AD AD9280-EB

a
Complete 8-Bit, 32 MSPS, 95 mW
CMOS A/D Converter
AD9280
FEATURES
CMOS 8-Bit 32 MSPS Sampling A/D Converter
Pin-Compatible with AD876-8
Power Dissipation: 95 mW (3 V Supply)
Operation Between +2.7 V and +5.5 V Supply
Differential Nonlinearity: 0.2 LSB
Power-Down (Sleep) Mode
Three-State Outputs
Out-of-Range Indicator
Built-In Clamp Function (DC Restore)
Adjustable On-Chip Voltage Reference
IF Undersampling to 135 MHz
A single clock input is used to control all internal conversion
cycles. The digital output data is presented in straight binary
output format. An out-of-range signal (OTR) indicates an overflow condition which can be used with the most significant bit
to determine low or high overflow.
The AD9280 can operate with a supply range from +2.7 V to
+5.5 V, ideally suiting it for low power operation in high speed
applications.
The AD9280 is specified over the industrial (–40°C to +85°C)
temperature range.
PRODUCT HIGHLIGHTS
Low Power
PRODUCT DESCRIPTION
The AD9280 is a monolithic, single supply, 8-bit, 32 MSPS
analog-to-digital converter with an on-chip sample-and-hold
amplifier and voltage reference. The AD9280 uses a multistage
differential pipeline architecture at 32 MSPS data rates and
guarantees no missing codes over the full operating temperature
range.
The AD9280 consumes 95 mW on a 3 V supply (excluding the
reference power). In sleep mode, power is reduced to below
5 mW.
Very Small Package
The AD9280 is available in a 28-lead SSOP package.
Pin Compatible with AD876-8
The input of the AD9280 has been designed to ease the development of both imaging and communications systems. The user
can select a variety of input ranges and offsets and can drive the
input either single-ended or differentially.
The AD9280 is pin compatible with the AD876-8, allowing
older designs to migrate to lower supply voltages.
300 MHz Onboard Sample-and-Hold
The versatile SHA input can be configured for either singleended or differential inputs.
The sample-and-hold amplifier (SHA) is equally suited for both
multiplexed systems that switch full-scale voltage levels in successive channels and sampling single-channel inputs at frequencies up to and beyond the Nyquist rate. AC-coupled input
signals can be shifted to a predetermined level, with an onboard
clamp circuit. The dynamic performance is excellent.
Out-of-Range Indicator
The OTR output bit indicates when the input signal is beyond
the AD9280’s input range.
Built-In Clamp Function
Allows dc restoration of video signals.
The AD9280 has an onboard programmable reference. An
external reference can also be chosen to suit the dc accuracy and
temperature drift requirements of the application.
FUNCTIONAL BLOCK DIAGRAM
CLAMP
CLAMP
IN
CLK
DRVDD
AVDD
STBY
SHA
SHA
GAIN
SHA
GAIN
SHA
GAIN
SHA
VINA
GAIN
MODE
A/D
REFTF
A/D
REFTS
D/A
A/D
D/A
A/D
D/A
A/D
D/A
THREESTATE
CORRECTION LOGIC
REFBS
REFBF
OUTPUT BUFFERS
OTR
VREF
REFSENSE
1V
AD9280
D7 (MSB)
D0 (LSB)
AVSS
DRVSS
REV. D
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
AD9280–SPECIFICATIONS
(AVDD = +3 V, DRVDD = +3 V, FS = 32 MHz (50% Duty Cycle), MODE = AVDD, 2 V Input
Span from 0.5 V to 2.5 V, External Reference, TMIN to TMAX unless otherwise noted)
Parameter
Min
Symbol
RESOLUTION
FS
DC ACCURACY
Differential Nonlinearity
Integral Nonlinearity
Offset Error
Gain Error
DNL
INL
EZS
EFS
ANALOG INPUT
Input Voltage Range
Input Capacitance
Aperture Delay
Aperture Uncertainty (Jitter)
Input Bandwidth (–3 dB)
Full Power (0 dB)
DC Leakage Current
INTERNAL REFERENCE
Output Voltage (1 V Mode)
Output Voltage Tolerance (1 V Mode)
Output Voltage (2 V Mode)
Load Regulation (1 V Mode)
POWER SUPPLY
Operating Voltage
Supply Current
Power Consumption
Power-Down
Gain Error Power Supply Rejection
Max
8
CONVERSION RATE
REFERENCE VOLTAGES
Top Reference Voltage
Bottom Reference Voltage
Differential Reference Voltage
Reference Input Resistance1
Typ
REFTS
REFBS
AIN
CIN
tAP
tAJ
BW
AVDD
DRVDD
IAVDD
PD
MHz
± 0.2
± 0.3
± 0.2
± 1.2
± 1.0
± 1.5
± 1.8
± 3.9
LSB
LSB
% FSR
% FSR
2
10
4.2
AVDD
V
AVDD – 1 V
V p-p
kΩ
kΩ
1
4
2
REFTS
V
pF
ns
ps
300
43
MHz
µA
1
± 10
2
0.5
2.7
2.7
PSRR
DYNAMIC PERFORMANCE (AIN = 0.5 dBFS)
Signal-to-Noise and Distortion
SINAD
f = 3.58 MHz
f = 16 MHz
Effective Bits
f = 3.58 MHz
f = 16 MHz
Signal-to-Noise
SNR
f = 3.58 MHz
f = 16 MHz
Total Harmonic Distortion
THD
f = 3.58 MHz
f = 16 MHz
Spurious Free Dynamic Range
SFDR
f = 3.58 MHz
f = 16 MHz
Differential Phase
DP
Differential Gain
DG
32
REFBS
VREF
46.4
47.8
Condition
Bits
1
GND
VREF
Units
3
3
31.7
95
4
± 25
2
5.5
5.5
36.7
110
V
mV
V
mV
V
V
mA
mW
mW
1
% FS
49
48
dB
dB
7.8
7.7
Bits
Bits
49
48
dB
dB
–62
–58
–49.5
dB
dB
66
61
0.2
0.08
51.4
dB
dB
Degree
%
–2–
REFTS = 2.5 V, REFBS = 0.5 V
REFTS, REFBS: MODE = AVDD
Between REFTF & REFBF: MODE = AVSS
REFBS Min = GND: REFTS Max = AVDD
Switched
Input = ± FS
REFSENSE = VREF
REFSENSE = GND
1 mA Load Current
AVDD = 3 V, MODE = AVSS
AVDD = DRVDD = 3 V, MODE = AVSS
STBY = AVDD, MODE and CLOCK
= AVSS
NTSC 40 IRE Mod Ramp
REV. D
AD9280
Parameter
Symbol
Min
DIGITAL INPUTS
High Input Voltage
Low Input Voltage
VIH
VIL
2.4
DIGITAL OUTPUTS
High-Z Leakage
Data Valid Delay
Data Enable Delay
Data High-Z Delay
IOZ
tOD
tDEN
tDHZ
–10
LOGIC OUTPUT (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)
VOH
VOH
VOL
VOL
+2.95
+2.80
LOGIC OUTPUT (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)
VOH
VOH
VOL
VOL
+4.5
+2.4
tCH
tCL
14.7
14.7
CLOCKING
Clock Pulsewidth High
Clock Pulsewidth Low
Pipeline Latency
Typ
Max
Units
0.3
V
V
+10
25
25
13
EOC
± 60
Clamp Pulsewidth
tCPW
2
µA
ns
ns
ns
+0.4
+0.05
V
V
V
V
+0.4
+0.1
V
V
V
V
Output = GND to VDD
CL = 20 pF
ns
ns
Cycles
3
CLAMP
Clamp Error Voltage
Condition
± 80
mV
CLAMPIN = +0.5 V to +2.0 V,
RIN = 10 Ω
CIN = 1 µF (Period = 63.5 µs)
µs
NOTES
1
See Figures 1a and 1b.
Specifications subject to change without notice.
REFTS
10kV
AD9280
AD9280
REFTS
REFTF
4.2kV
10kV
REFBF
REFBS
0.4 3 VDD
AVDD
REFBS
MODE
MODE
a.
b.
Figure 1. Equivalent Input Load
REV. D
–3–
AD9280
ABSOLUTE MAXIMUM RATINGS*
Parameter
With
Respect
to
AVDD
AVSS
DRVDD
DRVSS
AVSS
DRVSS
AVDD
DRVDD
MODE
AVSS
CLK
AVSS
Digital Outputs
DRVSS
AIN
AVSS
VREF
AVSS
REFSENSE
AVSS
REFTF, REFTB
AVSS
REFTS, REFBS
AVSS
Junction Temperature
Storage Temperature
Lead Temperature
10 sec
Min
Max
Units
–0.3
–0.3
–0.3
–6.5
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
–0.3
+6.5
+6.5
+0.3
+6.5
AVDD + 0.3
AVDD + 0.3
DRVDD + 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
°C
°C
+300
°C
–65
*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 effect device reliability.
ORDERING GUIDE
Temperature
Range
Model
Package
Description
Package
Option*
AD9280ARS
–40°C to +85°C 28-Lead SSOP
RS-28
AD9280ARSRL –40°C to +85°C 28-Lead SSOP (Reel) RS-28
AD9280-EB
Evaluation Board
*RS = Shrink Small Outline.
AVDD
DRVDD
AVDD
AVDD
AVDD
AVDD
AVSS
AVSS
AVSS
AVSS
DRVSS
DRVSS
AVSS
a. D0–D7, OTR
b. Three-State, Standby, Clamp
c. CLK
AVDD
AVDD
REFBS
AVDD
REFTF
25
AVSS
AVSS
AVDD
AVDD
REFBF
REFTS
24
d. AIN
e. Reference
AVDD
AVDD
AVDD
AVSS
f. CLAMPIN
21
AVSS
AVSS
AVSS
22
AVDD
AVSS
AVSS
g. MODE
h. REFSENSE
AVSS
i. VREF
Figure 2. Equivalent Circuits
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 AD9280 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. D
AD9280
PIN CONFIGURATION
28-Lead Wide Body (SSOP)
AVSS 1
28 AVDD
DRVDD 2
27 AIN
NC 3
26 VREF
NC 4
25 REFBS
D0 5
AD9280
24 REFBF
TOP VIEW 23 MODE
D2 7 (Not to Scale) 22 REFTF
D1 6
D3 8
21 REFTS
D4 9
20 CLAMPIN
D5 10
19 CLAMP
D6 11
18 REFSENSE
17 STBY
D7 12
OTR 13
16 THREE-STATE
DRVSS 14
15 CLK
NC = NO CONNECT
PIN FUNCTION DESCRIPTIONS
REV. D
SSOP
Pin No.
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
AVSS
DRVDD
NC
NC
D0
D1
D2
D3
D4
D5
D6
D7
OTR
DRVSS
CLK
THREE-STATE
STBY
REFSENSE
CLAMP
CLAMPIN
REFTS
REFTF
MODE
REFBF
REFBS
VREF
AIN
AVDD
Analog Ground
Digital Driver Supply
No Connect
No Connect
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7, Most Significant Bit
Out-of-Range Indicator
Digital Ground
Clock Input
HI: High Impedance State. LO: Normal Operation
HI: Power-Down Mode. LO: Normal Operation
Reference Select
HI: Enable Clamp Mode. LO: No Clamp
Clamp Reference Input
Top Reference
Top Reference Decoupling
Mode Select
Bottom Reference Decoupling
Bottom Reference
Internal Reference Output
Analog Input
Analog Supply
–5–
AD9280
DEFINITIONS OF SPECIFICATIONS
Integral Nonlinearity (INL)
Offset Error
The first transition should occur at a level 1 LSB above “zero.”
Offset is defined as the deviation of the actual first code transition from that point.
Integral nonlinearity refers to the deviation of each individual
code from a line drawn from “zero” through “full scale.” The
point used as “zero” occurs 1/2 LSB before the first code transition. “Full scale” is defined as a level 1 1/2 LSB beyond the last
code transition. The deviation is measured from the center of
each particular code to the true straight line.
Gain Error
The first code transition should occur for an analog value 1 LSB
above nominal negative full scale. The last transition should
occur for an analog value 1 LSB below the nominal positive full
scale. Gain error is the deviation of the actual difference between first and last code transitions and the ideal difference
between the first and last code transitions.
Differential Nonlinearity (DNL, No Missing Codes)
An ideal ADC exhibits code transitions that are exactly 1 LSB
apart. DNL is the deviation from this ideal value. It is often
specified in terms of the resolution for which no missing codes
(NMC) are guaranteed.
Pipeline Delay (Latency)
The number of clock cycles between conversion initiation and
the associated output data being made available. New output
data is provided every rising edge.
(AVDD = +3 V, DRVDD = +3 V, FS = 32 MHz (50% Duty Cycle), MODE = AVDD, 2 V Input
Typical Characterization Curves Span from 0.5 V to 2.5 V, External Reference, unless otherwise noted)
60
1.0
55
0.5
50
–0.5 AMPLITUDE
–6.0 AMPLITUDE
SNR– dB
DNL
45
0
40
35
–0.5
30
–20.0 AMPLITUDE
25
–1.0
0
32
64
96
128
160
CODE OFFSET
192
224
20
1.00E+05
240
Figure 3. Typical DNL
1.00E+06
1.00E+07
INPUT FREQUENCY – Hz
1.00E+08
Figure 5. SNR vs. Input Frequency
60
1.0
55
0.5
50
–0.5 AMPLITUDE
SINAD – dB
INL
45
0
–0.5
–6.0 AMPLITUDE
40
35
30
–20.0 AMPLITUDE
25
–1.0
0
32
64
96
128
160
CODE OFFSET
192
224
20
1.00E+05
240
1.00E+06
1.00E+07
INPUT FREQUENCY – Hz
1.00E+08
Figure 6. SINAD vs. Input Frequency
Figure 4. Typical INL
–6–
REV. D
AD9280
105
–30
–35
POWER CONSUMPTION – mW
100
–40
THD – dB
–45
–20.0 AMPLITUDE
–50
–55
–6.0 AMPLITUDE
–60
95
90
85
80
–65
–0.5 AMPLITUDE
–70
1.00E+05
1.00E+06
1.00E+07
INPUT FREQUENCY – Hz
75
1.00E+08
0
10
5
15
20
25
30
CLOCK FREQUENCY – MHz
35
40
Figure 10. Power Consumption vs. Clock Frequency
(MODE = AVSS)
Figure 7. THD vs. Input Frequency
–80
1M
–70
900k
AIN = –0.5dBFS
1M
800k
–60
600k
HITS
THD – dB
700k
–50
–40
500k
400k
–30
300k
–20
200k
–10
100k
0
0
0
1.00E+06
1.00E+07
CLOCK FREQUENCY – Hz
Figure 8. THD vs. Clock Frequency
0
N–1
1.00E+08
N
CODE
N+1
Figure 11. Grounded Input Histogram
30
20
1.01
CLOCK = 32MHz
10
1.009
0
FIN = 1MHz
FS = 32MHz
FUND
–10
VREF – V
–20
1.008
–30
–40
–50
1.007
–60
–70
–80
–90
1.006
2nd3rd
5th
7th
6th
9th
8th
4th
–100
–110
1.005
–50
–30
–10
10
30
50
TEMPERATURE – °C
70
–120
0E+0
90
16E+6
Figure 12. Single-Tone Frequency Domain
Figure 9. Voltage Reference Error vs. Temperature
REV. D
4E+6
8E+6
12E+6
SINGLE-TONE FREQUENCY DOMAIN
–7–
AD9280
APPLYING THE AD9280
0
THEORY OF OPERATION
SIGNAL AMPLITUDE – dB
–3
The AD9280 implements a pipelined multistage architecture to
achieve high sample rate with low power. The AD9280 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 AD9280 requires a small fraction of the
256 comparators used in a traditional flash type A/D. A sampleand-hold function within each of the stages permits the first
stage to operate on a new input sample while the second, third
and fourth stages operate on the three preceding samples.
–6
–9
–12
–15
–18
–21
–24
1.0E+6
1.0E+7
1.0E+8
FREQUENCY – Hz
OPERATIONAL MODES
1.0E+9
The AD9280 is designed to allow optimal performance in a
wide variety of imaging, communications and instrumentation
applications, including pin compatibility with the AD876-8 A/D.
To realize this flexibility, internal switches on the AD9280 are
used to reconfigure the circuit into different modes. These modes
are selected by appropriate pin strapping. There are three parts
of the circuit affected by this modality: the voltage reference, the
reference buffer, and the analog input. The nature of the application will determine which mode is appropriate: the descriptions in the following sections, as well as Table I should assist in
selecting the desired mode.
Figure 13. Full Power Bandwidth
50
40
30
20
REFBS = 0.5V
REFTS = 2.5V
CLOCK = 32MHz
IB – mA
10
0
–10
–20
–30
–40
–50
0
0.5
1.5
1.0
2.0
INPUT VOLTAGE – V
2.5
3.0
Figure 14. Input Bias Current vs. Input Voltage
Table I. Mode Selection
Modes
Input
Connect
Input
Span
MODE
Pin
REFSENSE
Pin
TOP/BOTTOM
AIN
1V
AVDD
AIN
2V
AVDD
CENTER SPAN AIN
1V
AVDD/2 Short VREF and REFSENSE Together
AVDD/2
AVDD/2 20
AIN
2V
AVDD/2 AGND
AVDD/2
AVDD/2
AIN Is Input 1
1V
AVDD/2 Short VREF and REFSENSE Together
AVDD/2
AVDD/2 29
AVDD/2 AGND
No Connect
AVDD/2
AVDD/2
No Connect
Span = REFTS
– REFBS (2 V max)
Differential
REFTS and
REFBS Are
Shorted Together
for Input 2
2V
External Ref
AIN
2 V max AVDD
REF
REFBS
Figure
Short REFSENSE, REFTS and VREF Together
AGND
18
AGND
AGND
19
Short REFTS and VREF Together
No Connect
AVDD
AGND
AD876-8
AIN
2V
Float or
AVSS
REFTS
AVDD
No Connect
–8–
21, 22
Short to
VREFTF
Short to 23
VREFBF
Short to
VREFTF
Short to 30
VREFBF
REV. D
AD9280
SUMMARY OF MODES
VOLTAGE REFERENCE
AIN
1 V Mode the internal reference may be set to 1 V by connecting REFSENSE and VREF together.
REFTS
2 V Mode the internal reference my be set to 2 V by connecting
REFSENSE to analog ground
REFERENCE BUFFER
Center Span Mode midscale is set by shorting REFTS and
REFBS together and applying the midscale voltage to that point
The MODE pin is set to AVDD/2. The analog input will swing
about that midscale point.
Top/Bottom Mode sets the input range between two points.
The two points are between 1 V and 2 V apart. The Top/Bottom
Mode is enabled by tying the MODE pin to AVDD.
ANALOG INPUT
Differential Mode is attained by driving the AIN pin as one
differential input, shorting REFTS and REFBS together and
driving them as the second differential input. The MODE pin
is tied to AVDD/2. Preferred mode for optimal distortion
performance.
Single-Ended is attained by driving the AIN pin while the
REFTS and REFBS pins are held at dc points. The MODE pin is
tied to AVDD.
Single-Ended/Clamped (AC Coupled) the input may be
clamped to some dc level by ac coupling the input. This is done
by tying the CLAMPIN to some dc point and applying a pulse
to the CLAMP pin. MODE pin is tied to AVDD.
SPECIAL
AD876-8 Mode enables users of the AD876-8 to drop the
AD9280 into their socket. This mode is attained by floating or
grounding the MODE pin.
INPUT AND REFERENCE OVERVIEW
Figure 16, a simplified model of the AD9280, highlights the
relationship between the analog input, AIN, and the reference
voltages, REFTS, REFBS and VREF. Like the voltages applied
to the resistor ladder in a flash A/D converter, REFTS and
REFBS define the maximum and minimum input voltages to
the A/D.
REFBS
Figure 15. AD9280 Equivalent Functional Input Circuit
In single-ended operation, the input spans the range,
REFBS ≤ AIN ≤ REFTS
where REFBS can be connected to GND and REFTS connected to VREF. If the user requires a different reference range,
REFBS and REFTS can be driven to any voltage within the
power supply rails, so long as the difference between the two is
between 1 V and 2 V.
In differential operation, REFTS and REFBS are shorted together, and the input span is set by VREF,
(REFTS – VREF/2) ≤ AIN ≤ (REFTS + VREF/2)
where VREF is determined by the internal reference or brought
in externally by the user.
The best noise performance may be obtained by operating the
AD9280 with a 2 V input range. The best distortion performance may be obtained by operating the AD9280 with a 1 V
input range.
REFERENCE OPERATION
The AD9280 can be configured in a variety of reference topologies. The simplest configuration is to use the AD9280’s onboard
bandgap reference, which provides a pin-strappable option to
generate either a 1 V or 2 V output. If the user desires a reference voltage other than those two, an external resistor divider
can be connected between VREF, REFSENSE and analog
ground to generate a potential anywhere between 1 V and 2 V.
Another alternative is to use an external reference for designs
requiring enhanced accuracy and/or drift performance. A
third alternative is to bring in top and bottom references,
bypassing VREF altogether.
Figures 16d, 16e and 16f illustrate the reference and input architecture of the AD9280. In tailoring a desired arrangement,
the user can select an input configuration to match drive circuit.
Then, moving to the reference modes at the bottom of the
figure, select a reference circuit to accommodate the offset and
amplitude of a full-scale signal.
Table I outlines pin configurations to match user requirements.
The input stage is normally configured for single-ended operation, but allows for differential operation by shorting REFTS
and REFBS together to be used as the second input.
REV. D
A/D
CORE
AD9280
External Divider Mode the internal reference may be set to a
point between 1 V and 2 V by adding external resistors. See
Figure 16f.
External Reference Mode enables the user to apply an external reference to REFTS, REFBS and VREF pins. This mode
is attained by tying REFSENSE to VDD.
SHA
–9–
AD9280
V*
MIDSCALE
+FS
–FS
AD9280
AIN
MODE
AVDD/2
SHA
AD9280
AIN
MODE
(AVDD)
SHA
+F/S RANGE
OBTAINED FROM
VREF PIN OR
EXTERNAL REF
10kV
REFTF
10kV
0.1mF
REFTF
0.1mF
10kV
REFTS
A2
10kV
REFTS
REFBS
A2
REFBS
A/D
CORE
10kV
–F/S RANGE
OBTAINED FROM
VREF PIN OR
EXTERNAL REF
10kV
0.1mF
4.2kV
TOTAL
A/D
CORE
4.2kV
TOTAL
10mF
0.1mF
10mF
INTERNAL
REF
0.1mF
10kV
0.1mF
10kV
REFBF
MIDSCALE OFFSET
VOLTAGE IS DERIVED
FROM INTERNAL OR
EXTERNAL REF
REFBF
a. Top/Bottom Mode
* MAXIMUM MAGNITUDE OF V IS DETERMINED
BY INTERNAL REFERENCE
b. Center Span Mode
MAXIMUM MAGNITUDE OF V
IS DETERMINED BY INTERNAL
REFERENCE AND TURNS RATIO
V
AD9280
AIN
MODE
AVDD/2
SHA
AVDD/2
10kV
REFTF
0.1mF
10kV
REFTS
A2
A/D
CORE
REFBS
10kV
INTERNAL
REF
4.2kV
TOTAL
10mF
0.1mF
0.1mF
10kV
REFBF
c. Differential Mode
VREF
(2V)
VREF
(1V)
A1
1V
0.1mF
0.1mF
A1
1V
10kV
1.0mF
1.0mF
REFSENSE
REFSENSE
AD9280
AVSS
10kV
AD9280
AVSS
d. 1 V Reference
A1
e. 2 V Reference
VREF
(= 1 + RA/RB)
1V
RA
0.1mF
A1
1.0mF
REFSENSE
REFSENSE
AVDD
RB
AD9280
VREF
1V
AD9280
AVSS
INTERNAL 10K REF RESISTORS ARE
SWITCHED OPEN BY THE PRESENSE
OF RA AND RB.
g. Internal Reference Disable
(Power Reduction)
f. Variable Reference
(Between 1 V and 2 V)
Figure 16.
–10–
REV. D
AD9280
The actual reference voltages used by the internal circuitry of
the AD9280 appear on REFTF and REFBF. For proper operation, it is necessary to add a capacitor network to decouple these
pins. The REFTF and REFBF should be decoupled for all
internal and external configurations as shown in Figure 17.
Figure 19 shows the single-ended configuration for 2 V p-p
operation. REFSENSE is connected to GND, resulting in a 2 V
reference output.
2V
AIN
AD9280
SHA
0V
REFTF
10mF
10kV
AD9280
0.1mF
REFTS
REFBF
0.1mF
AVDD
REFTF
0.1mF
0.1mF
10mF
10kV
A2
REFBS
0.1mF
MODE
A/D
CORE
10kV
4.2kV
TOTAL
0.1mF
10kV
Figure 17. Reference Decoupling Network
REFBF
VREF
Note: REFTF = reference top, force
REFBF = reference bottom, force
REFTS = reference top, sense
REFBS = reference bottom, sense
1.0mF
AIN
AD9280
SHA
0V
10kV
REFTS
Maximum reference drive is 1 mA. An external buffer is required for heavier loads.
MODE
10kV
0.1mF
REFTS
+1.5V
A/D
CORE
10kV
4.2kV
TOTAL
0.1mF
A2
A/D
CORE
10kV
REFTF
0.1mF
4.2kV
TOTAL
0.1mF
10mF
0.1mF
10kV
REFBF
VREF
1.0mF
VREF
A1
0.1mF
REF
SENSE
A1
1V
1V
REF
SENSE
Figure 20. Internal Reference 1 V p-p Input Span
(Center Span Mode)
Figure 18. Internal Reference—1 V p-p Input Span
(Top/Bottom Mode)
REV. D
AVDD/2
10mF
REFBF
0.1mF
MODE
10kV
REFBS
0.1mF
10kV
1.0mF
AD9280
SHA
AVDD
10kV
REFBS
AIN
1V
REFTF
A2
1V
Figure 20 shows the single-ended configuration that gives the
good high frequency dynamic performance (SINAD, SFDR).
To optimize dynamic performance, center the common-mode
voltage of the analog input at approximately 1.5 V. Connect the
shorted REFTS and REFBS inputs to a low impedance 1.5 V
source. In this configuration, the MODE pin is driven to a voltage at midsupply (AVDD/2).
2V
1V
A1
REF
SENSE
Figure 19. Internal Reference, 2 V p-p Input Span
(Top/Bottom Mode)
INTERNAL REFERENCE OPERATION
Figures 18, 19 and 20 show sample connections of the AD9280
internal reference in its most common configurations. (Figures
18 and 19 illustrate top/bottom mode while Figure 20 illustrates
center span mode). Figure 29 shows how to connect the AD9280
for 1 V p-p differential operation. Shorting the VREF pin
directly to the REFSENSE pin places the internal reference
amplifier, A1, in unity-gain mode and the resultant reference
output is 1 V. In Figure 18 REFBS is grounded to give an input
range from 0 V to 1 V. These modes can be chosen when the
supply is either +3 V or +5 V. The VREF pin must be bypassed to
AVSS (analog ground) with a 1.0 µF tantalum capacitor in
parallel with a low inductance, low ESR, 0.1 µF ceramic capacitor.
0.1mF
–11–
AD9280
Figure 23a shows an example of the external references driving
the REFTF and REFBF pins that is compatible with the
AD876. REFTS is shorted to REFTF and driven by an external
4 V low impedance source. REFBS is shorted to REFBF and
driven by a 2 V source. The MODE pin is connected to GND
in this configuration.
EXTERNAL REFERENCE OPERATION
Using an external reference may provide more flexibility and
improve drift and accuracy. Figures 21 through 23 show examples of how to use an external reference with the AD9280.
To use an external reference, the user must disable the internal
reference amplifier by connecting the REFSENSE pin to VDD.
The user then has the option of driving the VREF pin, or driving the REFTS and REFBS pins.
4V
VIN
The AD9280 contains an internal reference buffer (A2), that
simplifies the drive requirements of an external reference. The
external reference must simply be able to drive a 10 kΩ load.
2V
REFTS
4V
REFTF
10mF
Figure 21 shows an example of the user driving the top and bottom
references. REFTS is connected to a low impedance 2 V source
and REFBS is connected to a low impedance 1 V source. REFTS
and REFBS may be driven to any voltage within the supply as long
as the difference between them is between 1 V and 2 V.
AD9280
0.1mF
REFBF
2V
0.1mF
0.1mF
REFBS
VREF
REFSENSE
AVDD
MODE
2V
AIN
AD9280
SHA
1V
REFBS
1V
REFTF
A2
0.1mF
0.1mF
10kV
REFTS
2V
Figure 23a. External Reference—2 V p-p Input Span
10kV
REFTS
REF
SENSE
4.2kV
TOTAL
A/D
CORE
10kV
6
REFT
0.1mF
10kV
AVDD
+5V
10mF
MODE
8
C4
0.1mF
7
REFTF
5
C3
0.1mF
C2
10mF
REFBF
C6
0.1mF
AD9280
REFBS
C5
0.1mF
2
Figure 21. External Reference Mode—1 V p-p Input Span
Figure 22 shows an example of an external reference generating
2.5 V at the shorted REFTS and REFBS inputs. In this instance, a REF43 2.5 V reference drives REFTS and REFBS. A
resistive divider generates a 1 V VREF signal that is buffered by
A3. A3 must be able to drive a 10 kΩ, capacitive load. Choose
this op amp based on noise and accuracy requirements.
AD9280
3.0V
2.5V
2.0V
AIN
AVDD
AVDD
REFTS
0.1mF
REFBS
10mF
A3
0.1mF
VREF
1.0mF
10mF
0.1mF
0.1mF
0.1mF
REFBF
1kV
AVDD/2
+5V
AVDD
3
4
REFBF
C1
0.1mF
Figure 23b. Kelvin Connected Reference Using the AD9280
STANDBY OPERATION
The ADC may be placed into a powered down (sleep) mode by
driving the STBY (standby) pin to logic high potential and
holding the clock at logic low. In this mode the typical power
drain is approximately 4 mW.
The ADC will “wake up” in 400 ns (typ) after the standby pulse
goes low.
REFTF
0.1mF
1.5kV
6
REFB
MODE
REFSENSE
REF43
0.1mF
Figure 22. External Reference Mode—1 V p-p Input
Span 2.5 VCM
CLAMP OPERATION
The AD9280ARS features an optional clamp circuit for dc
restoration of video or ac coupled signals. Figure 24 shows the
internal clamp circuitry and the external control signals needed
for clamp operation. To enable the clamp, apply a logic high to
the CLAMP pin. This will close the switch SW1. The clamp
amplifier will then servo the voltage at the AIN pin to be equal
to the clamp voltage applied at the CLAMPIN pin. After the
desired clamp level is attained, SW1 is opened by taking
CLAMP back to a logic low. Ignoring the droop caused by the
input bias current, the input capacitor CIN will hold the dc
voltage at AIN constant until the next clamp interval. The input
resistor RIN has a minimum recommended value of 10 Ω, to
maintain the closed-loop stability of the clamp amplifier.
–12–
REV. D
AD9280
The allowable voltage range that can be applied to CLAMPIN
depends on the operational limits of the internal clamp amplifier. The recommended clamp range is between 0.5 volts and
2.0 volts.
back porch to truncate the SYNC below the AD9280’s minimum input voltage. With a CIN = 1 µF, and RIN = 20 Ω, the
acquisition time needed to set the input dc level to one volt
with 1 mV accuracy is about 140 µs, assuming a full 1 volt VC.
The input capacitor should be sized to allow sufficient acquisition time of the clamp voltage at AIN within the CLAMP interval, but also be sized to minimize droop between clamping
intervals. Specifically, the acquisition time when the switch is
closed will equal:
With a 1 µF input coupling capacitor, the droop across one
horizontal can be calculated:
T ACQ = RIN CIN
V 
ln  C 
 VE 
where VC is the voltage change required across CIN, and VE is
the error voltage. VC is calculated by taking the difference between the initial input dc level at the start of the clamp interval
and the clamp voltage supplied at CLAMPIN. VE is a system
dependent parameter, and equals the maximum tolerable deviation from VC. For example, if a 2-volt input level needs to be
clamped to 1 volt at the AD9280’s input within 10 millivolts,
then VC equals 2 – 1 or 1 volt, and VE equals 10 mV. Note that
once the proper clamp level is attained at the input, only a very
small voltage change will be required to correct for droop.
IBIAS = 22 µA, and t = 63.5 µs, so dV = 1.397 mV, which is less
than one LSB.
After the input capacitor is initially charged, the clamp pulse
width only needs to be wide enough to correct small voltage
errors such as the droop. The fine scale settling characteristics
of the clamp circuitry are shown in Table II.
Depending on the required accuracy, a CLAMP pulse width of
1 µs–3 µs should work in most applications. The OFFSET values ignore the contribution of offset from the clamp amplifier;
they simply compare the output code with a “final value” measured with a much longer CLAMP pulse duration.
Table II.
The voltage droop is calculated with the following equation:
dV =
()
I BIAS
t
CIN
where t = time between clamping intervals.
The bias current of the AD9280 will depend on the sampling
rate, FS, and the difference between the reference midpoint,
(REFTS–REFBS)/2 and the input voltage. For a fixed sampling
rate of 32 MHz, Figure 14 shows the input bias current for a
given input. For a 1 V input range, the maximum input bias
current from Figure 14 is 22 µA. For lower sampling rates the
input bias current will scale proportionally.
CLAMP
OFFSET
8 µs
4 µs
3 µs
2 µs
1 µs
<1 LSB
<2 LSBs
2 LSBs
5 LSBs
9 LSBs
AD9280
CLAMP IN
CLAMP
CIN
If droop is a critical parameter, then the minimum value of CIN
should be calculated first based on the droop requirement.
Acquisition time—the width of the CLAMP pulse—can be
adjusted accordingly once the minimum capacitor value is chosen. A tradeoff will often need to be made between droop and
acquisition time, or error voltage VE.
RIN
SW1
AIN
TO
SHA
Figure 24a. Clamp Operation
AIN
Clamp Circuit Example
0.1mF
A single supply video amplifier outputs a level-shifted video
signal between 2 and 3 volts with the following parameters:
horizontal period = 63.56 µs,
horizontal sync interval = 10.9 µs,
horizontal sync pulse = 4.7 µs,
sync amplitude = 0.3 volts,
video amplitude of 0.7 volts,
reference black level = 2.3 volts
10mF
0.1mF
AD9280
0.1mF
REFBF
REFBS
AVDD
2
MODE
CLAMP
SHORT TO REFBS
OR EXTERNAL DC
The video signal must be dc restored from a 2- to 3-volt range
down to a 1- to 2-volt range. Configuring the AD9280 for a
one volt input span with an input range from 1 to 2 volts (see
Figure 24), the CLAMPIN voltage can be set to 1 volt with an
external voltage or by direct connection to REFBS. The CLAMP
pulse may be applied during the SYNC pulse, or during the
REV. D
REFTF
REFTS
CLAMPIN
Figure 24b. Video Clamp Circuit
–13–
AD9280
DRIVING THE ANALOG INPUT
Figure 25 shows the equivalent analog input of the AD9280, a
sample-and-hold amplifier (switched capacitor input SHA).
Bringing CLK to a logic low level closes Switches 1 and 2 and
opens Switch 3. The input source connected to AIN must
charge capacitor CH during this time. When CLK transitions
from logic “low” to logic “high,” Switches 1 and 2 open, placing
the SHA in hold mode. Switch 3 then closes, forcing the output
of the op amp to equal the voltage stored on CH. When CLK
transitions from logic “high” to logic “low,” Switch 3 opens
first. Switches 1 and 2 close, placing the SHA in track mode.
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 8-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, the input source must provide the charging current
through the RON (50 Ω) of Switch 1 and quickly (within 1/2 CLK
period) settle. This situation corresponds to driving a low input
impedance. On the other hand, when the source voltage equals
the value previously stored on CH, the hold capacitor requires
no input current and the equivalent input impedance is extremely high.
Adding series resistance between the output of the source and
the AIN pin reduces the drive requirements placed on the
source. Figure 26 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 20 Ω or less. For applications with signal bandwidths less than 16 MHz, the user may
proportionally increase the size of the series resistor. Alternatively, adding a shunt capacitance between the AIN pin and
analog ground can lower the ac load impedance. The value of
this capacitance will depend on the source resistance and the
required signal bandwidth.
The input span of the AD9280 is a function of the reference
voltages. For more information regarding the input range, see
the Internal and External Reference sections of the data sheet.
In many cases, particularly in single-supply operation, ac coupling offers a convenient way of biasing the analog input signal
at the proper signal range. Figure 27 shows a typical configuration for ac-coupling the analog input signal to the AD9280.
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. The f –3 dB point
can be approximated by the equation:
f –3 dB = 1/(2 × pi × [R2] CEQ)
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. Adding a small ceramic
or polystyrene capacitor (on the order of 0.01 µF) that does not
become inductive until negligibly higher frequencies, maintains
a low impedance over a wide frequency range.
NOTE: AC coupled input signals may also be shifted to a desired
level with the AD9280’s internal clamp. See Clamp Operation.
C1
R1
VIN
AIN
R2
IB
AD9280
C2
VBIAS
Figure 27. AC Coupled Input
There are additional considerations when choosing the resistor
values. The ac-coupling capacitors integrate the switching transients present at the input of the AD9280 and cause a net dc
bias current, IB, to flow into the input. The magnitude of the
bias current increases as the signal magnitude deviates from
V midscale and the clock frequency increases; i.e., minimum
bias current flow when AIN = V midscale. This bias current
will result in an offset error of (R1 + R2) × IB. If it is necessary
to compensate this error, consider making R2 negligibly small or
modifying VBIAS to account for the resultant offset.
In systems that must use dc coupling, use an op amp to levelshift a ground-referenced signal to comply with the input requirements of the AD9280. Figure 28 shows an AD8041 configured in noninverting mode.
CH
+VCC
AIN
0.1mF
S1
CP
SHA
S3
(REFTS
REFBS)
NC
0VDC
S2
CH
2
1
AD8041
CP
AD9280
Figure 25. AD9280 Equivalent Input Structure
20V
6
AIN
5
3
MIDSCALE
OFFSET
VOLTAGE
AD9280
7
1V p-p
4
NC
Figure 28. Bipolar Level Shift
< 20V
AIN
VS
AD9280
Figure 26. Simple AD9280 Drive Configuration
–14–
REV. D
AD9280
DIFFERENTIAL INPUT OPERATION
The AD9280 will accept differential input signals. This function
may be used by shorting REFTS and REFBS and driving them
as one leg of the differential signal (the top leg is driven into
AIN). In the configuration below, the AD9280 is accepting a
1 V p-p signal. See Figure 29.
AD9280
2V
AIN
1V
0.1mF
AVDD/2
REFTF
REFTS
0.1mF
The pipelined architecture of the AD9280 operates on both
rising and falling edges of the input clock. To minimize duty
cycle variations the recommended logic family to drive the clock
input is high speed or advanced CMOS (HC/HCT, AC/ACT)
logic. CMOS logic provides both symmetrical voltage threshold
levels and sufficient rise and fall times to support 32 MSPS
operation. The AD9280 is designed to support a conversion rate
of 32 MSPS; running the part at slightly faster clock rates may
be possible, although at reduced performance levels. Conversely,
some slight performance improvements might be realized by
clocking the AD9280 at slower clock rates.
10mF
REFBS
S1
0.1mF
VREF
1.0mF
REFBF
0.1mF
S4
tC
tCH
REFSENSE
tCL
S3
INPUT
CLOCK
MODE
AVDD/2
S2
ANALOG
INPUT
25ns
Figure 29. Differential Input
DATA
OUTPUT
AD876-8 MODE OF OPERATION
The AD9280 may be dropped into the AD876-8 socket. This
will allow AD876-8 users to take advantage of the reduced
power consumption realized when running the AD9280 on a
3.0 V analog supply.
Figure 30 shows the pin functions of the AD876-8 and AD9280.
The grounded REFSENSE pin and floating MODE pin effectively put the AD9280 in the external reference mode. The
external reference input for the AD876-8 will now be placed
on the reference pins of the AD9280.
The clamp controls will be grounded by the AD876-8 socket.
The AD9280 has a 3 clock cycle delay compared to a 3.5 cycle
delay of the AD876-8.
Figure 31. Timing Diagram
The power dissipated by the output buffers is largely proportional to the clock frequency; running at reduced clock rates
provides a reduction in power consumption.
DIGITAL INPUTS AND OUTPUTS
Each of the AD9280 digital control inputs, THREE-STATE
and STBY are reference to analog ground. The clock is also
referenced to analog ground.
The format of the digital output is straight binary (see Figure
32). A low power mode feature is provided such that for STBY
= HIGH and the clock disabled, the static power of the AD9280
will drop below 5 mW.
4V
AIN
2V
DATA 1
OTR
AD9280
REFTS
REFTF
4V
10mF
0.1mF
REFBF
2V
0.1mF
0.1mF
REFBS
NC
AVDD
MODE
REFSENSE
–FS+1LSB
CLAMP
–FS
+FS
+FS–1LSB
CLAMPIN
OTR
Figure 32. Output Data Format
VREF
0.1mF
THREESTATE
Figure 30. AD876 Mode
tDHZ
DATA
(D0–D9)
CLOCK INPUT
The AD9280 clock input is buffered internally with an inverter
powered from the AVDD pin. This feature allows the AD9280
to accommodate either +5 V or +3.3 V CMOS logic input signal swings with the input threshold for the CLK pin nominally
at AVDD/2.
REV. D
tDEN
HIGH
IMPEDANCE
Figure 33. Three-State Timing Diagram
–15–
AD9280
APPLICATIONS
DIRECT IF DOWN CONVERSION USING THE AD9280
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 narrowband
or wideband 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 similar manner that a mixer will downconvert 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 tradeoff exists between the complexity of this image rejection
filter and the sample rate as well as dynamic range of the ADC.
The AD9280 is well suited for various narrowband IF sampling
applications. The AD9280’s low distortion input SHA has a
full-power bandwidth extending to 300 MHz thus encompassing
many popular IF frequencies. The AD9280 will typically yield
an improvement in SNR when configured for the 2 V span, the
1 V span provides the optimum full-scale distortion performance. Furthermore, the 1 V span reduces the performance
requirements of the input driver circuitry and thus may be
more practical for system implementation purposes.
Figure 34 shows a simplified schematic of the AD9280 configured in an IF sampling application. To reduce the complexity of
the digital demodulator in many quadrature demodulation applications, the IF frequency and/or sample rate are selected such
G1 = 20dB
SAW
FILTER
OUTPUT
G2 = 12dB
50V
200V
To maximize its distortion performance, the AD9280 is configured in the differential mode with a 1 V span using a transformer.
The center tap of the transformer is biased at midsupply via a
resistor divider. Preceding the AD9280 is a bandpass filter as
well as a 32 dB gain stage. A large gain stage may be required
to compensate for the high insertion losses of a SAW filter used
for image rejection. The gain stage will also provide adequate
isolation for the SAW filter from the charge “kick back” currents
associated with AD9280’s input stage.
The gain stage can be realized using one or two cascaded
AD8009 op amps amplifiers. The AD8009 is a low cost, 1 GHz,
current-feedback op amp having a 3rd order intercept characterized up to 250 MHz. A passive bandpass filter following the
AD8009 attenuates its dominant 2nd order distortion products
which would otherwise be aliased back into the AD9280’s
baseband region. Also, it reduces any out-of-band noise which
would also be aliased back due to the AD9280’s noise bandwidth of 220+ MHz. Note, the bandpass filters specifications
are application dependent and will affect both the total distortion and noise performance of this circuit.
The distortion and noise performance of an ADC at the given
IF frequency is of particular concern when evaluating an ADC
for a narrowband IF sampling application. Both single-tone and
dual-tone SFDR vs. amplitude are very useful in assessing an
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.
L-C
50V
50V
that the bandlimited IF signal aliases back into the center of the
ADC’s baseband region (i.e., FS/4). For example, if an IF signal centered at 45 MHz is sampled at 20 MSPS, an image of
this IF signal will be aliased back to 5.0 MHz which corresponds to one quarter of the sample rate (i.e., FS/4). This
demodulation technique typically reduces the complexity of the
post digital demodulator ASIC which follows the ADC.
MINI CIRCUITS
T4 - 6T
1:4
BANDPASS
FILTER
AD9280
AIN
200V
280V
REFTS
REFBS
22.1V
93.1V
VREF
1.0mF
0.1mF
REFSENSE
1kV
AVDD
1kV
0.1mF
Figure 34. Simplified AD9280 IF Sampling Circuit
–16–
REV. D
AD9280
Figures 35–38 combine the dual-tone SFDR as well as single
tone SFDR and SNR performance at IF frequencies of 45 MHz,
70 MHz, 85 MHz and 135 MHz. Note, the SFDR vs. amplitude data is referenced to dBFS while the single tone SNR data
is referenced to dBc. The AD9280 was operated in the differential mode (via transformer) with a 1 V span. The analog supply (AVDD) and the digital supply (DRVDD) were set to +5 V
and 3.3 V, respectively.
80
70
DUAL TONE SFDR
70
SINGLE TONE SFDR
WORST CASE SPURIOUS – dBFS
SNR – dBc
WORST CASE SPURIOUS – dBFS
SNR – dBc
60
50
40
30
SNR
20
CLK = 25.7MHz
SINGLE TONE = 45.5MHz
DUAL TONE F1 = 44.5MHz
F2 = 45.5MHz
10
0
–0.5
–5
–10
–15
–20
–25
–30
INPUT POWER LEVEL – dBFS
–35
SINGLE TONE SFDR
60
DUAL TONE SFDR
50
40
30
SNR
CLK = 30.9MHz
SINGLE TONE = 85.5MHz
DUAL TONE F1 = 84.5MHz
F2 = 85.5MHz
20
10
0
–0.5
–40
Figure 35. SNR/SFDR for IF @ 45 MHz
–5
–10
–15
–20
–25
–30
INPUT POWER LEVEL – dBFS
70
SINGLE TONE SFDR
DUAL TONE SFDR
60
WORST CASE SPURIOUS – dBFS
SNR – dBc
60
WORST CASE SFDR – dBFS
SNR – dBc
–40
Figure 37. SNR/SFDR for IF @ 85 MHz
70
SINGLE TONE SFDR
50
40
30
SNR
20
CLK = 31.1MHz
SINGLE TONE = 70.5MHz
DUAL TONE F1 = 69.5MHz
F2 = 70.5MHz
10
0
–0.5
–5
–10
–15
–20
–25
–30
INPUT POWER LEVEL – dBFS
–35
DUAL TONE SFDR
50
40
30
SNR
20
10
0
–0.5
–40
Figure 36. SNR/SFDR for IF @ 70 MHz
REV. D
–35
FS = 32MHz
SINGLE TONE = 135.5MHz
F1 = 134.5MHz
F2 = 135.5MHz
–5
–10
–15
–20
–25
–30
INPUT POWER LEVEL – dBFS
–35
Figure 38. SNR/SFDR for IF @ 135 MHz
–17–
–40
AD9280
R11
15kV
R10
5kV
+3–5A
TP14
+3–5A
5
AD822
R7
5.49kV
2
XXXX
ADJ.
R8
10kV
D1
AD1580
4
3
C8
10/10V
R9
1.5kV
7
U2
R17
316V
R15
1kV
C7
0.1mF
8
CW
6
1
U2
AD822
0.626V TO 4.8V
Q1
2N3906
TP16
EXTT
C11
0.1mF
C13
10/10V
C12
0.1mF
R19
178V
+3–5A
CM
R13
11kV
R12
10kV
2
XXXX
ADJ.
4
1
U3
3
8
CW
C9
10/10V
TP11
R20
178V
C29
0.1mF
AD822
6
5
C10
0.1mF
TP17
AD822
EXTB
7
U3
C14
0.1mF
Q2
2N3904
R16
1kV
C15
10/10V
R18
316kV
+3–5A
J7
JP5
CLAMP
R37
1kV
R53
49.9V
DRVDD
B1
JP17
3
R38
1kV
B1
GND
JP18
3
S3 2
THREE-STATE
A
S4 2
STBY
A
R39
1kV
7
10
DRVDD
AVDD
C16
0.1mF
2
AVDD
DRVDD
AD9280
U1
15
16
17
18
19
20
21
22
23
24
25
26
27
OTR
NC
CLK
THREE-STATE NC
BIT0
STBY
BIT1
REFSENSE
BIT2
CLAMP
BIT3
CLAMPIN
BIT4
REFTS
BIT5
REFTF
BIT6
MODE
BIT7
REFBF
REFBS
VREF
AIN
AVSS
1
D5
D6
D7
D8
D9
DRVDD
C40
0.1mF
16
15
21
20
19
18
17
14
24
23
22
13
GND GND
B
U4 A
B
U4 A
B
U4 A
B
U4 A
B
U4 A
B
U4 A
B
U4 A
B
U4 A
VCCB VCCA
NC1
T/R
GD2
OE
GD1 U4 GD3
8
9
3
4
5
6
7
10
1
2
11
12
9
4
25 J8
J8
CLK
2
B 1
+3–5D
C20
0.1mF
GND
D0
D1
D2
D3
D4
DRVDD
C41
0.1mF
GND
GND
U5
B
A
U5
B
A
U5
B
A
U5
B
A
U5
B
A
U5
B
A
U5
B
A
U5
B
A
VCCB VCCA
NC1
T/R
GD2
OE
GD1 U5 GD3
2
+3–5D
16
11
J8
5
12
24 J8
26 J8
NC
28 J8
29 J8
23 J8
14
NC
19 J8
RN2
22V
1
C43
0.1mF
15
NC
17 J8
RN2
22V
1
GND
31 J8
32 J8
34 J8
21 J8
3
39 J8
30 J8
13
GND
2
J8
20 J8
22 J8
RN2
22V
2
J8
8
18 J8
1
33 J8
CLK_OUT
RN2
22V
+3–5D
J8
6
14 J8
CLK
WHITE
C21
0.1mF
J8
4
12 J8
J8
RN1
22V
4
J8
2
16 J8
1
6
3
10 J8
RN2
22V
JP20
GND
J8
RN1
22V
C42
0.1mF
74LVXC4245WM
3
7
5
A
GND
2
5
4
3
6
7
8
9
10
1
2
11
12
S2
15
3
JP21
1
74LVXC4245WM
19
20
21
18
17
16
15
14
24
23
22
13
13
RN1
22V
3
DRVSS
14
NOTE:
THE AD9280 IS EXERCISED IN
AN AD9200 EVALUATION BOARD
27 J8
11 J8
RN1
22V
13
D0
D1
D2
D3
D4
D5
D6
D7
D8
D9
11
12
5
OTR
TP19
WHITE
3
4
5
6
7
8
9
10
11
12
J8
RN1
22V
C18
10/10V
28
C33 +
10/10V
6
C19
0.1mF
C17
10/10V
DUTCLK
THREE-STATE
STBY
REFSENSE
CLAMP
CLAMPIN
REFTS
REFTF
MODE
REFBF
REFBS
VREF
AIN
13
RN1
22V
16
35 J8
36 J8
37 J8
38 J8
40 J8
15 J8
RN2
22V
Figure 39a. Evaluation Board Schematic
–18–
REV. D
AD9280
REFSENSE
JP1
AVDD
JP10
TP1
JP14
EXTB
TP3
C3
0.1mF
JP2
AVDD
R5
10kV
REFBF
C5
10/10V
JP9
JP3
+
JP15
R6
10kV
C6
0.1mF
B
1
TP5
S5
JP16
GND
EXTT
2
CLAMPIN
3
A
JP6
JP11
TP6
REFTS
TP7
AVDDCLK
R35
4.99kV
REFBS
EXTB
R34
2kV
CW
AIN
3
A
3
R1
49.9V
JP22
GND
JP13
T1–1T
S8
AVDD
C37
C38
C36
C35
10/10V 0.1mF 0.1mF 0.1mF
JP7
2
GND
EXTT
GND
JP12
J1
MODE
REFTF
JP4
VREF
TP4
C4
0.1mF
1
U6
2
5
U6
6
R36
4.99kV
4
2
1 B
TP8
TP12
1B
6
P
S
JP8
1
REFBS
T1
C1
0.1mF
TP9
A
3
S1
R3
100V
A
CLK
R4
49.9V
3
1
B
U6
R52
49.9V
4
L4
+3–5D
TP20
C32
0.1mF
C31
10/10V
U6 DECOUPLING
AVDDCLK
L1
J2
TP21
C23
10/10V
14
74AHC14 PWR
U6
GND
L2
J3
TP22
AVDD
C24
0.1mF
C25
33/16V
7
L3
+3–5A
J4
C26
0.1mF
C27
10/10V
TP23 TP24 TP25 TP26 TP27 TP28
GND J6
GND J10
Figure 39b. Evaluation Board Schematic
REV. D
9
U6
8
DRVDD
C22
0.1mF
–19–
11
C28
0.1mF
TP13
DUTCLK
TP29
J9
R51
49.9V
A
ADC_CLK
TP10
DCIN
S6 2
3
S7 2
3
J5
CM
2
C2
47/10V
R2
100V
JP26
1B
C30
0.1mF
13
U6
U6
10
12
AD9280
Figure 40a. Evaluation Board, Component Signal (Not to Scale)
Figure 40b. Evaluation Board, Solder Signal (Not to Scale)
–20–
REV. D
AD9280
Figure 40c. Evaluation Board Power Plane (Not to Scale)
Figure 40d. Evaluation Board Ground Plane (Not to Scale)
REV. D
–21–
AD9280
Figure 40e. Evaluation Board Component Silk (Not to Scale)
C33 C6
C18 C19
C4
C5
C3
C16
C17
Figure 40f. Evaluation Board Solder Silk (Not to Scale)
–22–
REV. D
AD9280
GROUNDING AND LAYOUT RULES
DIGITAL OUTPUTS
As is the case for any high performance device, proper grounding and layout techniques are essential in achieving optimal
performance. The analog and digital grounds on the AD9280
have been separated to optimize the management of return
currents in a system. Grounds should be connected near the
ADC. It is recommended that a printed circuit board (PCB) of
at least four layers, employing a ground plane and power planes,
be used with the AD9280. The use of ground and power planes
offers distinct advantages:
Each of the on-chip buffers for the AD9280 output bits
(D0–D7) is powered from the DRVDD supply pins, separate
from AVDD. The output drivers are sized to handle a variety
of logic families while minimizing the amount of glitch energy
generated. In all cases, a fan-out of one is recommended to
keep the capacitive load on the output data bits below the specified 20 pF level.
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.
3. The inherent distributed capacitor formed by the power plane,
PCB insulation and ground plane.
These characteristics result in both a reduction of electromagnetic interference (EMI) and an overall improvement in
performance.
It is important to design a layout that prevents noise from coupling onto the input signal. Digital signals should not be run in
parallel with the input signal traces and should be routed away
from the input circuitry. Separate analog and digital grounds
should be joined together directly under the AD9280 in a solid
ground plane. The power and ground return currents must be
carefully managed. A general rule of thumb for mixed signal
layouts dictates that the return currents from digital circuitry
should not pass through critical analog circuitry.
REV. D
For DRVDD = 5 V, the AD9280 output signal swing is compatible with both high speed CMOS and TTL logic families.
For TTL, the AD9280 on-chip, output drivers were designed to
support several of the high speed TTL families (F, AS, S). For
applications where the clock rate is below 32 MSPS, other TTL
families may be appropriate. For interfacing with lower voltage
CMOS logic, the AD9280 sustains 32 MSPS operation with
DRVDD = 3 V. In all cases, check your logic family data sheets
for compatibility with the AD9280 Digital Specification table.
THREE-STATE OUTPUTS
The digital outputs of the AD9280 can be placed in a high
impedance state by setting the THREE-STATE pin to HIGH.
This feature is provided to facilitate in-circuit testing or evaluation.
–23–
AD9280
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
C3118d–0–8/99
28-Lead Shrink Small Outline Package (SSOP)
(RS-28)
28
15
1
14
0.212 (5.38)
0.205 (5.21)
0.078 (1.98) PIN 1
0.068 (1.73)
0.008 (0.203) 0.0256
(0.65)
0.002 (0.050) BSC
0.07 (1.79)
0.066 (1.67)
8°
0.015 (0.38)
SEATING 0.009 (0.229) 0°
0.010 (0.25)
PLANE
0.005 (0.127)
0.03 (0.762)
0.022 (0.558)
PRINTED IN U.S.A.
0.311 (7.9)
0.301 (7.64)
0.407 (10.34)
0.397 (10.08)
–24–
REV. D