AD9226-EB [ADI]
Complete 12-Bit, 65 MSPS ADC Converter; 完整的12位, 65 MSPS ADC转换器型号: | AD9226-EB |
厂家: | ADI |
描述: | Complete 12-Bit, 65 MSPS ADC Converter |
文件: | 总28页 (文件大小:1478K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
Complete 12-Bit, 65 MSPS
ADC Converter
a
AD9226
FEATURES
FUNCTIONAL BLOCK DIAGRAM
Signal-to-Noise Ratio: 69 dB @ fIN = 31 MHz
Spurious-Free Dynamic Range: 85 dB @ fIN = 31 MHz
Intermodulation Distortion of –75 dBFS @ fIN = 140 MHz
ENOB = 11.1 @ fIN = 10 MHz
Low-Power Dissipation: 475 mW
No Missing Codes Guaranteed
Differential Nonlinearity Error: ؎0.6 LSB
Integral Nonlinearity Error: ؎0.6 LSB
Clock Duty Cycle Stabilizer
Patented On-Chip Sample-and-Hold with
Full Power Bandwidth of 750 MHz
Straight Binary or Two’s Complement Output Data
28-Lead SSOP, 48-Lead LQFP
DRVDD
AVDD
CLK
DUTY CYCLE STABILIZER
SHA
VINA
VINB
8-STAGE
MDAC1
A/D
1-1/2-BIT PIPELINE
4
A/D
3
16
CAPT
CAPB
CALIBRATION
ROM
CORRECTION LOGIC
12
VREF
OTR
OUTPUT BUFFERS
BIT 1
(MSB)
SENSE
1V
REF
SELECT
MODE
SELECT
BIT 12
(LSB)
AD9226
Single 5 V Analog Supply, 3 V/5 V Driver Supply
Pin-Compatible to AD9220, AD9221, AD9223,
AD9224, AD9225
REFCOM
MODE
AVSS
DRVSS
PRODUCT DESCRIPTION
The AD9226 has two important mode functions. One will set
the data format to binary or two’s complement. The second will
make the ADC immune to clock duty cycle variations.
The AD9226 is a monolithic, single-supply, 12-bit, 65 MSPS
analog-to-digital converter with an on-chip, high-performance
sample-and-hold amplifier and voltage reference. The AD9226
uses a multistage differential pipelined architecture with a pat-
ented input stage and output error correction logic to provide
12-bit accuracy at 65 MSPS data rates. There are no missing
codes over the full operating temperature range (guaranteed).
PRODUCT HIGHLIGHTS
IF Sampling—The patented SHA input can be configured for
either single-ended or differential inputs. It will maintain out-
standing AC performance up to input frequencies of 300 MHz.
The input of the AD9226 allows for easy interfacing to both
imaging and communications systems. With a truly differential
input structure, the user can select a variety of input ranges and
offsets including single-ended applications.
Low Power—The AD9226 at 475 mW consumes a fraction of
the power presently available in existing, high-speed monolithic
solutions.
Out of Range (OTR)—The OTR output bit indicates when
The sample-and-hold amplifier (SHA) is well suited for IF
undersampling schemes such as in single-channel communi-
cation applications with input frequencies up to and well
beyond Nyquist frequencies.
the input signal is beyond the AD9226’s input range.
Single Supply—The AD9226 uses a single 5 V power supply
simplifying system power supply design. It also features a sepa-
rate digital output driver supply line to accommodate 3 V and
5 V logic families.
The AD9226 has an on-board programmable reference. For sys-
tem design flexibility, an external reference can also be chosen.
Pin Compatibility—The AD9226 is similar to the AD9220,
A single clock input is used to control all internal conversion
cycles. An out-of-range signal indicates an overflow condition
that can be used with the most significant bit to determine low
or high overflow.
AD9221, AD9223, AD9224, and AD9225 ADCs.
Clock Duty Cycle Stabilizer—Makes conversion immune to
varying clock pulsewidths.
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
Fax: 781/326-8703
World Wide Web Site: http://www.analog.com
© Analog Devices, Inc., 2000
AD9226–SPECIFICATIONS
(AVDD = 5 V, DRVDD = 3 V, fSAMPLE = 65 MSPS, VREF = 2.0 V, Differential inputs, TMIN to TMAX unless otherwise
DC SPECIFICATIONS noted.)
P
arameter
Temp
Test Level
Min
Typ
Max
Unit
RESOLUTION
12
Bits
ACCURACY
Integral Nonlinearity (INL)
Full
25°C
Full
25°C
Full
Full
25°C
25°C
Full
V
I
V
I
I
V
I
0.6
0.6
LSB
LSB
LSB
LSB
1.6
1.0
Differential Nonlinearity (DNL)
No Missing Codes Guaranteed
Zero Error
12
Bits
0.3
0.6
% FSR
% FSR
% FSR
% FSR
1.4
2.0
Gain Error
I
V
TEMPERATURE DRIFT
Zero Error
Full
Full
Full
V
V
V
2
26
0.4
ppm/°C
ppm/°C
ppm/°C
Gain Error1
Gain Error2
POWER SUPPLY REJECTION
AVDD (5 V 0.25 V)
Full
25°C
V
I
0.05
% FSR
% FSR
0.4
INPUT REFERRED NOISE
VREF = 1.0 V
VREF = 2.0 V
Full
Full
V
V
0.5
0.25
LSB rms
LSB rms
ANALOG INPUT
Input Span (VREF = 1 V)
(VREF = 2 V)
Input (VINA or VINB) Range
Input Capacitance
Full
Full
Full
Full
V
V
IV
V
1
2
V p-p
V p-p
V
0
AVDD
7
pF
INTERNAL VOLTAGE REFERENCE
Output Voltage (1 V Mode)
Output Voltage Tolerance (1 V Mode)
Output Voltage (2.0 V Mode)
Output Voltage Tolerance (2.0 V Mode)
Output Current (Available for External Loads)
Load Regulation3
Full
25°C
Full
25°C
Full
Full
V
I
V
I
V
V
I
1.0
2.0
V
mV
V
mV
mA
mV
mV
15
29
1.0
0.7
25°C
1.5
REFERENCE INPUT RESISTANCE
Full
V
5
5
kΩ
POWER SUPPLIES
Supply Voltages
AVDD
Full
Full
V
V
4.75
2.85
5.25
5.25
V ( 5% AVDD Operating)
V ( 5% DRVDD Operating)
DRVDD
Supply Current
IAVDD4
Full
25°C
Full
V
I
V
I
86
mA (2 V External VREF)
mA (2 V External VREF)
mA (2 V External VREF)
mA (2 V External VREF)
90.5
16.5
IDRVDD5
14.6
25°C
POWER CONSUMPTION4, 5
Full
25°C
V
I
475
500
mW (2 V External VREF)
NOTES
1Includes internal voltage reference error.
2Excludes internal voltage reference error.
3Load regulation with 1 mA load current (in addition to that required by the AD9226).
4AVDD = 5 V
5DRVDD = 3 V
Specifications subject to change without notice.
–2–
REV. 0
AD9226
(AVDD = 5 V, DRVDD = 3 V, fSAMPLE = 65 MSPS, VREF = 2.0 V, TMIN to TMAX, unless otherwise noted.)
DIGITAL SPECIFICATIONS
Parameters
Temp
Test Level Min
Typ
Max
Unit
LOGIC INPUTS (Clock, DFS1, Duty Cycle1, and
Output Enable1)
High-Level Input Voltage
Low-Level Input Voltage
Full
Full
Full
Full
Full
Full
IV
IV
IV
IV
V
2.4
V
V
µA
µA
pF
V
0.8
+10
+10
High-Level Input Current (VIN = AVDD)
Low-Level Input Current (VIN = 0 V)
Input Capacitance
–10
–10
5
Output Enable1
IV
DRVDD
DRVDD
+ 0.5
– 0.5
2
2
LOGIC OUTPUTS (With DRVDD = 5 V)
High-Level Output Voltage (IOH = 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)
Output Capacitance
Full
Full
Full
Full
IV
IV
IV
IV
4.5
2.4
V
V
V
V
0.4
0.1
5
pF
LOGIC OUTPUTS (With DRVDD = 3 V)
High-Level Output Voltage (IOH = 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)
Full
Full
Full
Full
IV
IV
IV
IV
2.95
2.80
V
V
V
V
0.4
0.05
NOTES
1LQFP package.
Specifications subject to change without notice.
(TMIN to TMAX with AVDD = 5 V, DRVDD = 3 V, CL = 20 pF)
SWITCHING SPECIFICATIONS
Parameters
Temp
Test Level
Min
Typ
Max
Unit
Max Conversion Rate
Clock Period1
Full
Full
Full
Full
Full
Full
Full
VI
V
V
V
V
V
V
65
15.38
3
3
MHz
ns
ns
ns
CLOCK Pulsewidth High2
CLOCK Pulsewidth Low2
Output Delay
3.5
7
ns
Pipeline Delay (Latency)
7
15
Clock Cycles
ns
Output Enable Delay3
NOTES
1The clock period may be extended to 10 µs without degradation in specified performance @ 25°C.
2When MODE pin is tied to AVDD or grounded, the AD9226 SSOP is not affected by clock duty cycle.
3LQFP package.
Specifications subject to change without notice.
n+2
n+1
n+3
n
n+8
ANALOG
INPUT
n+4
n+7
n+5
n+6
CLOCK
DATA
OUT
n–2
n
n–8
n–7
n–6
n–5
n–4
n–3
n–1
n+1
TOD = 7.0 MAX
3.5 MIN
Figure 1. Timing Diagram
–3–
REV. 0
AD9226–SPECIFICATIONS
(AVDD = 5 V, DRVDD = 3 V, fSAMPLE = 65 MSPS, VREF = 2.0 V, TMIN to TMAX, Differential Input unless otherwise noted.)
AC SPECIFICATIONS
Parameter
Temp
Test Level
Min
Typ
Max
Unit
SIGNAL-TO-NOISE RATIO
fIN = 2.5 MHz
Full
25°C
Full
25°C
Full
Full
Full
V
I
V
I
V
V
V
68.9
68.4
dBc
dBc
dBc
dBc
dBc
dBc
dBc
68
fIN = 15 MHz
67.4
f
IN = 31 MHz
68
68
65
fIN = 60 MHz
fIN = 200 MHz1
SIGNAL-TO-NOISE RATIO AND DISTORTION
fIN = 2.5 MHz
Full
25°C
Full
25°C
Full
Full
Full
V
I
V
I
V
V
V
68.8
68.3
dBc
dBc
dBc
dBc
dBc
dBc
dBc
67.9
67.3
fIN = 15 MHz
fIN = 31 MHz
fIN = 60 MHz
fIN = 200 MHz1
67
67
60
TOTAL HARMONIC DISTORTION
fIN = 2.5 MHz
Full
25°C
Full
25°C
Full
Full
Full
V
I
V
I
V
V
V
–84
dBc
dBc
dBc
dBc
dBc
dBc
dBc
–77.0
–76.0
f
IN = 15 MHz
–82.3
fIN = 31 MHz
–68
–68
–61
f
IN = 60 MHz
fIN = 200 MHz1
SECOND AND THIRD HARMONIC DISTORTION
f
IN = 2.5 MHz
Full
25°C
Full
25°C
Full
Full
Full
V
I
V
I
V
V
V
–86.5
–86.7
dBc
dBc
dBc
dBc
dBc
dBc
dBc
–78
–76
f
IN = 15 MHz
fIN = 31 MHz
–83
–82
–75
f
IN = 60 MHz
fIN = 200 MHz1
SPURIOUS FREE DYNAMIC RANGE
fIN = 2.5 MHz
Full
25°C
Full
25°C
Full
Full
Full
V
I
V
I
V
V
V
86.4
85.5
dBc
dBc
dBc
dBc
dBc
dBc
dBc
78
76
f
IN = 15 MHz
fIN = 31 MHz
82
81
60
f
IN = 60 MHz
fIN = 200 MHz1
ANALOG INPUT BANDWIDTH
25°C
V
750
MHz
NOTES
11.0 V Reference and Input Span
Specifications subject to change without notice.
–4–
REV. 0
AD9226
ABSOLUTE MAXIMUM RATINGS1
With
EXPLANATION OF TEST LEVELS
Test Level
I. 100% production tested.
Pin Name
Respect to Min
Max
Unit
II. 100% production tested at 25°C and sample tested at
AVDD
DRVDD
AVSS
AVSS
–0.3
–0.3
–0.3
–6.5
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
+6.5
+6.5
+0.3
+6.5
V
V
V
V
V
V
V
V
V
V
V
V
V
V
°C
°C
°C
specified temperatures. AC testing done on sample basis.
DRVSS
DRVSS
DRVDD
AVSS
AVSS
DRVSS
AVSS
AVSS
AVSS
AVSS
III. Sample tested only.
AVDD
IV. Parameter is guaranteed by design and characterization
testing.
REFCOM
CLK, MODE
Digital Outputs
VINA, VINB
VREF
+0.3
AVDD + 0.3
DRVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
AVDD + 0.3
DRVDD + 0.3
AVDD + 0.3
AVDD + 0.3
150
V. Parameter is a typical value only.
VI. All devices are 100% production tested at 25°C; sample tested
at temperature extremes.
SENSE
CAPB, CAPT
OEB2
DRVSS
AVSS
AVSS
CM LEVEL2
VR2
Junction Temperature
Storage Temperature
Lead Temperature (10 sec)
–65
+150
300
NOTES
1Stresses above those listed under Absolute Maximum Ratings may cause perma-
nent 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.
2LQFP package.
THERMAL RESISTANCE
θ
θ
θ
θ
JC SSOP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23°C/W
JA SSOP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .63.3°C/W
JC LQFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17°C/W
JA LQFP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .76.2°C/W
ORDERING GUIDE
Package Description
Model
Temperature Range
Package Option
AD9226ARS
AD9226AST
AD9226-EB
–40°C to +85°C
–40°C to +85°C
28-Lead Shrink Small Outline (SSOP)
48-Lead Thin Plastic Quad Flatpack (LQFP)
Evaluation Board (SSOP)
RS-28
ST-48
AD9226-LQFP-EB
Evaluation Board (LQFP)
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 AD9226 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.
WARNING!
ESD SENSITIVE DEVICE
–5–
REV. 0
AD9226
PIN CONNECTION
48-Lead LQFP
PIN CONNECTION
28-Lead SSOP
1
2
28
27
26
25
24
23
22
21
20
19
18
17
16
15
CLK
(LSB) BIT 12
BIT 11
BIT 10
BIT 9
DRVDD
DRVSS
AVDD
3
4
AVSS
5
VINB
48 47 46 45 44 43 42 41 40 39 38 37
6
BIT 8
VINA
AD9226
TOP VIEW
(Not to Scale)
1
2
AVSS
36
35
34
33
32
31
30
29
28
27
26
25
SENSE
7
PIN 1
IDENTIFIER
BIT 7
MODE
CAPT
AVSS
AVDD
AVDD
NC
MODE2
AVDD
8
BIT 6
3
9
4
BIT 5
CAPB
AVSS
5
10
11
12
13
14
AVSS
BIT 4
REFCOM (AVSS)
VREF
AD9226
TOP VIEW
(Not to Scale)
6
NC
AVDD
BIT 3
7
CLK
NC
DRVSS
DRVDD
OTR
BIT 1 (MSB)
BIT 2
BIT 2
SENSE
AVSS
8
(MSB) BIT 1
OTR
9
OEB
NC
AVDD
10
11
NC
(LSB) BIT 12 12
BIT 3
13 14 15 16 17 18 19 20 21 22 23 24
NC = NO CONNECT
48-PIN FUNCTION DESCRIPTIONS
28-PIN FUNCTION DESCRIPTIONS
Pin
Number
Pin
Number
Name
Description
Name
Description
1, 2, 32, 33 AVSS
3, 4, 31, 34 AVDD
5, 6, 8, 10, NC
11, 44
Analog Ground
5 V Analog Supply
No Connect
1
2
3–12
13
14
CLK
BIT 12
Clock Input Pin
Least Significant Data Bit (LSB)
BITS 11–2 Data Output Bits
BIT 1
OTR
Most Significant Data Bit (MSB)
Out of Range
7
CLK
Clock Input Pin
9
12
13
OEB
BIT 12
BIT 11
Output Enable (Active Low)
Least Significant Data Bit (LSB)
Data Output Bit
Digital Output Driver Ground
3 V to 5 V Digital Output
Driver Supply
15, 26
16, 25
17
18
19
AVDD
AVSS
SENSE
VREF
5 V Analog Supply
Analog Ground
Reference Select
14, 22, 30 DRVSS
15, 23, 29 DRVDD
Input Span Select (Reference I/O)
REFCOM Reference Common
(AVSS)
16–21,
24–26
27
28
35
36
37
38
BITS 10–5,
BITS 4–2
BIT 1
Data Output Bits
20
21
22
23
24
27
28
CAPB
Noise Reduction Pin
Noise Reduction Pin
Data Format Select/Clock Stabilizer
Analog Input Pin (+)
CAPT
MODE
VINA
VINB
DRVSS
Most Significant Data Bit (MSB)
Out of Range
Data Format Select
Reference Select
Reference In/Out
OTR
MODE2
SENSE
VREF
REFCOM
(AVSS)
CAPB
Analog Input Pin (–)
Digital Output Driver Ground
3 V to 5 V Digital Output
Driver Supply
DRVDD
Reference Common
39, 40
41, 42
43
45
46
47
48
Noise Reduction Pin
Noise Reduction Pin
Clock Stabilizer
Midsupply Reference
Analog Input Pin (+)
Analog Input Pin (–)
Noise Reduction Pin
CAPT
MODE1
CM LEVEL
VINA
VINB
VR
–6–
REV. 0
AD9226
DEFINITIONS OF SPECIFICATIONS
EFFECTIVE NUMBER OF BITS (ENOB)
INTEGRAL NONLINEARITY (INL)
For a sine wave, SINAD can be expressed in terms of the num-
ber of bits. Using the following formula,
INL 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.
N = (SINAD – 1.76)/6.02
it is possible to obtain a measure of performance expressed as
N, the effective number of bits.
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.
DIFFERENTIAL NONLINEARITY (DNL, NO MISSING
CODES)
TOTAL HARMONIC DISTORTION (THD)
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 12-bit resolution indicates that all 4096
codes, respectively, must be present over all operating ranges.
THD is the ratio of the rms sum of the first six harmonic com-
ponents to the rms value of the measured input signal and is
expressed as a percentage or in decibels.
SIGNAL-TO-NOISE RATIO (SNR)
ZERO ERROR
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 the first six harmonics and dc. The value
for SNR is expressed in decibels.
The major carry transition should occur for an analog value
1/2 LSB below VINA = VINB. Zero error is defined as the
deviation of the actual transition from that point.
GAIN ERROR
SPURIOUS FREE DYNAMIC RANGE (SFDR)
SFDR is the difference in dB between the rms amplitude of the
input signal and the peak spurious signal.
The first code transition should occur at an analog value
1/2 LSB above negative full scale. The last transition should
occur at an analog value 1 1/2 LSB below the positive 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.
ENCODE PULSEWIDTH DUTY CYCLE
Pulsewidth high is the minimum amount of time that the clock
pulse should be left in the logic “1” state to achieve rated per-
formance; pulsewidth low is the minimum time the clock pulse
should be left in the low state. At a given clock rate, these specs
define an acceptable clock duty cycle.
TEMPERATURE DRIFT
The temperature drift for zero error and gain error specifies the
maximum change from the initial (25°C) value to the value at
TMIN or TMAX.
MINIMUM CONVERSION RATE
The clock rate at which the SNR of the lowest analog signal
frequency drops by no more than 3 dB below the guaranteed limit.
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.
MAXIMUM CONVERSION RATE
The encode rate at which parametric testing is performed.
APERTURE JITTER
OUTPUT PROPAGATION DELAY
Aperture jitter is the variation in aperture delay for successive
samples and can be manifested as noise on the input to the ADC.
The delay between the clock logic threshold and the time when
all bits are within valid logic levels.
APERTURE DELAY
TWO TONE SFDR
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.
The ratio of the rms value of either input tone to the rms value
of the peak spurious component. The peak spurious component
may or may not be an IMD product. May be reported in dBc
(i.e., degrades as signal levels are lowered) or in dBFS (always
related back to converter full scale).
SIGNAL-TO-NOISE AND DISTORTION (S/N+D, SINAD)
RATIO
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.
–7–
REV. 0
AD9226
DRVDD
DRVDD
DRVDD
AVDD
AVSS
DRVSS
DRVSS
b. Three-State (OEB)
a. D0–D11, OTR
c. CLK
AVDD
AVDD
AVSS
AVSS
d. AIN
e. CAPT, CAPB, MODE, SENSE, VREF
Figure 2. Equivalent Circuits
–8–
REV. 0
Typical Performance Characteristics–AD9226
(AVDD = 5.0 V, DRVDD = 3.0 V, fSAMPLE = 65 MSPS with CLK Stabilizer Enabled, TA = 25؇C, 2 V Differential Input Span, VCM = 2.5 V, AIN = –0.5 dBFS,
VREF = 2.0 V, unless otherwise noted.)
0
–10
100
90
SNR = 69.9dBc
SINAD = 69.8dBc
ENOB = 11.4BITS
THD = –86.4dBc
SFDR = 88.7dBc
SFDR – dBFS
SFDR – dBc
–20
–30
–40
80
70
60
50
40
SNR – dBFS
–50
–60
–70
–80
SNR – dBc
–90
–100
–110
–120
0
6.5
13
19.5
26
32.5
–5
–25
–20
0
–30
–15
–10
FREQUENCY – MHz
A
– dBFS
IN
TPC 1. Single-Tone 8K FFT with fIN = 5 MHz
TPC 4. Single-Tone SNR/SFDR vs. AIN with fIN = 5 MHz
0
100
SNR = 70.4dBFS
SFDR = 87.5dBFS
–10
SFDR – dBFS
90
–20
SFDR – dBc
–30
–40
80
SNR – dBFS
–50
–60
70
–70
–80
60
–90
SNR – dBc
–100
–110
–120
50
40
–5
6.5
13
19.5
26
32.5
–25
–20
0
–30
–15
–10
0
A
– dBFS
FREQUENCY – MHz
IN
TPC 2. Dual-Tone 8K FFT with fIN–1 = 18 MHz and
TPC 5. Dual-Tone SNR/SFDR vs. AIN with fIN–1 = 18 MHz
and fIN–2 = 20 MHz
f
IN–2 = 20 MHz (AIN–1 = AIN–2 = –6.5 dBFS)
0
100
–10
–20
SNR = 69.5dBc
SINAD = 69.4dBc
ENOB = 11.3BITS
THD = –85dBc
SFDR – dBFS
90
–30
–40
SFDR = 87.6dBc
80
70
60
50
40
SNR – dBFS
–50
–60
–70
–80
SNR – dBc
–90
SFDR – dBc
–100
–110
–120
–5
–25
–20
0
–30
–15
–10
0
6.5
13
19.5
26
32.5
A
– dBFS
FREQUENCY – MHz
IN
TPC 3. Single-Tone 8K FFT with fIN = 31 MHz
TPC 6. Single-Tone SNR/SFDR vs. AIN with fIN = 31 MHz
–9–
REV. 0
AD9226
12.2
11.4
10.6
9.8
75
71
70
69
2V SPAN, DIFFERENTIAL
2V SPAN, DIFFERENTIAL
70
1V SPAN,
DIFFERENTIAL
68
67
66
65
64
63
62
61
2V SPAN, SINGLE-ENDED
65
60
1V SPAN,
DIFFERENTIAL
1V SPAN,
SINGLE-ENDED
8.9
55
50
1V SPAN,
SINGLE-ENDED
8.1
7.3
2V SPAN, SINGLE-ENDED
45
1
100
FREQUENCY – MHz
10
1000
1
10
100
1000
FREQUENCY – MHz
TPC 7. SINAD/ENOB vs. Frequency
TPC 10. SNR vs. Frequency
95
90
85
–45
–50
2V SPAN, SINGLE-ENDED
1V SPAN,
DIFFERENTIAL
–55
–60
–65
–70
–75
–80
–85
1V SPAN,
SINGLE-ENDED
80
75
2V SPAN,
DIFFERENTIAL
70
65
60
55
2V SPAN,
DIFFERENTIAL
1V SPAN,
SINGLE-ENDED
2V SPAN, SINGLE-ENDED
1V SPAN,
DIFFERENTIAL
50
45
–90
100
10
FREQUENCY – MHz
1
1000
100
10
FREQUENCY – MHz
1
1000
TPC 8. THD vs. Frequency
TPC 11. SFDR vs. Frequency
72
70
–70
–72
–74
–76
–78
–40؇C
+25؇C
68
66
64
+85؇C
+85؇C
–80
–82
–84
+25؇C
–86
–88
–90
–40؇C
62
1
100
10
FREQUENCY – MHz
1000
10
100
1
FREQUENCY – MHz
TPC 9. SNR vs. Temperature and Frequency
TPC 12. THD vs. Temperature and Frequency
–10–
REV. 0
AD9226
70.5
105
95
4th HARMONIC
70.25
f
= 2MHz
IN
70
f
= 12MHz
IN
85
69.75
3RD HARMONIC
75
65
55
69.5
f
= 20MHz
IN
69.25
69
2ND HARMONIC
10
20
30
40
50
60
70
100
10
FREQUENCY – MHz
1
1000
SAMPLE RATE – MSPS
TPC 13. Harmonics vs. Frequency
TPC 16. SINAD vs. Sample Rate
100
95
90
85
SFDR – CLOCK STABILIZER ON
80
75
70
65
60
55
50
45
SFDR – CLOCK STABILIZER OFF
SINAD – CLOCK STABILIZER ON
f
= 2MHz
IN
f
= 12MHz
IN
90
85
80
SINAD – CLOCK STABILIZER OFF
f
= 20MHz
IN
30
35
40
45
50
55
60
65
70
10
20
30
40
50
60
70
% POSITIVE DUTY CYCLE
SAMPLE RATE – MSPS
TPC 14. SFDR vs. Sample Rate
TPC 17. SINAD/SFDR vs. Duty Cycle @ fIN = 20 MHz
70.5
1
0.8
70.25
f
= 2MHz
IN
0.6
0.4
70
f
= 12MHz
IN
0.2
69.75
0
–0.2
–0.4
–0.6
–0.8
–1
69.5
f
= 20MHz
IN
69.25
69
1k
10
20
30
40
50
60
70
500
1500
2k
2500
3k
3500
4k
0
SAMPLE RATE – MSPS
CODE
TPC 15. Typical INL
TPC 18. Typical DNL
–11–
REV. 0
AD9226–Typical IF Sampling Performance Characteristics
(AVDD = 5.0 V, DRVDD = 3.0 V, fSAMPLE = 65 MSPS with CLK Stabilizer Enabled, TA = 25؇C, 2 V Differential Input Span, VCM = 2.5 V, AIN = –6.5 dBFS,
VREF = 2.0 V, unless otherwise noted.)
0
–10
–20
170.1
165.1
160.1
155.1
150.1
145.1
95
90
SNR = 70.2dBFS
SFDR = 89dBFS
NOISE FLOOR = 145.33dBFS/Hz
SFDR – 2V SPAN
–30
–40
85
80
75
70
65
–50
–60
–70
–80
SNR/NOISE FLOOR – 2V SPAN
–90
–100
–110
–120
140.1
–21
–15
–12
–9
–24
–18
–6
4
8
20
FREQUENCY – MHz
32
0
12
16
24
28
A
– dBFS
IN
TPC 19. Dual-Tone 8K FFT with fIN–1 = 44.2 MHz and
fIN–2 = 45.6 MHz
TPC 22. Dual-Tone SNR and SFDR with fIN–1 = 44.2 MHz
and fIN–2 = 45.6 MHz
0
165.1
160.1
155.1
150.1
90
85
SNR = 68.5dBFS
–10
–20
SFDR – 2V SPAN
SFDR = 75dBFS
NOISE FLOOR = 143.6dBFS/Hz
–30
–40
80
75
SFDR – 1V SPAN
–50
–60
–70
SNR/NOISE FLOOR – 2V SPAN
145.1
140.1
135.1
–80
70
65
60
–90
–100
–110
–120
SNR/NOISE FLOOR – 1V SPAN
–21
–15
–12
–9
–24
–18
–6
20
FREQUENCY – MHz
32
0
4
8
12
16
24
28
A
– dBFS
IN
TPC 20. Dual-Tone 8K FFT with fIN–1 = 69.2 MHz and
TPC 23. Dual-Tone SNR and SFDR with fIN–1 = 69.2 MHz
and fIN–2 = 70.6 MHz
f
IN–2 = 70.6 MHz
0
–10
–20
165.1
160.1
155.1
150.1
145.1
140.1
90
85
SNR = 67.5dBFS
SFDR – 2V SPAN
SFDR = 75dBFS
NOISE FLOOR = 142.6dBFS/Hz
–30
–40
80
75
70
65
60
SFDR – 1V SPAN
–50
–60
SNR/NOISE FLOOR – 2V SPAN
–70
–80
–90
SNR/NOISE FLOOR – 1V SPAN
–100
–110
–120
135.1
–21
–15
–12
–9
–18
–6
4
8
20
FREQUENCY – MHz
32
–24
0
12
16
24
28
A
– dBFS
IN
TPC 21. Dual-Tone 8K FFT with fIN–1 = 139.2 MHz and
IN–2 = 140.7 MHz
TPC 24. Dual-Tone SNR and SFDR with fIN–1 = 139.2 MHz
and fIN–2 = 140.7 MHz
f
–12–
REV. 0
AD9226
165.1
0
–10
–20
90
85
SFDR – 2V SPAN
f
f
= 190.82MHz
IN
SAMPLE
= 61.44MSPS
160.1
–30
–40
155.1
80
75
SFDR – 1V SPAN
–50
–60
150.1
SNR/NOISE FLOOR – 2V SPAN
–70
–80
145.1
140.1
135.1
70
65
60
–90
–100
–110
–120
SNR/NOISE FLOOR – 1V SPAN
–21
–15
– dBFS
–12
–9
–24
–18
–6
25
0
5
10
15
20
30
FREQUENCY – MHz
A
IN
TPC 25. Single-Tone 8K FFT at IF = 190 MHz–WCDMA
(fIN = 190.82 MHz, fSAMPLE = 61.44 MSPS)
TPC 28. Single-Tone SNR and SFDR vs. AIN at IF= 190 MHz
–WCDMA (fIN–1 = 190.8 MHz, fSAMPLE = 61.44 MSPS)
0
85
80
75
70
65
60
55
160.1
155.1
SNR = 65.1dBFS
–10
–20
SFDR = 59dBFS
SFDR – 2V SPAN
NOISE FLOOR = 140.2dBFS/Hz
–30
–40
150.1
145.1
140.1
SFDR – 1V SPAN
–50
–60
SNR/NOISE FLOOR – 2V SPAN
–70
–80
–90
SNR/NOISE FLOOR – 1V SPAN
–100
–110
–120
135.1
130.1
4
8
20
FREQUENCY – MHz
32
–21
0
12
16
24
28
–24
–18
–15
– dBFS
–12
–9
–6
A
IN
TPC 26. Dual-Tone 8K FFT with fIN–1 = 239.1 MHz and
fIN–2 = 240.7 MHz
TPC 29. Dual-Tone SNR and SFDR with fIN–1 = 239.1 MHz
and fIN–2 = 240.7 MHz
–35
–45
–55
–65
INPUT SPAN = 2V p–p
–75
–85
–95
INPUT SPAN = 1V p–p
1
10
FREQUENCY – MHz
100
1000
TPC 27. CMRR vs. Frequency (AIN = –0 dBFS and
CML = 2.5 V)
–13–
REV. 0
AD9226
and/or shunt capacitor can help limit the wideband noise at the
ADC’s input by forming a low-pass filter. The source imped-
ance driving VINA and VINB should be matched. Failure to
provide matching will result in degradation of the AD9226’s
SNR, THD, and SFDR.
THEORY OF OPERATION
The AD9226 is a high-performance, single-supply 12-bit ADC.
The analog input of the AD9226 is very flexible allowing for both
single-ended or differential inputs of varying amplitudes that can
be ac- or dc-coupled.
It utilizes a nine-stage pipeline architecture with a wideband,
sample-and-hold amplifier (SHA) implemented on a cost-
effective CMOS process. A patented structure is used in the
SHA to greatly improve high frequency SFDR/distortion. This
also improves performance in IF undersampling applications.
Each stage of the pipeline, excluding the last stage, consists of a
low resolution flash ADC connected to a switched capacitor
DAC and interstage residue amplifier (MDAC). The residue
amplifier amplifies 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 of the stages to facilitate digital
correction of flash errors. The last stage simply consists of a
flash ADC.
C
H
Q
S2
C
C
PIN
C
Q
S
S1
PAR
VINA
VINB
Q
C
Q
H1
S
S1
C
C
PIN
Q
S2
PAR
C
H
Figure 3. Equivalent Input Circuit
V
V
CC
Factory calibration ensures high linearity and low distortion.
R
S
AD9226
33⍀
VINA
ANALOG INPUT OPERATION
15pF
R
33⍀
S
Figure 3 shows the equivalent analog input of the AD9226 which
consists of a 750 MHz differential SHA. The differential input
structure of the SHA is highly flexible, allowing the device to be
easily configured for either a differential or single-ended input.
The analog inputs, VINA and VINB, are interchangeable with
the exception that reversing the inputs to the VINA and VINB
pins results in a data inversion (complementing the output word).
EE
VINB
VREF
0.1F
10F
SENSE
REFCOM
Figure 4. Series Resistor Isolates Switched-Capacitor
SHA Input from Op Amp; Matching Resistors Improve
SNR Performance
The optimum noise and dc linearity performance for either
differential or single-ended inputs is achieved with the largest input
signal voltage span (i.e., 2 V input span) and matched input
impedance for VINA and VINB. Only a slight degradation in
dc linearity performance exists between the 2 V and 1 V input
spans.
OVERVIEW OF INPUT AND REFERENCE
CONNECTIONS
The overall input span of the AD9226 is equal to the potential
at the VREF pin. The VREF potential may be obtained from
the internal AD9226 reference or an external source (see
Reference Operation section).
High frequency inputs may find the 1 V span better suited to
achieve superior SFDR performance. (See Typical Perfor-
mance Characteristics.)
The ADC samples the analog input on the rising edge of the clock
input. During the clock low time (between the falling edge and
rising edge of the clock), the input SHA is in the sample mode;
during the clock high time it is in hold. System disturbances just
prior to the rising edge of the clock and/or excessive clock jitter
on the rising edge may cause the input SHA to acquire the wrong
value and should be minimized.
In differential applications, the center point of the span is
obtained by the common-mode level of the signals. In single-
ended applications, the center point is the dc potential applied
to one input pin while the signal is applied to the opposite input
pin. Figures 5a–5f show various system configurations.
DRIVING THE ANALOG INPUTS
When the ADC is driven by an op amp and a capacitive load is
switched onto the output of the op amp, the output will momen-
tarily drop due to its effective output impedance. As the output
recovers, ringing may occur. To remedy the situation, a series
resistor can be inserted between the op amp and the SHA
input as shown in Figure 4. A shunt capacitance also acts like
a charge reservoir, sinking or sourcing the additional charge
required by the hold capacitor, CH, further reducing current
transients seen at the op amp’s output.
The AD9226 has a very flexible input structure allowing it to
interface with single-ended or differential input interface circuitry.
The optimum mode of operation, analog input range, and asso-
ciated interface circuitry will be determined by the particular
applications performance requirements as well as power supply
options.
DIFFERENTIAL DRIVER CIRCUITS
Differential operation requires that VINA and VINB be simulta-
neously driven with two equal signals that are 180؇ out of phase
with each other.
The optimum size of this resistor is dependent on several factors,
including the ADC sampling rate, the selected op amp, and the
particular application. In most applications, a 30 Ω to 100 Ω
resistor is sufficient.
Differential modes of operation (ac- or dc-coupled input) provide
the best THD and SFDR performance over a wide frequency
range. They should be considered for the most demanding
spectral-based applications (e.g., direct IF conversion to digital).
For noise-sensitive applications, the very high bandwidth of the
AD9226 may be detrimental and the addition of a series resistor
–14–
REV. 0
AD9226
1.5V
0.5V
2.5V
AD9226
VINA
CMLEVEL
33⍀
15pF
3.0V
2.5V
2.0V
0.1F
AD9226
(LQFP)
0.1F
0.1F
33⍀
VINB
VINA
33⍀
1V
CAPT
CAPB
49.9⍀
15pF
0.1F
VREF
10F
VINB
CAPT
CAPB
33⍀
0.1F
10F
SENSE
REFCOM
0.1F
10F
2V
0.1F
0.1F
VREF
3.0V
2.5V
2.0V
10F
0.1F
SENSE
Figure 5a. 1 V Single-Ended Input, Common-Mode
Voltage = 1 V
Figure 5e. 2 V Differential Input, Common-Mode
Voltage = 2.5 V
1.25V
AD9226
0.75V
33⍀
10k⍀ 10k⍀
VINA
AVDD
0.1F
0.1F
49.9⍀
15pF
0.1F
CAPT
CAPB
VINB
33⍀
2.5V
33⍀
2.75V
2.5V
2.0V
10F
AD9226
1V
0.1F
VREF
1.25V
0.75V
VINA
10F
0.1F
0.1F
0.1F
49.9⍀
15pF
SENSE
VINB
CAPT
CAPB
33⍀
10F
1V
0.1F
VREF
Figure 5b. 1 V Differential Input, Common-Mode
Voltage = 1 V
2.75V
2.5V
2.25V
10F
0.1F
SENSE
Figure 5f. 1 V Differential Input, Common-Mode
2.5V
AD9226
1.5V
Voltage = 2.5 V (Recommended for IF Undersampling)
33⍀
VINA
0.1F
0.1F
49.9⍀
15pF
The differential input characterization for this data sheet was
performed using the configuration shown in Figure 7.
VINB
CAPT
CAPB
33⍀
10F
2V
0.1F
Since not all applications have a signal preconditioned for
differential operation, there is often a need to perform a single-
ended-to-differential conversion. In systems that do not need to
be dc-coupled, an RF transformer with a center tap is the best
method to generate differential inputs for the AD9226. It pro-
vides all the benefits of operating the ADC 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 ADC. An improvement
in THD and SFDR performance can be realized by operating
the AD9226 in the differential mode. The performance enhance-
ment between the differential and single-ended mode is most
noteworthy as the input frequency approaches and goes beyond
the Nyquist frequency (i.e., fIN > FS /2).
VREF
2.5V
1.5V
10F
0.1F
SENSE
Figure 5c. 2 V Differential Input, Common-Mode
Voltage = 2 V
3.0V
AD9226
VINA
1.0V
33⍀
15pF
0.1F
0.1F
VINB
33⍀
CAPT
CAPB
The circuit shown in Figure 6a is an ideal method of applying
a differential dc drive to the AD9226. It uses an AD8138 to
derive a differential signal from a single-ended one. Figure 6b
illustrates its performance.
2V
VREF
10F
0.1F
10F
SENSE
REFCOM
0.1F
Figure 7 presents the schematic of the suggested transformer
circuit. The circuit uses a Minicircuits RF transformer, model
T1-1T, which has an impedance ratio of four (turns ratio of 2).
The schematic assumes that the signal source has a 50 Ω source
impedance. The center tap of the transformer provides a con-
venient means of level-shifting the input signal to a desired
common-mode voltage. In Figure 7 the transformer centertap
is connected to a resistor divider at the midsupply voltage.
Figure 5d. 2 V Single-Ended Input, Common-Mode
Voltage = 2 V
–15–
REV. 0
AD9226
SINGLE-ENDED DRIVER CIRCUITS
1V p-p
The AD9226 can be configured for single-ended operation using
dc- or ac-coupling. In either case, the input of the ADC must be
driven from an operational amplifier that will not degrade the
ADC’s performance. Because the ADC operates from a single
supply, it will be necessary to level-shift ground-based bipolar
signals to comply with its input requirements. Both dc- and
ac-coupling provide this necessary function, but each method
results in different interface issues which may influence the
system design and performance.
0.1F
4.7F
1k⍀
49⍀
1k⍀
0.1F
V
V
A
IN
499⍀
CAPT
AD9226
CAPB
450⍀
15pF
0.1F
10F
AD8138
49⍀
499⍀
0.1F
49⍀
B
IN
499⍀
Single-ended operation requires that VINA be ac- or dc-coupled
to the input signal source, while VINB of the AD9226 be biased
to the appropriate voltage corresponding to the middle of the input
span. The single-ended specifications for the AD9226 are char-
acterized using Figure 9a circuitry with input spans of 1 V and
2 V. The common-mode level is 2.5 V.
Figure 6a. Direct-Coupled Drive Circuit with AD8138
Differential Op Amp
0
SNR = 66.9dBc
SFDR = 70.0dBc
–20
–40
–60
–80
If the analog inputs exceed the supply limits, internal parasitic
diodes will turn on. This will result in transient currents within
the device. Figure 8 shows a simple means of clamping an input.
It uses a series resistor and two diodes. An optional capacitor is
shown for ac-coupled applications. A larger series resistor can
be used to limit the fault current through D1 and D2. This
can cause a degradation in overall performance. A similar
clamping circuit can also be used for each input if a differen-
tial input signal is being applied. A better method to ensure
the input is not overdriven is to use amplifiers powered by a single
5 V supply such as the AD8138.
–100
–120
0
4
8
12
16
20
24
28
32
MHz
OPTIONAL
AC-COUPLING
CAPACITOR
AVDD
D2
V
CC
Figure 6b. FS = 65 MSPS, fIN = 30 MHz, Input Span = 1 V p-p
R
R
20⍀
S1
S2
30⍀
The same midsupply potential may be obtained from the
CMLEVEL pin of the AD9226 in the LQFP package.
AD9226
D1
Referring to Figure 7, a series resistor, RS, is inserted between the
AD9226 and the secondary of the transformer. The value of
33 ohm was selected to specifically optimize both the THD and
SNR performance of the ADC. RS and the internal capacitance
help provide a low-pass filter to block high-frequency noise.
V
EE
Figure 8. Simple Clamping Circuit
AC-COUPLING AND INTERFACE ISSUES
For applications where ac-coupling is appropriate, the op amp
output can be easily level-shifted by means of a coupling
capacitor. This has the advantage of allowing the op amp’s com-
mon-mode level to be symmetrically biased to its midsupply
level (i.e., (AVDD/2). Op amps that operate symmetrically with
respect to their power supplies typically provide the best ac
performance as well as greatest input/output span. Various high-
speed performance amplifiers that are restricted to +5 V/–5 V
operation and/or specified for 5 V single-supply operation can be
easily configured for the 2 V or 1 V input span of the AD9226.
Transformers with other turns ratios may also be selected to
optimize the performance of a given application. For example, a
given input signal source or amplifier may realize an improve-
ment in distortion performance at reduced output power levels
and signal swings. By selecting a transformer with a higher
impedance ratio (e.g., Minicircuits T16-6T with a 1:16 imped-
ance ratio), the signal level is effectively “stepped up” thus
further reducing the driving requirements of signal source.
AVDD
1k⍀
R
33⍀
Simple AC Interface
S
0.1F
0.1F
Figure 9a shows a typical example of an ac-coupled, single-
ended configuration of the SSOP package. The bias voltage
shifts the bipolar, ground-referenced input signal to approxi-
mately AVDD/2. The capacitors, C1 and C2, are 0.1 µF ceramic
and 10 µF tantalum capacitors in parallel to achieve a low
cutoff frequency while maintaining a low impedance over a
wide frequency range. The combination of the capacitor and the
resistor form a high-pass network with a high-pass –3 dB fre-
quency determined by the equation,
VINA
CAPT
AD9226
10F
49.9⍀
0.1F
15pF
1k⍀
CAPB
0.1F
VINB
R
33⍀
MINICIRCUITS
T1-1T
S
Figure 7. Transformer-Coupled Input
f
–3 dB = 1/(2 × π × R × (C1 + C2))
–16–
REV. 0
AD9226
The low-impedance VREF output can be used to provide dc
bias levels to the fixed VINB pin and the signal on VINA. Fig-
ure 9b shows the VREF configured for 2.0 V, thus the input
range of the ADC is 1.0 V to 3.0 V. Other input ranges could
be selected by changing VREF.
Figure 10 illustrates the relation between common-mode voltage
and THD. Note that optimal performance occurs when the
reference voltage is set to 2.0 V (input span = 2.0 V).
DC-COUPLING AND INTERFACE ISSUES
Many applications require the analog input signal to be dc-coupled
to the AD9226. An operational amplifier can be configured to
rescale and level-shift the input signal to make it compatible
with the selected input range of the ADC.
When the inputs are biased from the reference (Figure 9b),
there may be a slight degeneration of dynamic performance. A
midsupply output level is available at the CM LEVEL pin of the
LQFP package.
The selected input range of the AD9226 should be considered
with the headroom requirements of the particular op amp to
prevent clipping of the signal. Many of the new high-performance
op amps are specified for only 5 V operation and have limited
input/output swing capabilities. Also, since the output of a dual
supply amplifier can swing below absolute minimum (–0.3 V),
clamping its output should be considered in some applications
(see Figure 8). When single-ended, dc-coupling is needed, the
use of the AD8138 in a differential configuration (Figure 9a) is
highly recommended.
+1V
C1
V
V
0V
10F
–1V
R
R
+5V
V
IN
R
S
0.1F
0.1F
VINA
VINB
C2
0.1F
CAPT
–5V
15pF
10F
AD9226
CAPB
R
S
0.1F
R
R
0.1F
10F
VREF
Simple Op Amp Buffer
In the simplest case, the input signal to the AD9226 will already
be biased at levels in accordance with the selected input range. It
is necessary to provide an adequately low source impedance for
the VINA and VINB analog pins of the ADC.
3.5
2.5
1.5
10F
0.1F
Figure 9a. AC-Coupled Input Configuration
REFERENCE OPERATION
0.1F
The AD9226 contains an on-board bandgap reference that
provides a pin-strappable option to generate either a 1 V or
2 V output. With the addition of two external resistors, the user
can generate reference voltages between 1 V and 2 V. See
Figures 5a-5f for a summary of the pin-strapping options for the
AD9226 reference configurations. Another alternative is to use
an external reference for designs requiring enhanced accuracy
and/or drift performance described later in this section.
V
IN
10F
AD9226
R
S
VINA
0.1F
0.1F
1k⍀
CAPT
15pF
10F
1k⍀
CAPB
R
S
0.1F
VINB
0.1F
Figure 11a shows a simplified model of the internal voltage refer-
ence of the AD9226. A reference amplifier buffers a 1 V fixed
reference. The output from the reference amplifier, A1, appears
on the VREF pin. The voltage on the VREF pin determines
the full-scale input span of the ADC. This input span equals,
10F
VREF
10F
0.1F
Full-Scale Input Span = VREF
Figure 9b. Alternate AC-Coupled Input Configuration
The voltage appearing at the VREF pin, and the state of the
internal reference amplifier, A1, are determined by the voltage
appearing at the SENSE pin. The logic circuitry contains com-
parators that monitor the voltage at the SENSE pin. If the
SENSE pin is tied to AVSS, the switch is connected to the
internal resistor network thus providing a VREF of 2.0 V. If the
SENSE pin is tied to the VREF pin via a short or resistor, the
switch will connect to the SENSE pin. This connection will pro-
vide a VREF of 1.0 V. An external resistor network will provide
an alternative VREF between 1.0 V and 2.0 V (see Figure 12).
Another comparator controls internal circuitry that will disable
the reference amplifier if the SENSE pin is tied to AVDD.
Disabling the reference amplifier allows the VREF pin to be
driven by an external voltage reference.
–84
–83
–82
–81
–80
–79
–78
–77
–76
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5 5.0
volts
Figure 10. THD vs. Common-Mode Voltage
(2 V Differential Input Span, fIN = 10 MHz)
–17–
REV. 0
AD9226
sets the input span to be 1.5 V p-p. The midscale voltage can
also be set to VREF by connecting VINB to VREF. Alterna-
tively, the midscale voltage can be set to 2.5 V by connecting
VINB to a low-impedance 2.5 V source as shown in Figure 12.
AD9226
A2
TO
A/D
CAPT
CAPB
2.5V
AD9226
VINA
33⍀
15pF
3.25V
1.75V
0.1F
0.1F
2.5V
VINB
33⍀
CAPT
CAPB
1.5V
VREF
VREF
SENSE
R1
10F
C1
A1
2.5k⍀ 0.1F
0.1F
10F
1V
R2
5k⍀
0.1F
REFCOM
SENSE
DISABLE
A1
LOGIC
REFCOM
Figure 12. Resistor Programmable Reference (1.5 V p-p
Input Span, Differential Input VCM = 2.5 V)
Figure 11a. Equivalent Reference Circuit
USING AN EXTERNAL REFERENCE
The AD9226 contains an internal reference buffer, A2 (see
Figure 11b), that simplifies the drive requirements of an external
reference. The external reference must be able to drive about
5 kΩ ( 20%) load. Note that the bandwidth of the reference
buffer is deliberately left small to minimize the reference noise
contribution. As a result, it is not possible to rapidly change the
reference voltage in this mode.
0.1F
VREF
CAPT
10F
10F
0.1F
0.1F
AD9226
CAPB
0.1F
Figure 11b. CAPT and CAPB DC-Coupling
Figure 13 shows an example of an external reference driving
both VINB and VREF. In this case, both the common-mode
voltage and input span are directly dependent on the value of
VREF. Both the input span and the center of the input span are
equal to the external VREF. Thus the valid input range extends
from (VREF + VREF/2) to (VREF – VREF/2). For example,
if the REF191, a 2.048 V external reference, is selected, the
input span extends to 2.048 V. In this case, 1 LSB of the AD9226
corresponds to 0.5 mV. It is essential that a minimum of a 10 µF
capacitor, in parallel with a 0.1 µF low-inductance ceramic
capacitor, decouple the reference output to ground.
The actual reference voltages used by the internal circuitry of the
AD9226 appear on the CAPT and CAPB pins. The voltages
on these pins are symmetrical about the analog supply. For
proper operation when using an internal or external reference, it
is necessary to add a capacitor network to decouple these pins.
Figure 11b shows the recommended decoupling network. The
turn-on time of the reference voltage appearing between CAPT
and CAPB is approximately 10 ms and should be evaluated in
any power-down mode of operation.
USING THE INTERNAL REFERENCE
The AD9226 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 12 of this data sheet, or
using an external reference.
To use an external reference, the SENSE pin must be connected
to AVDD. This connection will disable the internal reference.
AD9226
VINA
VINA+VREF/2
33⍀
15pF
33⍀
VINB–VREF/2
Pin Programmable Reference
0.1F
0.1F
5V
0.1F
VREF
VINB
By shorting the VREF pin directly to the SENSE pin, the inter-
nal reference amplifier is placed in a unity-gain mode and the
resultant VREF output is 1 V. By shorting the SENSE pin
directly to the REFCOM pin, the internal reference amplifier is
configured for a gain of 2.0 and the resultant VREF output is
2.0 V. The VREF pin should be bypassed to the REFCOM pin
with a 10 µF tantalum capacitor in parallel with a low-inductance
0.1 µF ceramic capacitor as shown in Figure 11b.
CAPT
CAPB
10F
10F
VREF
SENSE
0.1F
0.1F
5V
Figure 13. Using an External Reference
MODE CONTROLS
Clock Stabilizer
Resistor Programmable Reference
Figure 12 shows an example of how to generate a reference
voltage other than 1.0 V or 2.0 V with the addition of two exter-
nal resistors. Use the equation,
The clock stabilizer is a circuit that desensitizes the ADC from
clock duty cycle variations. The AD9226 eases system clock
constraints by incorporating a circuit that restores the internal duty
cycle to 50%, independent of the input duty cycle. Low jitter on
the rising edge (sampling edge) of the clock is preserved while
the noncritical falling edge is generated on-chip.
VREF = 1 V × (1 + R1/R2)
to determine appropriate values for R1 and R2. These resistors
should be in the 2 kΩ to 10 kΩ range. For the example shown,
R1 equals 2.5 kΩ and R2 equals 5 kΩ. From the equation above,
the resultant reference voltage on the VREF pin is 1.5 V. This
It may be desirable to disable the clock stabilizer, and may be
necessary when the clock frequency speed is varied or completely
–18–
REV. 0
AD9226
stopped. Once the clock frequency is changed, over 100 clock
cycles may be required for the clock stabilizer to settle to a dif-
ferent speed. When the stabilizer is disabled, the internal switching
will be directly affected by the clock state. If the external clock is
high, the SHA will be in hold. If the clock pulse is low, the SHA
will be in track. TPC 16 shows the benefits of using the clock
stabilizer. See Tables I and III.
Table IV. Output Data Format
Two’s
Binary
Complement
Input (V)
Condition (V)
Output Mode Mode
OTR
VINA–VINB < – VREF
VINA–VINB = – VREF
VINA–VINB = 0
0000 0000 0000 1000 0000 0000
0000 0000 0000 1000 0000 0000
1000 0000 0000 0000 0000 0000
1
0
0
0
1
Data Format Select (DFS)
The AD9226 may be set for binary or two’s complement data
output formats. See Tables I and II.
VINA–VINB = + VREF – 1 LSB 1111 1111 1111 0111 1111 1111
VINA–VINB ≥ + VREF
1111 1111 1111 0111 1111 1111
Out of Range (OTR)
SSOP Package
An out-of-range condition exists when the analog input voltage
is beyond the input range of the converter. OTR is a digital
output that is updated along with the data output corresponding
to the particular sampled analog input voltage. Hence, OTR has
the same pipeline delay (latency) as the digital data. It is LOW
when the analog input voltage is within the analog input range.
It is HIGH when the analog input voltage exceeds the input
range as shown in Figure 14. OTR will remain HIGH until the
analog input returns within the input range and another conversion
is completed. By logical ANDing OTR with the MSB and its
complement, overrange high or underrange low conditions can be
detected. Table V is a truth table for the over/underrange
circuit in Figure 15, which uses NAND gates. Systems requiring
programmable gain conditioning of the AD9226 input signal
can immediately detect an out-of-range condition, thus elimi-
nating gain selection iterations. Also, OTR can be used for
digital offset and gain calibration.
The SSOP mode control (Pin 22) has two functions. It enables/
disables the clock stabilizer and determines the output data format.
The exact functions of the mode pin are outlined in Table I.
Table I. Mode Select (SSOP)
Mode
DFS
Clock Duty Cycle Shaping
DNC
AVDD
GND
10 kΩ
Resistor
Binary
Binary
Clock Stabilizer Disabled
Clock Stabilizer Enabled
Two’s Complement Clock Stabilizer Enabled
Two’s Complement Clock Stabilizer Disabled
To GND
LQFP Package
Pin 35 of the LQFP package determines the output data format
(DFS). If it is connected to AVSS, the output word will be straight
binary. If it is connected to AVDD, the output data format will
be two’s complement. See Table II.
Table V. Out-of-Range Truth Table
Pin 43 of the LQFP package controls the clock stabilizer function
of the AD9226. If the pin is connected to AVDD, both clock
edges will be used in the conversion architecture. When Pin 43
is connected to AVSS, the internal duty cycle will be determined
by the clock stabilizer function within the ADC. See Table III.
OTR
MSB
Analog Input Is
0
0
1
1
0
1
0
1
In Range
In Range
Underrange
Overrange
Table II. DFS Pin Controls
+FS – 1 1/2 LSB
OTR DATA OUTPUTS
DFS Function
Pin 35 Connection
OTR
1111 1111 1111
1111 1111 1111
1111 1111 1110
1
0
0
Straight Binary
Two’s Complement
AVDD
AVSS
–FS +1/2 LSB
0000 0000 0001
0000 0000 0000
0000 0000 0000
0
0
1
Table III. Clock Stabilizer Pin
–FS
–FS – 1/2 LSB
Clock Restore Function
Pin 43 Connection
+FS
+FS – 1/2 LSB
Clock Stabilizer Enabled
Clock Stabilizer Disabled
AVDD
AVSS
Figure 14. OTR Relation to Input Voltage and Output Data
MSB
OVER = 1
OTR
DIGITAL INPUTS AND OUTPUTS
Digital Outputs
UNDER = 1
MSB
Table IV details the relationship among the ADC input, OTR, and
straight binary output.
Figure 15. Overrange or Underrange Logic
–19–
REV. 0
AD9226
Digital Output Driver Considerations
3. The inherent distributed capacitor formed by the power
plane, PCB insulation, and ground plane.
The AD9226 output drivers can be configured to interface with
5 V or 3.3 V logic families by setting DRVDD to 5 V or 3.3 V
respectively. The output drivers are sized to provide sufficient
output current to drive a wide variety of logic families. However,
large drive currents tend to cause glitches on the supplies and may
affect converter performance. Applications requiring the ADC to
drive large capacitive loads or large fan outs may require external
buffers or latches.
It is important to design a layout that prevents noise from cou-
pling onto the input signal. Digital signals should not be run in
parallel with input signal traces and should be routed away from
the input circuitry. While the AD9226 features separate analog
and driver ground pins, it should be treated as an analog com-
ponent. The AVSS and DRVSS pins must be joined together
directly under the AD9226. A solid ground plane under the
ADC is acceptable if the power and ground return currents are
carefully managed.
OEB Function (Three-State)
The LQFP-packaged AD9226 has Three-State (OEB) ability. If
the OEB pin is held low, the output data drivers are enabled. If
the OEB pin is high, the output data drivers are placed in a high
impedance state. It is not intended for rapid access to buss.
AVDD
10F
0.1F
AD9226
Clock Input Considerations
AVSS
High-speed, high-resolution ADCs are sensitive to the quality of
the clock input. The clock input should be treated as an analog
signal in cases where aperture jitter may affect the dynamic
performance of the AD9226. Power supplies for clock drivers
should be separated from the ADC output driver supplies to
avoid modulating the clock signal with digital noise. Low-jitter
crystal controlled oscillators make the best clock sources.
Figure 17. Analog Supply Decoupling
Analog and Digital Driver Supply Decoupling
The AD9226 features separate analog and digital supply and
ground pins, helping to minimize digital corruption of sensitive
analog signals. In general, AVDD (analog power) should be
decoupled to AVSS (analog ground). The AVDD and AVSS
pins are adjacent to one another. Also, DRVDD (digital power)
should be decoupled to DRVDD (digital ground). The decoupling
capacitors (especially 0.1 µf) should be located as close to the
pins as possible. Figure 17 shows the recommended decoupling
for the pair of analog supplies; 0.1 µF ceramic chip and 10 µF
tantalum capacitors should provide adequately low impedance
over a wide frequency range.
The quality of the clock input, particularly the rising edge, is
critical in realizing the best possible jitter performance of the
part. Faster rising edges often have less jitter.
Clock Input and Power Dissipation
Most of the power dissipated by the AD9226 is from the analog
power supplies. However, lower clock speeds will reduce digital
current. Figure 16 shows the relationship between power and
clock rate.
600
550
CML
VR
AD9226
0.1F
0.1F
500
Figure 18. CML Decoupling (LQFP)
Bias Decoupling
DRVDD = 5V
450
400
The CML and VR are analog bias points used internally by the
AD9226. These pins must be decoupled with at least a 0.1 µF
capacitor as shown in Figure 18. The dc level of CML is approxi-
mately AVDD/2. This voltage should be buffered if it is to be
used for any external biasing. CML and VR outputs are only
available in the LQFP package.
DRVDD = 3V
350
300
250
200
65
75
5
15
25
35
45
55
DRVDD
SAMPLE RATE – Msps
10F
0.1F
AD9226
DRVSS
Figure 16. Power Consumption vs. Sample Rate
GROUNDING AND DECOUPLING
Analog and Digital Grounding
Figure 19. Digital Supply Decoupling
Proper grounding is essential in any high-speed, high-resolution
system. Multilayer printed circuit boards (PCBs) are recom-
mended to provide optimal grounding and power schemes. The
use of ground and power planes offers distinct advantages:
CML
The LQFP-packaged AD9226 has a midsupply reference point.
This midsupply point is used within the internal architecture of
the AD9226 and must be decoupled with a 0.1 µF capacitor. It
will source or sink a load of up to 300 µA. If more current is
required, it should be buffered with a high impedance amplifier.
1. The minimization of the loop area encompassed by a signal
and its return path.
2. The minimization of the impedance associated with ground
and power paths.
–20–
REV. 0
AD9226
VR
S3 connector. The various input signal options are accessible by
the jumper connections. Refer to the Evaluation Board schematic.
VR is an internal bias point on the LQFP package. It must be
decoupled to ground with a 0.1 µF capacitor.
The clock input signal to the AD9226 evaluation board can be
applied to one of two inputs, CLOCK and AUXCLK. The
CLOCK input should be selected if the frequency of the input
clock signal is at the target sample rate of the AD9226. The
input clock signal is ac-coupled and level-shifted to the switch-
ing threshold of a 74VHC02 clock driver. The AUXCLK input
should be selected in applications requiring the lowest jitter and
SNR performance (i.e., IF Undersampling characterization). It
allows the user to apply a clock input signal that is 4× the target
sample rate of the AD9226. A low-jitter, differential divide-by-4
counter, the MC100EL33D, provides a 1× clock output that is
subsequently returned back to the CLOCK input via JP7. For
example, a 260 MHz signal (sinusoid) will be divided down to
a 65 MHz signal for clocking the ADC. Note, R1 must be
removed with the AUXCLK interface. Lower jitter is often
achieved with this interface since many RF signal generators
display improved phase noise at higher output frequencies and
the slew rate of the sinusoidal output signal is 4× that of a 1×
signal of equal amplitude.
The digital activity on the AD9226 chip falls into two general
categories: correction logic and output drivers. The internal
correction logic draws relatively small surges of current, mainly
during the clock transitions. The output drivers draw large
current impulses while the output bits are changing. The size
and duration of these currents are a function of the load on the
output bits: large capacitive loads are to be avoided.
For the digital decoupling shown in Figure 19, 0.1 µF ceramic
chip and 10 µF tantalum capacitors are appropriate. Reason-
able capacitive loads on the data pins are less than 20 pF per
bit. Applications involving greater digital loads should consider
increasing the digital decoupling proportionally and/or using
external buffers/latches.
A complete decoupling scheme will also include large tantalum
or electrolytic capacitors on the power supply connector to
reduce low-frequency ripple to negligible levels.
EVALUATION BOARD AND TYPICAL BENCH
Figure 20 shows the bench characterization setup used to evalu-
ate the AD9226’s ac performance for many of the data sheet
characterization curves. Signal and Clock RF generators A and
B are high-frequency, “very” low-phase noise frequency sources.
These generators should be phase locked by sharing the same
10 MHz REF signal (located on the instruments back panel) to
allow for nonwindowed, coherent FFTs. Also, the AUXCLK
option on the AD9226 evaluation board should be used to
achieve the best SNR performance. Since the distortion and
broadband noise of an RF generator can often be a limiting
factor in measuring the true performance of an ADC, a high Q
passive bandpass filter should be inserted between the generator
and AD9226 evaluation board.
CHARACTERIZATION TEST SETUP
The AD9226 evaluation board is configured to operate upon
applying both power and the analog and clock input signals. It
provides three possible analog input interfaces to characterize
the AD9226’s ac and dc performance. For ac characterization, it
provides a transformer coupled input with the common-mode
input voltage (CMV) set to AVDD/2. Note, the evaluation
board is shipped with a transformer coupled interface and a 2 V
input span. For differential dc coupled applications, the evalua-
tion board has provisions to be driven by the AD8138 amplifier.
If a single-ended input is desired, it may be driven through the
5V
5V
3V
3V
AVDD
GND DUT GND DUT
DVDD
AVDD
DVDD
S4
INPUT
xFMR
SIGNAL SYNTHESIZER
65(OR 260 MHz), 4V p-p
HP8644
1 MHz
BANDPASS FILTER
REFIN
AD9226
OUTPUT
WORD
(P1)
DSP
EQUIPMENT
EVALUATION BOARD
S4
AUX CLOCK
(،4)
S1
INPUT
CLOCK
CLK SYNTHESIZER
65(OR 260 MHz), 4V p-p
HP8644
10 MHz
REFOUT
Figure 20. Evaluation Board Connections
–21–
REV. 0
AD9226
DUTAVDD
TP5
WHT
JP23
JP25
JP24
JP22
C1
10F
10V
C36
0.1F
C39
0.001F
AD9226LQFP
R3
10k⍀
28
27
26
25
24
21
20
19
18
17
16
13
12
11
10
8
3
4
AVDD1
AVDD2
AVSS1
AVSS2
SENSE
VREF
OTR
MSB-B1
B2
OTR0
D130
D120
D110
D100
D90
1
C21
10F
10V
R4
10k⍀
C35
0.1F
2
B3
36
37
38
39
40
41
42
45
46
47
B4
B5
REFCOM
CAPB1
CAPB2
CAPT1
CAPT2
CML
B6
C34
0.1F
D80
B7
D70
C20
B8
D60
C33
0.1F
10F
B9
D50
10V
B10
B11
B12
B13
LSB-B14
NC3
OEB
VR
D40
C32
0.1F
D30
AVDD
U1
C50
0.1F
VINA
VINA
D20
JP6
JP1
JP2
SHEET 3
TP2
VINB
VINB
D10
FBEAD L1
2
RED
5
1
NC1
D00
DUTAVDDIN TB1
2
DUTAVDD
6
32
33
31
34
30
29
23
22
C58
22F
25V
C59
0.1F
NC2
9
AVSS3
AVSS4
AVDD3
AVDD4
DRVSS3
DRVDD3
AGND TB1
3
1
48
35
43
7
DUTAVDD
C2
0.1F
R42
1k⍀
DFS
DUTY
CLK
NC4
TP1
C23
10F
10V
FBEAD L2
2
RED
C38
0.1F
C41
0.001F
1
R6
AVDDIN
TB1
AVDD
C47
22F
25V
1k⍀
C52
0.1F
44
15
14
R10
1k⍀
DRVDD1 DRVDD2
DRVSS1 DRVSS2
DUTCLK
TP3
FBEAD L3
2
RED
DUTDRVDD
WHT
TP6
1
DRVDDIN TB1
AGND TB1
5
4
DUTDRVDD
C48
22F
25V
C3
10F
10V
C53
0.1F
C37
0.1F
C40
0.001F
NC = NO CONNECT
TP4
FBEAD L4
RED
DVDD
TP12
2
1
DVDDIN
TB1
6
C6
22F
25V
C14
0.1F
TP11
BLK
TP13
BLK
TP14
BLK
BLK
Figure 21. AD9226 Evaluation Board
–22–
REV. 0
AD9226
C12
DVDD
0.1F
10V
2
10F
1
C4
74VHC541
1
20
10
18
17
16
15
14
13
12
11
RP1
G1
VCC
GND
Y1
22⍀
AUXCLK
1
2
3
4
5
6
7
16
15
14
13
12
11
10
19
1
3
5
7
9
P1
P1
P1
P1
P1
P1
P1
P1
P1
2
4
6
8
1N5712
D2
S5
T1–1T
G2
A1
A2
A3
A4
A5
A6
A7
A8
RP1
22⍀
6
5
4
1
2
3
1
2
3
4
5
6
7
8
9
D13
D12
D11
D10
D9
2
2
R11
RP1
22⍀
49.9⍀
Y2
Y3
Y4
Y5
Y6
Y7
Y8
2
D1
T2
U6
RP1
22⍀
1N5712
RP1
22⍀
P1 10
P1 12
P1 14
MC100EL33D
RP1
22⍀
D8
8
7
6
5
1
2
3
4
VCC
OUT
REF
VEE
NC
INA
INB
AVDD
11 P1
13 P1
D7
U3
RP1
22⍀
D6
RP1
INCOM
22⍀
8
1
2
3
4
5
6
9
15 P1
17 P1
19 P1
21 P1
23 P1
25 P1
27 P1
29 P1
31 P1
33 P1
35 P1
37 P1
39 P1
P1 16
P1 18
P1 20
P1 22
P1 24
C11
0.1F
RP2
22⍀
AVDD
AVDD
R12
AVDD
16
15
14
13
12
11
C26
10F
10V
C18
0.1F
10V
10F
C5
RP2
22⍀
2
1
C17
0.1F
R13
113⍀
113⍀
C19
0.1F
U3
DECOUPLING
RP2
22⍀
74VHC541
1
R14
90⍀
R15
90⍀
20
10
18
17
16
15
14
13
12
11
G1
VCC
GND
Y1
19
JP7
RP2
22⍀
G2
A1
A2
A3
A4
A5
A6
A7
A8
2
3
4
5
6
7
8
9
D5
D4
RP2
22⍀
R19 R2 R18
4k⍀ 5k⍀ 4k⍀
Y2
P1 26
P1 28
P1 30
P1 32
P1 34
P1 36
P1 38
P1 40
AVDD
U7
Y3
D3
RP2
22⍀
Y4
JP17
B
D2
3
1
A
Y5
D1
2
CLOCK
S1
TP7
C13
R7
22⍀
10
WHT
13
8a
8b
0.10F
DUTCLK
Y6
D0
1
12
11
Y7
2
OTR
R9
22⍀
R1
49.9⍀
74VHC04
74VHC04
8c
JP4
JP3
Y8
RP2
22⍀
8
7
9
1
2
74VHC04
AVDD
8d
9
8
C3
10F
10V
74VHC04
8e
C10
0.1F
5
6
RP2
22⍀
U8
10
74VHC04
8f
DECOUPLING
NC = NO CONNECT
3
4
74VHC04
Figure 22. AD9226 Evaluation Board
–23–
REV. 0
AD9226
RP3
22⍀
1
2
3
4
8
7
6
5
OTRO
D130
D120
D110
OTR
D13
D12
D11
RP3
22⍀
JP5
RP3
22⍀
AVDD
SINGLE
INPUT
C9
0.33F
R40
1k⍀
C7
0.1F
RP3
22⍀
S3
1
JP42
2
R5
49.9⍀
R41
1k⍀
RP4
C15
10F
10V
JP40
JP45
JP46
22⍀
1
2
3
4
8
7
6
5
AVDD
AVDD
D100
D90
D80
D70
D10
D9
RP4
22⍀
C44
TBD
R21
22⍀
1
2
R32
10k⍀
RP4
22⍀
VINA
C24
50pF
VINB
C69
0.1F
R22
22⍀
SHEET 1
D8
RP4
22⍀
C8
0.1F
R33
10k⍀
R37
499⍀
D7
C43
JP41
JP43
TBD
3
R34
523⍀
VCC
–W
1
8
4
RP5
22⍀
1
2
3
4
8
VO؉
VDC
VO–
2
D60
D6
D5
D4
AMP INPUT
R35
499⍀
U2
RP5
22⍀
S2
1
7
6
5
؉W
VEE
D50
D40
5
2
RP5
22⍀
XFMR INPUT
DUTAVDD
R31
49.9⍀
AD8138
R36
499⍀
S4
T1–1T
6
R38
1k⍀
6
5
4
1
2
3
1
RP5
22⍀
2
R24
49.9⍀
C25
0.33F
C16
0.1F
R8
1k⍀
T2
RP6
22⍀
1
2
3
4
8
7
6
5
D30
D20
D10
D00
D3
D2
D1
D0
RP6
22⍀
RP6
22⍀
RP6
22⍀
Figure 23. AD9226 Evaluation Board
Figure 24. Evaluation Board Component Side Layout (Not to Scale)
–24–
REV. 0
AD9226
Figure 25. Evaluation Board Solder Side Layout (Not to Scale)
Figure 26. Evaluation Board Power Plane
–25–
REV. 0
AD9226
Figure 27. Evaluation Board Ground Plane
Figure 28. Evaluation Board Component Side (Not to Scale)
–26–
REV. 0
AD9226
Figure 29. Evaluation Board Solder Side (Not to Scale)
–27–
REV. 0
AD9226
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
28-Lead Shrink Small Outline
(RS-28)
48-Lead Thin Plastic Quad Flatpack
(ST-48)
0.407 (10.34)
0.397 (10.08)
0.063 (1.60)
MAX
0.354 (9.00) BSC SQ
0.030 (0.75)
0.018 (0.45)
37
48
36
1
28
15
14
0.276
(7.00)
BSC
SQ
TOP VIEW
(PINS DOWN)
1
COPLANARITY
0.003 (0.08)
12
25
0؇
MIN
13
24
0.011 (0.27)
0.006 (0.17)
0.019 (0.5)
BSC
0.008 (0.2)
0.004 (0.09)
0.07 (1.79)
0.066 (1.67)
0.078 (1.98)
0.068 (1.73)
PIN 1
0.057 (1.45)
0.053 (1.35)
7؇
0؇
0.03 (0.762)
0.022 (0.558)
8°
0°
0.006 (0.15)
0.002 (0.05)
SEATING
PLANE
0.0256
(0.65)
BSC
0.015 (0.38)
0.010 (0.25)
0.008 (0.203)
0.002 (0.050)
SEATING
PLANE
0.009 (0.229)
0.005 (0.127)
–28–
REV. 0
相关型号:
AD9226ARSRL
IC 1-CH 12-BIT FLASH METHOD ADC, PARALLEL ACCESS, PDSO28, SSOP-28, Analog to Digital Converter
ADI
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