mF
DRVDD
B3
+
+
B2
R107
1kV
C24
0.1mF
AVDD
10mF
10V
+ C15
10mF
10V
+ C44
FBEAD
2
1
DRVDD
R108
1kV
DRVDD
B1
TP29
C41
0.1mF
D2
D1
D0
LSB11
LSB12
OTR
CLK
C40
0.1mF
D9
D8
D7
D6
D5
D4
D3
10mF
10V
+ C31
L3
1
21
24
23
22
13
14
15
16
17
18
19
20
21
24
23
22
13
14
15
16
17
18
19
20
FBEAD
2
U4
U5
10
9
8
7
6
5
4
3
A8
1
VCCA
2
T/R
11
GD2
12
GD3
A1
A2
A3
A4
A5
A6
A7
74LVXC4245WM
GD1
NC1
OE
B8
VCCB
B1
B2
B3
B4
B5
B6
B7
3
10
9
8
7
6
5
4
A8
1
VCCA
2
T/R
11
GD2
12
GD3
A1
A2
A3
A4
A5
A6
A7
74LVXC4245WM
GD1
NC1
OE
B8
VCCB
B1
B2
B3
B4
B5
B6
B7
C32
0.1mF
+3–5D
B5
B6
1
1
TP23
C21
0.1mF
+3–5D
C20
0.1mF
+3–5D
TP24
TP25
TP26
TP27
RN2
7 22V 8
RN2
6 22V 9
RN2
5 22V 10
RN2
4 22V 11
RN2
3 22V 12
RN2
2 22V 13
RN2
1 22V 14
RN1
7 22V 8
RN1
6 22V 9
RN1
5 22V 10
RN1
4 22V 11
RN1
3 22V 12
RN1
2 22V 13
RN1
1 22V 14
TP28
39
37
35
33
P1
P1
P1
P1
P1
P1
31
P1
29
P1
25
27
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
23
21
19
17
15
13
11
9
7
5
3
1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
P1
40
38
36
34
32
30
28
26
24
22
20
18
16
14
12
10
8
6
4
2
AD9203
Figure 38. Evaluation Board (Rev. C)
REV. 0
AD9203
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
C3596–2–7/99
28-Lead Thin Shrink Small Outline
(RU-28)
0.386 (9.80)
0.378 (9.60)
28
15
0.177 (4.50)
0.169 (4.30)
0.256 (6.50)
0.246 (6.25)
1
14
PIN 1
0.006 (0.15)
0.002 (0.05)
0.0256 (0.65)
BSC
0.0118 (0.30)
0.0075 (0.19)
0.0079 (0.20)
0.0035 (0.090)
88
08
0.028 (0.70)
0.020 (0.50)
PRINTED IN U.S.A.
SEATING
PLANE
0.0433 (1.10)
MAX
REV. 0
–19–