AD AD9271BSVZ-50

Octal LNA/VGA/AAF/ADC
and Crosspoint Switch
AD9271
Preliminary Technical Data
Each channel features a variable gain range of 30 dB, a fully
differential signal path, an active input preamplifier termination, a
maximum gain of up to 40 dB, and an ADC with a conversion
rate of up to 50 MSPS. The channel is optimized for dynamic
performance and low power in applications where a small
package size is critical.
DRVDD
AAF
12-BIT
PIPELINE
ADC
SERIAL
LVDS
DOUT + C
DOUT – C
AAF
12-BIT
PIPELINE
ADC
SERIAL
LVDS
DOUT + D
DOUT – D
AAF
12-BIT
PIPELINE
ADC
SERIAL
LVDS
DOUT + E
DOUT – E
AAF
12-BIT
PIPELINE
ADC
SERIAL
LVDS
DOUT + F
DOUT – F
AAF
12-BIT
PIPELINE
ADC
SERIAL
LVDS
DOUT + G
DOUT – G
AAF
12-BIT
PIPELINE
ADC
SERIAL
LVDS
DOUT + H
DOUT – H
LNA
VGA
VGA
LNA
VGA
LNA
gm
6
REFERENCE
CWVDD
SWITCH
ARRAY
FCO+
FCO–
DCO+
DCO–
06304-001
VGA
LNA
CWD+/–[5:0]
The AD9271 is designed for low cost, low power, small size, and
ease of use. It contains eight channels of a variable gain amplifier
(VGA) with low noise preamplifier (LNA); an antialiasing filter
(AAF); and a 12-bit, 10 MSPS to 50 MSPS analog-to-digital
converter (ADC).
DOUT + B
DOUT – B
VGA
LNA
LO-H
LOSW-H
LI-H
LG-H
SERIAL
LVDS
DATA
RATE
MULTIPLIER
LOSW-G
LO-G
LI-G
LG-G
AAF
12-BIT
PIPELINE
ADC
VGA
LNA
LOSW-F
LO-F
LI-F
LG-F
DOUT + A
DOUT – A
SDIO
LOSW-E
LO-E
LI-E
LG-E
SERIAL
LVDS
VGA
LOSW-D
LO-D
LI-D
LG-D
12-BIT
PIPELINE
ADC
CLK +
CLK –
LNA
LOSW-C
LO-C
LI-C
LG-C
AAF
VGA
LNA
SERIAL
PORT
INTERFACE
LOSW-B
LO-B
LI-B
LG-B
AD9271
CSB
SCLK
LO-A
LI-A
LG-A
Medical imaging/ultrasound
Automotive radar
GENERAL DESCRIPTION
PWDN
STDBY
AVDD
LOSW-A
SENSE
VREF
REFB
REFT
RBIAS
APPLICATIONS
FUNCTIONAL BLOCK DIAGRAM
GAIN–
8 channels of LNA, VGA, AAF, and ADC
Low noise preamplifier (LNA)
Input-referred noise = 1.2 nV/√Hz @ 7.5 MHz typical
SPI-programmable gain = 14 dB/15.6 dB/18 dB
Single-ended input; VIN maximum = 400 mV p-p/
333 mV p-p/250 mV p-p
Dual mode, active input impedance match
Bandwidth (BW) > 70 MHz
Full-scale (FS) output = 2 V p-p diff
Variable gain amplifier (VGA)
Gain range = −6 dB to +24 dB
Linear-in-dB gain control
Antialiasing filter (AAF)
3rd-order Butterworth cutoff
Programmable from 8 MHz to 18 MHz
Analog-to-digital converter (ADC)
12 bits at 10 MSPS to 50 MSPS
SNR = 70 dB
SFDR = 80 dB
Serial LVDS (ANSI-644, IEEE 1596.3 reduced range link)
Data and frame clock outputs
Includes crosspoint switch to support
continuous wave (CW) Doppler
Low power, 150 mW/channel at 12 bits/40 MSPS (TGC)
60 mW/channel in CW Doppler
Single 1.8 V supply (3.3 V supply for CW Doppler output bias)
Flexible power-down modes
Overload recovery in <10 ns
Fast recovery from low power standby mode, <2 μs
100-pin TQFP
The LNA has a single-ended-to-differential gain that is selectable
through the SPI. The LNA input noise is typically 1.2 nV/√Hz,
GAIN+
FEATURES
Figure 1.Block Diagram
and the combined input-referred noise of the entire channel
is 1.4 nV/√Hz at maximum gain. Assuming a 15 MHz noise
bandwidth (NBW) and a 15.6 dB LNA gain, the input SNR is
roughly 86 dB. In CW Doppler mode, the LNA output drives a
transconductance amp that is switched through an 8 × 6,
differential crosspoint switch. The switch is programmable
through the SPI.
Rev. PrA
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 that may result from its use. Specifications subject to change without notice. No
license is granted by implication or otherwise under any patent or patent rights of Analog Devices.
Trademarks and registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
www.analog.com
Fax: 781.461.3113
©2007 Analog Devices, Inc. All rights reserved.
AD9271
Preliminary Technical Data
TABLE OF CONTENTS
Features .............................................................................................. 1
Input Overdrive .......................................................................... 23
Applications....................................................................................... 1
CW Doppler Operation............................................................. 23
General Description ......................................................................... 1
TGC Operation........................................................................... 25
Functional Block Diagram .............................................................. 1
A/D Converter ............................................................................ 28
Revision History ............................................................................... 2
Clock Input Considerations...................................................... 28
Product Highlights ........................................................................... 3
Serial Port Interface (SPI).............................................................. 35
Specifications..................................................................................... 4
Hardware Interface..................................................................... 35
AC Specifications.......................................................................... 4
Memory Map .................................................................................. 37
Digital Specifications ................................................................... 8
Reading the Memory Map Table.............................................. 37
Switching Specifications .............................................................. 9
Reserved Locations .................................................................... 37
ADC Timing Diagrams ................................................................. 10
Default Values ............................................................................. 37
Absolute Maximum Ratings.......................................................... 11
Logic Levels................................................................................. 37
Thermal Impedance ................................................................... 11
Evaluation Board ............................................................................ 42
ESD Caution................................................................................ 11
Power Supplies ............................................................................ 42
Pin Configuration and Function Descriptions........................... 12
Input Signals................................................................................ 42
Equivalent Circuits ......................................................................... 15
Output Signals ............................................................................ 42
Typical Performance Characteristics ........................................... 17
Default Operation and Jumper Selection Settings................. 43
Theory of Operation ...................................................................... 20
Outline Dimensions ....................................................................... 56
Ultrasound................................................................................... 20
Ordering Guide .......................................................................... 56
Channel Overview...................................................................... 21
REVISION HISTORY
x/07—Revision 0: Initial Version
Rev. PrA | Page 2 of 58
Preliminary Technical Data
AD9271
The AD9271 requires a LVPECL-/CMOS-/LVDS-compatible
sample rate clock for full performance operation. No external
reference or driver components are required for many
applications.
Fabricated in an advanced CMOS process, the AD9271 is
available in a 14 mm × 14 mm, Pb-free, 100-lead TQFP. It is
specified over the industrial temperature range of –40°C to +85°C.
The ADC automatically multiplies the sample rate clock for
the appropriate LVDS serial data rate. A data clock (DCO) for
capturing data on the output and a frame clock (FCO) trigger
for signaling a new output byte are provided.
1.
Small Footprint. Eight channels are contained in a small,
space-saving package. Full TGC path, ADC, and crosspoint
switch contained within a 100-lead, 16 mm × 16 mm, TQFP.
2.
Low power of 150 mW/channel at 40 MSPS.
Powering down individual channel is supported to increase battery
life for portable applications. There is also a standby mode option
that allows quick power-up for power cycling. In CW Doppler
operation, the VGA, AAF, and ADC are powered down. The
power of the TGC path scales with selectable speed grades.
3.
Integrated Crosspoint Switch. This switch allows numerous
multichannel configuration options to enable the CW
Doppler mode.
4.
Ease of Use. A data clock output (DCO) operates up to
300 MHz and supports double data rate operation (DDR).
The ADC contains several features designed to maximize flexibility
and minimize system cost, such as a programmable clock, data
alignment, and programmable digital test pattern generation. The
digital test patterns include built-in fixed patterns, built-in
pseudorandom pattern, and custom user-defined test patterns
entered via the serial port interface.
5.
User Flexibility. Serial port interface (SPI) control offers a wide
range of flexible features to meet specific system requirements.
6.
Integrated Third-Order Antialiasing Filter. This filter is
placed between TGC path and ADC and is programmable
from 8 MHz to 18 MHz.
PRODUCT HIGHLIGHTS
Rev. PrA | Page 3 of 58
AD9271
Preliminary Technical Data
SPECIFICATIONS
AC SPECIFICATIONS
AVDD = 1.8 V, DRVDD = 1.8 V, CWVDD = 3.3 V, 1.0 V internal ADC reference, AIN = 5 MHz, RS = 50 Ω, LNA gain = 15.6 dB (6),
unless otherwise noted.
Table 1.
Parameter1
LNA
CHARACTERISTICS
Gain = 5/6/8
Input Voltage
Range, Gain =
5/6/8
Input Common
Mode
Input Resistance
Input Capacitance
−3 dB Bandwidth
Input Noise
Voltage,
Gain = 5/6/8
1 dB Input
Compression
Point
Gain = 5/6/8
Active
Termination
Match
Unterminated
FULL-CHANNEL (TGC)
CHARACTERISTICS
AAF High-Pass
Cutoff
AAF Low-Pass
Cutoff
Group Delay
Variation
Bandwidth
Tolerance
Input-Referred
Noise Voltage,
LNA Gain =
5/6/8
Correlated Noise
Output Offset
Signal-to-Noise
Ratio (SNR)
FIN = 5 MHz at −7
dBFS
Conditions
Min
AD9271-25
Typ
Max
Min
AD9271-40
Typ
Max
Min
AD9271-50
Typ
Max
Unit
14/15.6/18
14/15.6/18
14/15.6/18
dB
8/9.6/12
8/9.6/12
8/9.6/12
dB
400/333/250
400/333/250
400/333/250
mV p-p
SE2
1.4
1.4
1.4
V
50
100
15
15
40
1.4/1.4/1.3
50
100
15
15
60
1.3/1.2/1.1
50
100
15
15
70
1.3/1.2/1.1
Ω
Ω
kΩ
pF
MHz
nV/√Hz
VGAIN = 0 V
782.6/649.1/508.8
782.6/649.1/508.8
782.6/649.1/508.8
mV p-p
Ω, RFB = 200 Ω
6.7
6.7
6.7
dB
RFB = ∞
4.9
4.4
4.2
dB
−3 dB
DC/350/700
DC/350/700
DC/350/700
kHz
−3 dB,
programmable
f = 1 MHz to
10 MHz, gain =
0 V to 1 V
1/3 × fSAMPLE
(8 to 18)
±1
1/3 × fSAMPLE
(8 to 18)
±1
1/3 × fSAMPLE
(8 to 18)
±1
MHz
±15
±15
±15
%
RFB = ∞
1.7/1.6/1.5
1.6/1.4/1.3
1.6/1.4/1.2
nV/√Hz
No signal
AAF high-pass
= 700 kHz
−30
TBD
−30
TBD
−30
TBD
dB
LSB
GAIN pin = 0 V
65
65
65
dBFS
Single-ended
input to
differential
output
Single-ended
input to
single-ended
output
LNA output
limited to
2 V p-p
differential
output
RFB = 200 Ω,
RFB = 400 Ω,
RFB = ∞
LI-x
RS = 0 Ω, RFB =
∞
Rev. PrA | Page 4 of 58
ns
Preliminary Technical Data
Parameter1
FIN = 5 MHz at −1
dBFS
Harmonic
Distortion
Second Harmonic,
FIN = 5 MHz at
−7 dBFS
Second Harmonic,
FIN = 5 MHz at
−1 dBFS
Third Harmonic,
FIN = 5 MHz at
−7 dBFS
Third Harmonic,
FIN = 5 MHz at
−1 dBFS
Two-Tone IMD3
(2 × F1 − F2)
Distortion
FIN1 = 5.0 MHz at
−1 dBFS
FIN2 = 5.1 MHz at
−26 dBFS
Channel-toChannel
Crosstalk
Channel-toChannel
Crosstalk
(Overrange
Condition)3
Overload Recovery
GAIN ACCURACY
Absolute Gain
Error
Channel-toChannel
Matching
GAIN CONTROL
INTERFACE
Normal Operating
Range
Gain Range
Scale Factor
Response Time
CW DOPPLER MODE
Transconductance,
LNA Gain =
5/6/8
Common Mode
Input-Referred
Noise Voltage,
LNA Gain =
5/6/8
Output DC Bias
Maximum Output
Swing
POWER SUPPLY
AVDD
Conditions
GAIN pin = 1 V
Min
AD9271
AD9271-25
Typ
65
Max
Min
AD9271-40
Typ
65
Max
Min
AD9271-50
Typ
65
Max
Unit
dBFS
GAIN pin = 0 V
−65
−65
−65
dBFS
GAIN pin = 1 V
−65
−65
−65
dBFS
GAIN pin = 0 V
−70
−70
−70
dBFS
GAIN pin = 1 V
−70
−70
−70
dBFS
GAIN pin = 1 V
−65
−65
−65
dB
−70
−70
−70
dB
−70
−70
−70
dB
10
10
10
ns
LNA or VGA
0 < VGAIN < 0.1
V
0.1 V < VGAIN <
0.9 V, 1σ
0.9 V < VGAIN <
1V
0.1 V < VGAIN <
0.9 V
−1.0
+0.5
+2.0
−1.0
+0.5
+2.0
−1.0
+0.5
+2.0
dB
−1.0
+0.3
+1.0
−1.0
+0.3
+1.0
−1.0
+0.3
+1.0
dB
−2.0
-0.5
+1.0
−2.0
-0.5
+1.0
−2.0
-0.5
+1.0
dB
1
dB
1
V
40.6
1
0
0 V to 1 V
10.6
30 dB change
CW Doppler
output pins
RS = 0 Ω, RFB =
∞
1.7
1
0
40.6
10.6
1
0
40.6
10.6
32
350
32
350
32
350
dB
dB/V
ns
10/12/16
10/12/16
10/12/16
mA/V
1.5
Per channel
Per channel
1
3.6
1.5
3.6
1.5
3.6
V
1.8 /1.7/1.5
1.7 /1.5/1.4
1.7 /1.5/1.3
nV/√Hz
2.4
±2
2.4
±2
2.4
±2
mA
mA pp
1.8
1.9
1.7
1.8
Rev. PrA | Page 5 of 58
1.9
1.7
1.8
1.9
V
AD9271
Parameter1
DRVDD
CWVDD
IAVDD
IDRVDD
Total Power
Dissipation
(Including
Output Drivers)
Preliminary Technical Data
Conditions
Full-channel
mode
CW Doppler
mode with
four channels
enabled
Full-channel
mode
CW Doppler
mode with
four channels
enabled
Power-Down
Dissipation
Standby Power
Dissipation
Power Supply
Rejection Ratio
(PSRR)
ADC RESOLUTION
Min
1.7
3.0
AD9271-25
Typ
1.8
3.3
500
Max
1.9
3.6
Min
1.7
3.0
AD9271-40
Typ
1.8
3.3
622
Max
1.9
3.6
Min
1.7
3.0
AD9271-50
Typ
1.8
3.3
746
Max
1.9
3.6
Unit
V
mA
136
160
170
mA
49
984
49
1200
49
1400
mA
mW
192
216
224
mW
10
mW
65
65
65
mW
1
1
1
mV/V
12
12
12
Bits
Rev. PrA | Page 6 of 58
Preliminary Technical Data
Parameter1
ADC REFERENCE
Output Voltage
Error (VREF = 1
V)
Load Regulation @
1.0 mA (VREF =
1 V)
Input Resistance
Conditions
Min
AD9271
AD9271-25
Typ
Max
Min
AD9271-40
Typ
Max
Min
AD9271-50
Typ
Max
Unit
±2
±2
±2
mV
3
3
3
mV
6
6
6
kΩ
1
See the AN-835 Application Note, Understanding High Speed ADC Testing and Evaluation, for a complete set of definitions and how these tests were completed.
SE = single ended.
3
The overrange condition is specified as being 6 dB more than the full-scale input range.
2
Rev. PrA | Page 7 of 58
AD9271
Preliminary Technical Data
DIGITAL SPECIFICATIONS
AVDD = 1.8 V, DRVDD = 1.8 V, CWVDD = 3.3 V, 400 m V p-p differential input, 1.0 V internal ADC reference, AIN = −0.5 dBFS, unless
otherwise noted.
Table 2.
Parameter1
CLOCK INPUTS (CLK+, CLK−)
Logic Compliance
Differential Input Voltage2
Input Common-Mode Voltage
Input Resistance (Differential)
Input Capacitance
LOGIC INPUTS (PDWN, STBY, SCLK)
Logic 1 Voltage
Logic 0 Voltage
Input Resistance
Input Capacitance
LOGIC INPUT (CSB)
Logic 1 Voltage
Logic 0 Voltage
Input Resistance
Input Capacitance
LOGIC INPUT (SDIO)
Logic 1 Voltage
Logic 0 Voltage
Input Resistance
Input Capacitance
LOGIC OUTPUT (SDIO)3
Logic 1 Voltage (IOH = 800 μA)
Logic 0 Voltage (IOL = 50 μA)
DIGITAL OUTPUTS (D+, D−), (ANSI-644)1
Logic Compliance
Differential Output Voltage (VOD)
Output Offset Voltage (VOS)
Output Coding (Default)
DIGITAL OUTPUTS (D+, D−),
(Low Power, Reduced Signal Option)1
Logic Compliance
Differential Output Voltage (VOD)
Output Offset Voltage (VOS)
Output Coding (Default)
Temperature
Min
Full
Full
25°C
25°C
250
Full
Full
25°C
25°C
1.2
Full
Full
25°C
25°C
1.2
Full
Full
25°C
25°C
1.2
0
Typ
Max
Unit
CMOS/LVDS/LVPECL
mV p-p
V
kΩ
pF
1.2
20
1.5
3.6
0.3
V
V
kΩ
pF
3.6
0.3
V
V
kΩ
pF
DRVDD + 0.3
0.3
V
V
kΩ
pF
30
0.5
70
0.5
30
2
Full
Full
1.79
0.05
V
V
454
1.375
mV
V
250
1.30
mV
V
LVDS
Full
Full
247
1.125
Offset binary
LVDS
Full
Full
150
1.10
Offset binary
1
See the AN-835 Application Note, Understanding High Speed ADC Testing and Evaluation, for a complete set of definitions and how these tests were completed.
Specified for LVDS and LVPECL only.
3
Specified for 13 SDIO pins sharing the same connection.
2
Rev. PrA | Page 8 of 58
Preliminary Technical Data
AD9271
SWITCHING SPECIFICATIONS
AVDD = 1.8 V, DRVDD = 1.8 V, CWVDD = 3.3 V, 400 m V p-p differential input, 1.0 V internal ADC reference, AIN = −0.5 dBFS, unless
otherwise noted.
Table 3.
Parameter1
CLOCK2
Maximum Clock Rate
Minimum Clock Rate
Clock Pulse Width High (tEH)
Clock Pulse Width Low (tEL)
OUTPUT PARAMETERS2, 3
Propagation Delay (tPD)
Rise Time (tR) (20% to 80%)
Fall Time (tF) (20% to 80%)
FCO Propagation Delay (tFCO)
DCO Propagation Delay (tCPD)4
DCO to Data Delay (tDATA)4
DCO to FCO Delay (tFRAME)4
Data-to-Data Skew
(tDATA-MAX − tDATA-MIN)
Wake-Up Time (Standby)
Wake-Up Time (Power-Down)
Pipeline Latency
APERTURE
Aperture Uncertainty (Jitter)
Temp
Min
Typ
Max
Full
Full
Full
Full
50
Full
Full
Full
Full
Full
1.5
1.5
2.3
3.1
Full
Full
Full
(tSAMPLE/24) − 300
(tSAMPLE/24) − 300
tFCO +
(tSAMPLE/24)
(tSAMPLE/24)
(tSAMPLE/24)
(tSAMPLE/24) + 300
(tSAMPLE/24) + 300
±50
±200
10
10.0
10.0
2.3
3.1
300
300
25°C
25°C
Full
600
25°C
<1
375
8
1
Unit
MSPS
MSPS
ns
ns
ns
ps
ps
ns
ns
ps
ps
ps
ns
μs
CLK
cycles
ps rms
See the AN-835 Application Note, Understanding High Speed ADC Testing and Evaluation, for a complete set of definitions and how these tests were completed.
Can be adjusted via the SPI interface.
3
Measurements were made using a part soldered to FR4 material.
4
tSAMPLE/24 is based on the number of bits divided by 2, because the delays are based on half duty cycles.
2
Rev. PrA | Page 9 of 58
AD9271
Preliminary Technical Data
ADC TIMING DIAGRAMS
N–1
AIN
tA
N
tEH
CLK–
tEL
CLK+
tCPD
DCO–
DCO+
tFRAME
tFCO
FCO–
FCO+
tPD
MSB
N–8
D10
N–8
D9
N–8
D8
N–8
D7
N–8
D6
N–8
D5
N–8
D4
N–8
D3
N–8
D2
N–8
D1
N–8
D0
N–8
MSB
N–7
D10
N–7
D8
(N – 8)
D9
(N – 8)
D10
(N – 8)
LSB
(N – 7)
D0
(N – 7)
DOUT+
06304-002
tDATA
DOUT–
Figure 2. 12-(Preliminary) Bit Data Serial Stream (Default)
N–1
AIN
tA
N
tEH
tEL
CLK–
CLK+
tCPD
DCO–
DCO+
tFRAME
tFCO
FCO–
FCO+
tPD
tDATA
DOUT–
D0
(N – 8)
D1
(N – 8)
D2
(N – 8)
D3
D4
(N – 8) (N – 8)
D5
(N – 8)
D6
(N – 8)
D7
(N – 8)
06304-004
LSB
(N – 8)
DOUT+
Figure 3. 12-(Preliminary) Bit Data Serial Stream, LSB First
Rev. PrA | Page 10 of 58
Preliminary Technical Data
AD9271
ABSOLUTE MAXIMUM RATINGS
Table 4.
Parameter
ELECTRICAL
AVDD
DRVDD
CWVDD
GND
AVDD
Digital Outputs
(DOUT+, DOUT−, DCO+,
DCO−, FCO+, FCO−)
CLK+, CLK−
LI-x
LO-x
LOSW-x
CWDx−, CWDx+
SDIO, GAIN+,GAIN−
PDWN, STBY, SCLK, CSB
REFT, REFB, RBIAS
VREF, SENSE
ENVIRONMENTAL
Operating Temperature
Range (Ambient)
Maximum Junction
Temperature
Lead Temperature
(Soldering, 10 sec)
Storage Temperature
Range (Ambient)
With
Respect To
Rating
GND
GND
GND
GND
DRVDD
GND
−0.3 V to +2.0 V
−0.3 V to +2.0 V
−0.3 V to +3.9 V
−0.3 V to +0.3 V
−2.0 V to +2.0 V
−0.3 V to +2.0 V
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
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
THERMAL IMPEDANCE
Table 5.
GND
LG-x
LG-x
LG-x
GND
GND
GND
GND
GND
−0.3 V to +3.9 V
−0.3 V to +2.0 V
−0.3 V to +2.0 V
−0.3 V to +2.0 V
−0.3 V to +2.0 V
−0.3 V to +2.0 V
−0.3 V to +3.9 V
−0.3 V to +2.0 V
−0.3 V to +2.0 V
Air Flow Velocity (m/s)
0.0
1.0
2.5
1
θJA1
20.3°C/W
14.4°C/W
12.9°C/W
θJB
θJC
7.6°C/W
4.7°C/W
θJA for a 4-layer PCB with solid ground plane (simulated). Exposed pad
soldered to PCB.
ESD CAUTION
−40°C to +85°C
150°C
300°C
−65°C to +150°C
Rev. PrA | Page 11 of 58
AD9271
Preliminary Technical Data
76 LOSW-D
77 LO–D
78 CWD0–
79 CWD0+
80 CWD1–
81 CWD1+
82 CWD2–
83 CWD2+
84 CWVD-D
85 GAIN–
86 GAIN+
87 RBIAS
88 SENSE
89 VREF
90 REFB
91 REFT
92 AVDD
93 CWD3–
94 CWD3+
95 CWD4–
96 CWD4+
97 CWD5–
98 CWD5+
99 LO–E
100 LOSW-E
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
PIN 1
INDICATOR
LI-E 1
75 LI-D
LG-E 2
74 LG-D
AVDD 3
73 AVDD
72 AVDD
AVDD 4
EXPOSED PADDLE, PIN 0
(BOTTOM OF PACKAGE)
LO-F 5
LOSW-F 6
71 LO-C
70 LOSW-C
LI-F 7
69 LI-C
AD9271
LG-F 8
68 LG-C
TOP VIEW
(Not to Scale)
AVDD 9
67 AVDD
AVDD 10
66 AVDD
LO-G 11
65 LO-B
LOSW-G 12
64 LOSW-B
63 LI-B
LI-G 13
LG-G 14
62 LG-B
AVDD 15
61 AVDD
AVDD 16
60 AVDD
LO-H 17
59 LO-A
58 LOSW-A
LOSW-H 18
LI-H 19
AVDD 50
PWDN 49
STBY 48
DRVDD 47
DOUT + A 46
DOUT – A 45
DOUT + B 44
DOUT – B 43
DOUT + C 42
DOUT – C 41
DOUT + D 40
DOUT – D 39
FCO+ 38
FCO– 37
DCO+ 36
DCO– 35
DOUT + E 34
DOUT – E 33
DOUT + F 32
DOUT – F 31
51 SCLK
DOUT + G 30
52 SDIO
AVDD 25
DOUT – G 29
53 CSB
CLK+ 24
DOUT + H 28
54 AVDD
CLK– 23
DRVDD 26
55 AVDD
AVDD 22
DOUT – H 27
56 LG-A
AVDD 21
Figure 4. 100-Lead TQFP
Table 6. Pin Function Descriptions
Pin No.
0
3, 4, 9, 10, 15,
16, 21, 22, 25,
50, 54, 55, 60,
61, 66, 67, 72,
73,92
26, 47
84
1
2
5
6
7
8
11
12
13
14
Name
GND
AVDD
Description
Ground (Exposed paddle should be tied to a quiet analog ground)
1.8 V Analog Supply
DRVDD
CWVDD
LI-E
LG-E
LO-F
LOSW-F
LI-F
LG-F
LO-G
LOSW-G
LI-G
LG-G
1.8 V Digital Output Driver Supply
3.3 V Analog Supply
LNA Analog Input for Channel E
LNA Ground for Channel E
LNA Analog Output for Channel F
LNA Analog Output Complement for Channel F
LNA Analog Input for Channel F
LNA Ground for Channel F
LNA Analog Output for Channel G
LNA Analog Output Complement for Channel G
LNA Analog Input for Channel G
LNA Ground for Channel G
Rev. PrA | Page 12 of 58
06304-005
57 LI-A
LG-H 20
Preliminary Technical Data
Pin No.
17
18
19
20
23
24
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
48
49
51
52
53
56
57
58
59
62
63
64
65
68
69
70
71
74
75
76
77
78
79
80
81
82
83
Name
LO-H
LOSW-H
LI-H
LG-H
CLK−
CLK+
DOUT − H
DOUT + H
DOUT − G
DOUT + G
DOUT − F
DOUT + F
DOUT − E
DOUT + E
DCO−
DCO+
FCO−
FCO+
DOUT − D
DOUT + D
DOUT − C
DOUT + C
DOUT − B
DOUT + B
DOUT − A
DOUT + A
STDBY
PDWN
SCLK
SDIO
CSB
LG-A
LI-A
LOSW-A
LO-A
LG-B
LI-B
LOSW-B
LO-B
LG-C
LI-C
LOSW-C
LO-C
LG-D
LI-D
LOSW-D
LO-D
CWD0−
CWD0+
CWD1−
CWD1+
CWD2−
CWD2+
AD9271
Description
LNA Analog Output for Channel H
LNA Analog Output Complement for Channel H
LNA Analog Input for Channel H
LNA Ground for Channel H
Clock Input Complement
Clock Input True
ADC H Digital Output Complement
ADC H True Digital Output True
ADC C Digital Output Complement
ADC C True Digital Output
ADC B Digital Output Complement
ADC B True Digital Output True
ADC A Digital Output Complement
ADC A True Digital Output True
Frame Clock Digital Output Complement
Frame Clock Digital Output True
Frame Clock Digital Output Complement
Frame Clock Digital Output True
ADC H Digital Output Complement
ADC H True Digital Output True
ADC C Digital Output Complement
ADC C True Digital Output
ADC B Digital Output Complement
ADC B True Digital Output True
ADC A Digital Output Complement
ADC A True Digital Output True
Standby Power Down
Full Power Down
Serial Clock
Serial Data Input/Output
Chip Select Bar
LNA Ground for Channel A
LNA Analog Input for Channel A
LNA Analog Output Complement for Channel A
LNA Analog Output for Channel A
LNA Ground for Channel B
LNA Analog Input for Channel B
LNA Analog Output Complement for Channel B
LNA Analog Output for Channel B
LNA Ground for Channel C
LNA Analog Input for Channel C
LNA Analog Output Complement for Channel C
LNA Analog Output for Channel C
LNA Ground for Channel D
LNA Analog Input for Channel D
LNA Analog Output Complement for Channel D
LNA Analog Output for Channel D
CW Doppler Output Complement for Channel 0
CW Doppler Output True for Channel 0
CW Doppler Output Complement for Channel 1
CW Doppler Output True for Channel 1
CW Doppler Output Complement for Channel 2
CW Doppler Output True for Channel 2
Rev. PrA | Page 13 of 58
AD9271
Pin No.
85
86
87
88
89
90
91
93
93
95
96
97
98
99
100
Preliminary Technical Data
Name
GAIN−
GAIN+
RBIAS
SENSE
VREF
REFB
REFT
CWD3−
CWD3+
CWD4−
CWD4+
CWD5−
CWD5+
LO-E
LOSW-E
Description
GAIN Control Voltage Input Complement
GAIN Control Voltage Input True
External resistor sets the internal ADC core bias current
Reference Mode Selection
Voltage Reference Input/Output
Differential Reference (Negative)
Differential Reference (Positive)
CW Doppler Output Complement for Channel 3
CW Doppler Output True for Channel 3
CW Doppler Output Complement for Channel 4
CW Doppler Output True for Channel 4
CW Doppler Output Complement for Channel 5
CW Doppler Output True for Channel 5
LNA Analog Output for Channel E
LNA Analog Output Complement for Channel E
Rev. PrA | Page 14 of 58
Preliminary Technical Data
AD9271
EQUIVALENT CIRCUITS
AVDD
VCM
15kΩ
LI-x,
LG-x
350Ω
SDIO
06304-073
30kΩ
Figure 5. Equivalent LNA Input Circuit
06304-008
AVDD
Figure 8. Equivalent SDIO Input Circuit
DRVDD
AVDD
V
DOUT+
06304-075
V
V
06304-009
10Ω
LO-x,
LOSW-x
V
DOUT–
DRGND
Figure 9. Equivalent Digital Output Circuit
Figure 6. Equivalent LNA Output Circuit
10Ω
CLK+
10kΩ
1.25V
10kΩ
SCLK OR PDWN
OR STBY
10Ω
30kΩ
06304-010
06304-007
CLK–
1kΩ
Figure 7. Equivalent Clock Input Circuit
Figure 10. Equivalent SCLK Input Circuit
Rev. PrA | Page 15 of 58
AD9271
Preliminary Technical Data
AVDD
100Ω
RBIAS
AVDD
6kΩ
06304-014
06304-011
VREF
Figure 14. Equivalent VREF Circuit
Figure 11. Equivalent RBIAS Circuit
AVDD
70kΩ
CSB
1kΩ
50Ω
06304-012
06304-074
GAIN
Figure 15. Equivalent GAIN Input Circuit
Figure 12. Equivalent CSB Input Circuit
SENSE
1kΩ
10Ω
06304-013
06304-076
CWDx+,
CWDx–
Figure 13. Equivalent SENSE Circuit
Figure 16. Equivalent CWD Output Circuit
Rev. PrA | Page 16 of 58
Preliminary Technical Data
AD9271
TYPICAL PERFORMANCE CHARACTERISTICS
(fSAMPLE = 50 MSPS, AIN = 5 MHz, LPF = 1/3 × fSAMPLE, LNA gain = 6×)
2000000
2.00
1800000
1.50
1600000
1.00
1400000
1200000
Number of Hits
85C
0.00
25C
1000000
800000
-40C
-0.50
600000
-1.00
400000
200000
-1.50
0
-5
-2.00
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
-4
-3
-2
-1
0
1
2
3
4
5
Codes
1
Vgain (V)
Figure 17. Absolute Gain Error vs. VGAIN at Three Temperatures
Figure 20. Output-Referred Noise Histogram with Gain Pin at 0.0V, AD927150
1200000
1000000
800000
Number of Hits
0
600000
400000
200000
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Codes
Figure 18. Gain Error Histogram
Figure 21. Output-Referred Noise Histogram with Gain Pin at 1.0V, AD927150
4.5
4
3.5
Input-referred Noise (nV/sqrt-Hz)
Absolute Error (dB)
0.50
3
2.5
2
LNA Gain = 5x
1.5
LNA Gain = 6x
LNA Gain = 8x
1
0.5
Figure 19. Gain Match Histogram for VGAIN = 0.2 V and 0.7 V
0
0
5
10
15
20
Frequency (MHz)
Figure 22. Short-Circuit, Input-Referred Noise vs. Frequency
Rev. PrA | Page 17 of 58
25
AD9271
Preliminary Technical Data
0
-99
-100
-5
LNA Gain = 5x
-3dB line
LNA Gain = 6x
-101
-10
-102
(1/3)*50MHz
-15
Fundamental (dBFS)
Output-referred Noise (dBFS/rt-Hz)
LNA Gain = 8x
-103
-104
(1/3)*40MHz
-20
-25
-105
(1/3)*25MHz
-30
-106
-35
-107
-108
-40
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0
2.5
5
7.5
10
12.5
Vgain (V)
15
17.5
20
22.5
25
Frequency (MHz)
Figure 23. Short-Circuit, Output-Referred Noise vs. VGAIN
Figure 26. Antialiasing Filter (AAF) Pass-Band Response
66
400
350
64
300
62
SNR (dBFS)
250
Group Delay (n s)
SINAD (dB)
SNR/SINAD
SINAD (dBFS)
60
58
200
150
56
100
Vgain = 0.0 V
Vgain = 0.5 V
54
50
52
0
Vgain = 1.0 V
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
0.1
1
1
10
100
Analog Input Frequency (MHz)
Vgain (V)
Figure 27. Antialiasing Filter (AAF) Group Delay Response
Figure 24. SNR/SINAD vs. Gain
-50
1.7
-55
1.65
Vgain=0.2V
-65
H2 (dBFS)
Input-referred noise (nV/rt-Hz)
-60
1.6
1.55
Vgain=1V
-70
1.5
-75
Vgain=0.5V
-80
1.45
-85
2
1.4
-40
-20
0
20
40
60
80
4
6
8
10
12
14
Fin (MHz)
Temperature (C)
Figure 28. Second-Order Harmonic Distortion vs. Frequency
Figure 25. Short-Circuit, Input-Referred Noise vs. Temperature
Rev. PrA | Page 18 of 58
16
Preliminary Technical Data
AD9271
-40
-55
-50
-60
-60
Third Harmonic (dBFS)
-50
H3 (dBFS)
-65
Vgain=0.5V
Vgain=1V
-70
Vgain=0V
Vgain=0.5V
Vgain=1V
-70
-80
-90
-75
-100
Vgain=0.2V
-80
-110
-40
-85
2
4
6
8
10
12
14
16
-35
-30
-25
-20
-15
-10
-5
ADC Output Level (dBFS)
Fin (MHz)
Figure 29. Third-Order Harmonic Distortion vs. Frequency
Figure 31. Third-Order Harmonic Distortion vs. ADC Output Level
-40
-50
Second Harmonic (dBFS)
-60
Vgain=0V
Vgain=0.5V
Vgain=1V
-70
-80
-90
-100
-110
-40
-35
-30
-25
-20
-15
-10
-5
0
ADC Output Level (dBFS)
Figure 30. Second-Order Harmonic Distortion vs. ADC Output Level
Rev. PrA | Page 19 of 58
0
AD9271
Preliminary Technical Data
THEORY OF OPERATION
ULTRASOUND
Most modern machines use digital beam forming. In this
technique, the signal is converted to digital format immediately
following the TGC amplifier; beam forming is done digitally.
The primary application for the AD9271 is medical ultrasound.
Figure 32 shows a simplified block diagram of an ultrasound
system. A critical function of an ultrasound system is the time
gain control (TGC) compensation for physiological signal
attenuation. Because the attenuation of ultrasound signals is
exponential with respect to distance (time), a linear-in-dB VGA
is the optimal solution.
The ADC resolution of 12 bits with up to 50 MSPS sampling
satisfies the requirements of both general-purpose and highend systems.
Power consumption and low cost are of primary importance in
low-end and portable ultrasound machines, and the AD9271 is
designed for these criteria.
Key requirements in an ultrasound signal chain are very low
noise, active input termination, fast overload recovery, low
power, and differential drive to an ADC. Because ultrasound
machines use beam-forming techniques requiring large binaryweighted numbers (for example, 32 to 512) of channels, the
lowest power at the lowest possible noise is of key importance.
For additional information regarding ultrasound systems, refer
to “How Ultrasound System Considerations Influence Front-End
Component Choice,” Analog Dialogue, Volume 36, Number 3,
May–July 2002.
TX HV AMPs
BEAMFORMER
CENTRAL CONTROL
TX BEAMFORMER
MULTICHANNEL
TGC USES MANY VGAs
AD9271
HV
MUX/
DEMUX
LNA
T/R
SWITCHES
ADC
VGA
AAF
Rx BEAMFORMER
(B AND F MODES)
CW
TRANSDUCER
ARRAY
128, 256 ETC.
ELEMENTS
TGC
TIME GAIN COMPENSATION
CW (ANALOG)
BEAMFORMER
SPECTRAL
DOPPLER
PROCESSING
MODE
AUDIO
OUTPUT
Figure 32. Simplified Ultrasound System Block Diagram
Rev. PrA | Page 20 of 58
IMAGE AND
MOTION
PROCESSING
(B MODE)
COLOR
DOPPLER (PW)
PROCESSING
(F MODE)
DISPLAY
06304-077
BIDIRECTIONAL
CABLE
Preliminary Technical Data
LO-X
TO
SWITCH
ARRAY
gm
CFB RFB2
CS
LOSW-X
CDW+
CDW–
LI-X
AAF
LG-X
SERIAL PORT
INTERFACE
CSB
GAIN–
GAIN+
GAIN
INTERPOLATOR
SERIAL
LVDS
DOUT + X
DOUT – X
AD9271
SDIO
CLG
12-BIT
PIPELINE
ADC
+24dB
SCLK
RS
ATTENUATOR
–30dB TO 0dB
LNA
CSH
06304-071
RFB1
AD9271
Figure 33. Simplified Block Diagram of Single Channel
CHANNEL OVERVIEW
Each channel contains both a TGC and CW Doppler signal
path. Common to both signal paths, the LNA provides useradjustable input impedance termination. The CW Doppler path
includes a transconductance amplifier and crosspoint switch.
The TGC path includes a differential X-AMP® VGA, an
antialiasing filter, and an ADC. Figure 33 shows a simplified
block diagram with external components.
The signal path is fully differential throughout to maximize
signal swing and reduce even-order distortion; however, the
LNA is designed to be driven from a single-ended signal source.
Low Noise Amplifier (LNA)
Good noise performance relies on a proprietary ultralow noise
LNA at the beginning of the signal chain, which minimizes the
noise contribution in the following VGA. Active impedance
control optimizes noise performance for applications that benefit
from input impedance matching.
A simplified schematic of the LNA is shown in Figure 34. LI-x is
capacitively coupled to the source. An on-chip bias generator
establishes dc input bias voltages of around 1.4 V and centers
the output common-mode levels at 0.9 V (VDD/2). A capacitor,
CLG, of the same value as the input coupling capacitor, CS, is
connected from the LG-x pin to ground.
CFB
RFB1
RFB2
LOSW
LO-X
CS
LI-X
CSH
Low value feedback resistors and the current-driving capability
of the output stage allow the LNA to achieve a low input-referred
noise voltage of 1.2 nV/√Hz. This is achieved with a current
consumption of only 16 mA per channel (30 mW). On-chip
resistor matching results in precise single-ended gains critical
for accurate impedance control. The use of a fully differential
topology and negative feedback minimizes distortion. Low HD2
is particularly important in second harmonic ultrasound imaging
applications. Differential signaling enables smaller swings at
each output, further reducing third-order distortion.
Active Impedance Matching
The LNA consists of a single-ended voltage gain amplifier with
differential outputs and the negative output externally available.
For example, with a fixed gain of 6 (15.6 dB), an active input
termination is synthesized by connecting a feedback resistor
between the negative output pin, LO-x, and the positive input
pin, LI-x. This technique is well known and results in the input
resistance shown in Equation 2, where A/2 is the single-ended
gain or the gain from the LI-x inputs to the LO-x outputs.
LG-X
R IN =
CLG
06304-101
RS
The LNA supports differential output voltages as high as 2 V p-p
with positive and negative excursions of ±0.5 V from a
common-mode voltage of 0.9 V. The LNA differential gain sets
the maximum input signal before saturation. One of three gains
is set through the SPI. The corresponding input full-scale for
the gain settings of 5, 6, or 8 is 400 mV p-p, 333 mV p-p, and
250 mV p-p, respectively. Overload protection ensures quick
recovery time from large input voltages. Because the inputs are
capacitively coupled to a bias voltage near midsupply, very large
inputs can be handled without interacting with the ESD protection.
Figure 34. Simplified LNA Schematic
Rev. PrA | Page 21 of 58
R FB
(1 + A 2)
(2)
AD9271
Preliminary Technical Data
Because the amplifier has a gain of 6× from its input to its
differential output, it is important to note that the gain A/2 is
the gain from Pin LI-x to Pin LO-x, and is 6 dB less than the
gain of the amplifier, or 9.6 dB (3×). The input resistance is
reduced by an internal bias resistor of 15 kΩ in parallel with the
source resistance connected to Pin LI-x, with Pin LG-x ac
grounded. Equation 3 can be used to calculate the needed RFB
for a desired RIN, even for higher values of RIN.
RIN =
RFB
|| 15 k Ω
(1+ 3)
(3)
For example, to set RIN to 200 Ω, the value of RFB is 845 Ω. If the
simplified equation, Equation 2, is used to calculate RIN, the
resulting value is 190 Ω, resulting in a less than 0.1 dB gain
error. Factors such as a dynamic source resistance might
influence the absolute gain accuracy more significantly. At
higher frequencies, the input capacitance of the LNA needs to
be considered. The user must determine the level of matching
accuracy and adjust RFB accordingly.
The bandwidth (BW) of the LNA is about 70 MHz. Ultimately
the BW of the LNA limits the accuracy of the synthesized RIN.
For RIN = RS up to about 200 Ω, the best match is between
100 kHz and 10 MHz, where the lower frequency limit is
determined by the size of the ac-coupling capacitors, and the
upper limit, by the LNA BW. Furthermore, the input
capacitance and RS limit the BW at higher frequencies.
1k
RSH =
RIN = 500Ω, RFB = 2.5kΩ
∞, CSH = 0 pF
CFB is needed in series with RFB because the dc levels at Pin LO-x
and Pin LI-x are unequal.
Table 7. Active Termination External Component Values
LNA Gain
5×
6×
8×
5×
6×
8×
5×
6×
8×
RIN (Ω)
50
50
50
100
100
100
200
200
200
RFB (Ω)
175
200
250
350
400
500
700
800
1000
Minimum
CSH (pF)
90
70
50
30
20
10
na
na
na
LNA Noise
The short-circuit noise voltage (input-referred noise) is an
important limit on system performance. The short-circuit noise
voltage for the LNA is 1.2 nV/√Hz or 1.4 nV/√Hz (at maximum
gain), including the VGA noise. These measurements, which
are taken without a feedback resistor, provide the basis for
calculating the input noise and noise figure performance of the
configurations shown in Figure 43. Figure 43 and Figure 44 are
simulations of noise figure vs. RS results using these
configurations and an input-referred noise voltage for the VGA
of 4 nV/√Hz. Unterminated (RFB = ∞) operation exhibits the
lowest equivalent input noise and noise figure. Figure 44 shows
the noise figure vs. source resistance rising at low RS—where the
LNA voltage noise is large compared with the source noise—
and at high RS due to current noise.
RS
RSH = 50Ω, CSH = 22 pF
VIN
100
RIN = 100Ω, RFB = 499Ω
RIN = 50Ω, RFB = 249Ω
RSH =
+
RESISTIVE TERMINATION
∞, CSH = 0 pF
1M
FREQUENCY (Hz)
10M
VOUT
–
RSH = 50Ω, CSH = 22 pF
RS
VIN
10
100k
RIN
RIN
+
RS
VOUT
–
50M
ACTIVE IMPEDANCE MATCH
RFB
R
Figure 35. RIN vs. Frequency for Various Values of RFB
(Effects of RSH and CSH are Also Shown
IN
RS
Figure 35 shows RIN vs. frequency for various values of RFB. Note
that at the lowest value, 50 Ω, RIN peaks at frequencies greater
than 10 MHz. This is due to the BW roll-off of the LNA as
mentioned earlier.
VIN
+
VOUT
–
RIN =
RFB
1 + A/2
Figure 36. Input Configurations
However, as can be seen for larger RIN values, parasitic capacitance
starts rolling off the signal BW before the LNA can produce
peaking. CSH further degrades the match; therefore, CSH should
not be used for values of RIN that are greater than 100 Ω. Table 7
lists the recommended values for RFB and CSH in terms of RIN.
Rev. PrA | Page 22 of 58
03199-079
INPUT IMPEDANCE (Ω)
UNTERMINATED
RIN = 200Ω, RFB = 1kΩ
BW (MHz)
49
59
73
49
59
73
49
49
49
Preliminary Technical Data
AD9271
7
INCLUDES NOISE OF VGA
INPUT OVERDRIVE
RESISTIVE TERMINATION
(RS = RIN)
5
Excellent overload behavior is of primary importance in ultrasound. Both the LNA and VGA have built-in overdrive
protection and quickly recover after an overload event.
4
Input Overload Protection
3
ACTIVE IMPEDANCE MATCH
2
SIMULATION
0
50
100
03199-076
1
UNTERMINATED
1k
RS (Ω)
Figure 37. Noise Figure vs. RS for Resistive,
Active Matched and Unterminated Inputs, Gain = 1 V
7
INCLUDES NOISE OF VGA
NOISE FIGURE (dB)
6
5
RIN = 50Ω
4
3
2
RIN = 75Ω
RIN = 100Ω
RIN = 200Ω
RFB = ∞
03199-077
1
SIMULATION
0
50
100
1k
RS (Ω)
Figure 38. Noise Figure vs. RS for Various Fixed Values of RIN,
Actively Matched, Gain = 1 V.
The primary purpose of input impedance matching is to
improve the system transient response. With resistive termination,
the input noise increases due to the thermal noise of the
matching resistor and the increased contribution of the LNA’s
input voltage noise generator. With active impedance matching,
however, the contributions of both are smaller than they would
be for resistive termination by a factor of 1/(1 + LNA Gain).
Figure 37 shows the relative noise figure (NF) performance. In
this graph, the input impedance was swept with RS to preserve
the match at each point. The noise figures for a source impedance
of 50 Ω are 7.1 dB, 4.1 dB, and 2.5 dB for the resistive, active,
and unterminated configurations, respectively. The noise
figures for 200 Ω are 4.6 dB, 2.0 dB, and 1.0 dB, respectively.
Figure 38 shows the NF vs. RS for various values of RIN, which is
helpful for design purposes. The plateau in the NF for actively
matched inputs mitigates source impedance variations. For
comparison purposes, a preamp with a gain of 15.6 dB and
noise spectral density of 1.2 nV/√Hz, combined with a VGA
with 4 nV/√Hz, yields a noise figure degradation of
approximately 1.5 dB (for most input impedances), which is
significantly worse than the AD9271 performance.
As with any amplifier, voltage clamping prior to the inputs is
highly recommended if the application is subject to high
transient voltages.
A block diagram of a simplified ultrasound transducer interface
is shown in Figure 39. A common transducer element serves the
dual functions of transmitting and receiving ultrasound energy.
During the transmitting phase, high voltage pulses are applied
to the ceramic elements. A typical transmit/receive (T/R) switch
may consist of four high voltage diodes in a bridge configuration.
Although the diodes ideally block transmit pulses from the
sensitive receiver input, diode characteristics are not ideal, and
resulting leakage transients imposed on the LI-x inputs can be
problematic.
Because ultrasound is a pulse system and time-of-flight is used
to determine depth, quick recovery from input overloads is
essential. Overload can occur in the preamp and the VGA.
Immediately following a transmit pulse, the typical VGA gains
are low, and the LNA is subject to overload from T/R switch
leakage. With increasing gain, the VGA can become overloaded
due to strong echoes that occur near field echoes and
acoustically dense materials, such as bone.
Figure 39 illustrates an external overload protection scheme. A
pair of back-to-back Schottky diodes is installed prior to
installing the ac-coupling capacitors. Although the BAS40
diodes are shown, any diode is prone to exhibiting some amount
of shot noise. Many types of diodes are available for achieving the
desired noise performance. The configuration shown in Figure
39 tends to add 2 nV√Hz of input-referred noise. Decreasing the
5 kΩ resistor and increasing the 2 kΩ resistor may improve noise
contribution, depending on the application. With the diodes
shown in Figure 39, clamping levels of ±0.5 V or less
significantly enhances the system overload performance.
+5V
Tx
DRIVER
5kΩ
AD9271
HV
BAS40-04
10nF
LNA
5kΩ
2kΩ
10nF
TRANSDUCER
–5V
Figure 39. Input Overload Protection
CW DOPPLER OPERATION
Modern ultrasound machines used for medical applications
employ a 2n binary array of receivers for beam forming, with
Rev. PrA | Page 23 of 58
06304-100
NOISE FIGURE (dB)
6
AD9271
Preliminary Technical Data
The AD9271 includes the front-end components needed to
implement analog beam forming for CW Doppler operation.
These components allow CW channels with similar phases to be
coherently combined before phase alignment and down mixing,
thus reducing the number of delay lines or adjustable phase
shifters/down mixers (AD8333 or AD8339) required. Next, if
delay lines are used, the phase alignment is performed and then
the channels are coherently summed and down converted by a
dynamic range I/Q demodulator. Alternatively, if phase shifters/
down mixers, such as the AD8333 and AD8339, are used, phase
alignment and down conversion are done before coherently
summing all channels into I/Q signals. In either case, the resultant I
and Q signals are filtered and sampled by two high resolution
ADCs, and the sampled signals are processed to extract the
relevant Doppler information.
typical array sizes of 16 or 32 receiver channels phase-shifted
and summed together to extract coherent information. When
used in multiples, the desired signals from each of the channels
can be summed to yield a larger signal (increased by a factor N,
where N is the number of channels), and the noise is increased by
the square root of the number of channels. This technique
enhances the signal-to-noise performance of the machine. The
critical elements in a beam-former design are the means to
align the incoming signals in the time domain and the means to
sum the individual signals into a composite whole.
Beam forming, as applied to medical ultrasound, is defined as the
phase alignment and summation of signals that are generated
from a common source but received at different times by a
multielement ultrasound transducer. Beam forming has two
functions: It imparts directivity to the transducer, enhancing its
gain, and it defines a focal point within the body from which the
location of the returning echo is derived.
AD9271
LNA
gm
LNA
gm
SWITCH
ARRAY
8 × CHANNEL
gm
LNA
AD8333
2.5V
600nH
700Ω
600nH
gm
2.5V
600nH
600nH
8 × AD9271
3 × AD8333
AD8333
AD9271
LNA
gm
LNA
gm
2.5V
LNA
gm
LNA
gm
600nH
700Ω
600nH
600nH
2.5V
SWITCH
ARRAY
8 × CHANNEL
700Ω
600nH
700Ω
I
OPA
16-BIT
ADC
OPA
16-BIT
ADC
Q
Figure 40. Typical CW Doppler System Using the AD9271 and AD8339
Rev. PrA | Page 24 of 58
06304-096
LNA
Preliminary Technical Data
AD9271
Table 9. ADC Specifications
Crosspoint Switch
Each LNA is followed by a transconductance amp for V/I conversion. Currents can be routed to one of six pairs of differential
outputs or to 12 single-ended outputs for summing. Each CWD
output pin sinks 2.4 mA dc current, and the signal has a full-scale
of ±2 mA for each channel selected by the cross-point switch.
For example, if four channels were to be summed on one CWD
output, the output would sink 9.6 mA dc and have a full-scale
current output of ±8 mA. The maximum number of channels
combined must be considered in setting the load impedance for
I/V conversion to ensure that the full-scale swing and commonmode voltage are within the operating limits of the AD9271.
When interfacing to the AD8339, a common-mode voltage of
2.5 V and a full-scale swing of 2.8 V p-p are desired This can be
accomplished by connecting an inductor between each CWD
output and a 2.5 V supply, and then connecting either a singleended or differential load resistance to the CWD outputs. The
value of resistance should be calculated based on the maximum
number of channels that can be combined.
ADC Parameters
FS/FSrms (Vpp/mV)
SNR (dB)
ENOB (Bits)
SFDR (dB)
Noise (rms uV/nV/rt(Hz))
Specifications
2/707
70
11.3
−82
194/50
In summary, the maximum gain required is determined by
(ADC Noise Floor/VGA Input Noise Floor) + Margin =
20 log(194/4.7) + 10 dB = 42.3 dB
The minimum gain required is determined by
(ADC Input FS/VGA Input FS) + Margin =
20 log(2/0.333) – 6 dB = 9.6 dB
Therefore, a 12-bit, 40 MSPS ADC with 15 MHz of bandwidth
should suffice in achieving the dynamic range required for most
ultrasound systems today.
CWD outputs are required under full-scale swing to be within
1.5 V and CWVDD (3.3 V supply).
The system gain is distributed as listed in Table 7.
TGC OPERATION
Table 10. Channel Gain Distribution
The signal path is fully differential throughout to maximize
signal swing and reduce even-order distortion; however, the
LNAs are designed to be driven from a single-ended signal
source. Gain values are referenced from the single-ended LNA
input to the differential output of the LNA. A simple exercise in
understanding the maximum and minimum gain requirements
is shown in Figure 41.
Section
LNA
Attenuator
VGA Amp
Filter
ADC
Total
Table 8. LNA Specifications
The linear-in-dB gain range of the TGC path is 30 dB, extending
from 9.6 dB to 39.6 dB. The slope of the gain control interface is
30 dB/V, and the gain control range is 0 V to 1 V. Equation 1 is
the expression for gain.
LNA Parameters
BW (MHz)
FS/FSrms (mVpp/mV)
SNR (dB)
ENOB (Bits)
Noise (rms uV/nV/rt(Hz))
Specifications
15
333/118
88.1
14.3
4.65/1.2
Gain (dB ) = 30
Nominal Gain (dB)
14/15.6/18
0 to −30
25
0
0
9 to 39/10.6 to 40.6/13 to 43
dB
VGAIN + ICPT
V
(1)
where ICPT is the intercept point of the LNA gain.
MINIMUM GAIN
LNA FS
(0.333V p-p SE)
70dB
88dB
ADC NOISE FLOOR
(194µV rms)
MAXIMUM GAIN
VGA NOISE FLOOR
(4.7µV rms)
Figure 41. Gain Requirements of TGC for a 12-Bit, 40 MSPS ADC
06304-097
ADC EQUIVALENT
DYNAMIC RANGE
ADC FS (2V p-p)
In its default condition, the LNA has a gain of 15.6 dB (6×) and
the VGA gain is −6 dB if the voltage on the VGAIN pin is 0 V.
This gives rise to a total gain (or ICPT) of 9.6 dB through the
TGC path if the LNA input is unmatched, or of 3.6 dB if the
LNA is matched to 50 Ω (RFB = 200 Ω). If the voltage on the
VGAIN pin is 1 V, however, the VGA gain is 24 dB. This gives rise
to a total gain of 39.6 dB through the TGC path if the LNA
input is unmatched, or of 33.5 dB if the LNA input is matched.
Each of the LNA outputs is dc-coupled to a VGA input. The
VGA consists of an attenuator with a range of 30 dB followed by
an amplifier with 24 dB of gain for a net gain range of −5 dB to
+25 dB. The X-AMP gain-interpolation technique results in low
Rev. PrA | Page 25 of 58
AD9271
Preliminary Technical Data
gain error and uniform bandwidth, and differential signal paths
minimize distortion.
At low gain the VGA should limit the system noise performance
(SNR), whereas at high gains the noise is defined by the source
and LNA. The maximum voltage swing is bounded by the fullscale peak-to-peak ADC input voltage (2 V p-p).
Variable Gain Amplifier
The differential X-AMP VGA provides precise input
attenuation and interpolation. It has a low input-referred noise
of 4 nV/√Hz and excellent gain linearity. A simplified block
diagram is shown in Figure 42.
GAIN
GAIN INTERPOLATOR
+
The gain control interface, GAIN+, is a differential input. VGAIN
varies the gain of all VGAs through the interpolator by selecting
the appropriate input stages connected to the input attenuator.
The nominal VGAIN range for 30 dB/V is 0 V to 1 V, with the best
gain-linearity from about 0.1 V to 0.9 V, where the error is
typically less than ±0.2 dB. For VGAIN voltages greater than 0.9 V
and less than 0.1 V, the error increases. The value of the VGAIN
voltage can be increased to that of the supply voltage without
gain foldover.
Gain control response time is less than 750 ns to settle within 10%
of the final value for a change from minimum to maximum gain.
There are two ways in which the GAIN pins can be interfaced.
Using a single-ended method, a Kelvin type of connection to
ground should be used as shown in Figure 43. For driving multiple
devices, it is preferred to use a differential method as shown in
Figure 44. In either method, the GAIN pins should be dc-coupled
and driven to accommodate a 1 V full-scale input.
POSTAMP
gm
VIP
Gain Control
3dB
–
POSTAMP
06304-078
VIN
Figure 42. Simplified VGA Schematic
Figure 43. Single-Ended Gain Pin Configuration
The input stages of the X-AMP are distributed along the ladder,
and a biasing interpolator, controlled by the gain interface,
determines the input tap point. With overlapping bias currents,
signals from successive taps merge to provide a smooth
attenuation range from 0 dB to −30 dB. This circuit technique
results in linear-in-dB gain law conformance and low distortion
levels—only deviating ±0.2 dB or less from the ideal. The gain
slope is monotonic with respect to the control voltage and is
stable with variations in process, temperature, and supply.
The X-AMP inputs are part of a 25 dB gain feedback amplifier
that completes the VGA. Its bandwidth is about 80 MHz. The
input stage is designed to reduce feedthrough to the output and
to ensure excellent frequency response uniformity across the
gain setting.
499Ω
AD9271
GAIN+
100Ω
0.01µF
GAIN–
±0.25DC AT
0.5V CM
499Ω
AD8318
±0.25DC AT
0.5V CM
26kΩ
±0.5V DC
0.5V CM
523Ω
100Ω
0.01µF
AVDD
50Ω
10kΩ
499Ω
06304-098
The input of the VGA is a 12-stage differential resistor ladder with
3.01 dB per tap. The resulting total gain range is 30 dB, which
allows for range loss at the endpoints. The effective input resistance
per side is 180 Ω nominally for a total differential resistance of
360 Ω. The ladder is driven by a fully differential input signal from
the LNA. LNA outputs are dc-coupled to avoid external decoupling
capacitors. The common-mode voltage of the attenuator and the
VGA is controlled by an amplifier that uses the same midsupply
voltage derived in the LNA, permitting dc coupling of the LNA
to the VGA without introducing large offsets due to commonmode differences. However, any offset from the LNA will be
amplified as the gain is increased, producing an exponentially
increasing VGA output offset.
Figure 44. Differential Gain Pin Configuration
VGA Noise
In a typical application, a VGA compresses a wide dynamic
range input signal to within the input span of an ADC. The
input-referred noise of the LNA limits the minimum resolvable
input signal, whereas the output-referred noise, which depends
primarily on the VGA, limits the maximum instantaneous
dynamic range that can be processed at any one particular gain
control voltage. This limit is set in accordance with the
quantization noise floor of the ADC.
Output- and input-referred noise as a function of VGAIN are
shown in Figure TBD and Figure TBD for the short-circuited
input conditions. The input noise voltage is simply equal to the
output noise divided by the measured gain at each point in the
control range.
The output-referred noise is a flat 65 nV/√Hz over most of the
gain range, because it is dominated by the fixed output-referred
noise of the VGA. At the high end of the gain control range, the
Rev. PrA | Page 26 of 58
Preliminary Technical Data
AD9271
noise of the LNA and source prevail. The input-referred noise
reaches its minimum value near the maximum gain control
voltage, where the input-referred contribution of the VGA is
miniscule.
At lower gains, the input-referred noise, and therefore the noise
figure, increases as the gain decreases. The instantaneous
dynamic range of the system is not lost, however, because the
input capacity increases as the input-referred noise increases.
The contribution of the ADC noise floor has the same
dependence. The important relationship is the magnitude of the
VGA output noise floor relative to that of the ADC.
Tuning is normally off to avoid changing the capacitor settings
during critical times. The tuning circuit is enabled and disabled
through the SPI. Tuning should be done after initial power-up
and after reprogramming the filter cutoff scaling or ADC
sample rate. Occasional retuning during an idle time is
recommended.
Gain control noise is a concern in very low noise applications.
Thermal noise in the gain control interface can modulate the
channel gain. The resultant noise is proportional to the output
signal level and usually only evident when a large signal is present.
The gain interface includes an on-chip noise filter, which reduces
this effect significantly at frequencies above 5 MHz. Care should be
taken to minimize noise impinging at the GAIN input. An external
RC filter can be used to remove VGAIN source noise. The filter bandwidth should be sufficient to accommodate the desired control
bandwidth.
Antialiasing Filter
The filter that the signal reaches prior to the ADC is used to
reject dc signals and to bandlimit the signal for antialiasing.
Figure 45 shows the architecture of the filter.
4kΩ
1C*
56/112pF
2kΩ
2kΩ
7.5C*
2kΩ
2kΩ
2kΩ
6.5C*
2kΩ
1C*
4kΩ
*C = 0.5 TO 3.1pF
06304-099
56/112pF
Figure 45. Simplified Filter Schematic
The filter can be configured for dc coupling or to have a single
pole for high-pass filtering at either 700 kHz or 350 kHz
(programmed through the SPI). The high-pass pole, however, is
not tuned and can vary by ±30%.
A third-order Butterworth low-pass filter is used to reduce
noise bandwidth and provide antialiasing for the ADC. The
filter uses on-chip tuning to trim the capacitors to set the
desired cutoff and reduce variation. The default −3dB cutoff is
1/3 the ADC sample clock rate. The cutoff can be scaled to 0.7,
0.8, 0.9, 1, 1.1, 1.2, or 1.3 times this frequency through the SPI.
The cutoff can be set from 8 MHz to 18 MHz.
Rev. PrA | Page 27 of 58
AD9271
Preliminary Technical Data
3.3V
A/D CONVERTER
The output staging block aligns the data, carries out the error
correction, and passes the data to the output buffers. The data is
then serialized and aligned to the frame and output clock.
CLOCK INPUT CONSIDERATIONS
For optimum performance, the AD9271 sample clock inputs
(CLK+ and CLK−) should be clocked with a differential signal.
This signal is typically ac-coupled into the CLK+ and CLK− pins
via a transformer or capacitors. These pins are biased internally
and require no additional bias.
Figure 46 shows the preferred method for clocking the AD9271.
The low jitter clock source, such as the Valpey Fisher oscillator
VFAC3-BHL-50MHz, is converted from single-ended to
differential using an RF transformer. The back-to-back Schottky
diodes across the secondary transformer limit clock excursions
into the AD9271 to approximately 0.8 V p-p differential. This
helps prevent the large voltage swings of the clock from feeding
through to other portions of the AD9271 and preserves the fast
rise and fall times of the signal, which are critical to low jitter
performance.
0.1µF
0.1µF
0.1µF
0.1µF
EN OUT
50Ω 100Ω
240Ω
RESISTOR IS OPTIONAL.
Figure 47. Differential PECL Sample Clock
3.3V
AD951x FAMILY
0.1µF
VFAC3
OUT
EN
0.1µF
CLK+
CLK–
CLK
06304-052
*50Ω
RESISTOR IS OPTIONAL.
Figure 48. Differential LVDS Sample Clock
In some applications, it is acceptable to drive the sample clock
inputs with a single-ended CMOS signal. In such applications,
CLK+ should be driven directly from a CMOS gate, and the
CLK− pin should be bypassed to ground with a 0.1 μF capacitor
in parallel with a 39 kΩ resistor (see Figure 48). Although the
CLK+ input circuit supply is AVDD (1.8 V), this input is
designed to withstand input voltages up to 3.3 V, making the
selection of the drive logic voltage very flexible.
3.3V
VFAC3
OUT
EN
AD951x FAMILY
0.1µF
CLK
50Ω*
OPTIONAL
0.1µF
100Ω
CMOS DRIVER
CLK–
0.1µF
39kΩ
*50Ω RESISTOR IS OPTIONAL.
Figure 49. Single-Ended 1.8 V CMOS Sample Clock
3.3V
AD951x FAMILY
CLK
50Ω *
CMOS DRIVER
OPTIONAL 0.1µF
100Ω
CLK
0.1µF
Figure 46. Transformer-Coupled Differential Clock
CLK+
ADC
AD9271
CLK
0.1µF
ADC
AD9271
SCHOTTKY
DIODES:
HSM2812
ADC
AD9271
100Ω
0.1µF
LVDS DRIVER
50Ω *
CLK+
06304-050
0.1µF
0.1µF
CLK
VFAC3
CLK–
CLK–
240Ω
06304-051
*50Ω
EN
0.1µF
VFAC3
0.1µF
CLK
0.1µF
MINI-CIRCUITS
ADT1–1WT, 1:1Z
0.1µF
XFMR
ADC
AD9271
100Ω
PECL DRIVER
50Ω*
OUT
3.3V
CLK+
CLK
06304-053
Each stage except for the last of the pipeline consists of a low
resolution flash ADC connected to a switched-capacitor DAC
and interstage residue amplifier (MDAC). The residue amplifier
magnifies the difference between the reconstructed DAC output
and the flash input for the next stage in the pipeline. One bit of
redundancy is used in each stage to facilitate digital correction
of flash errors. The last stage consists of a flash ADC.
AD951x FAMILY
VFAC3
OUT
EN
0.1µF
CLK+
ADC
AD9271
CLK–
*50Ω RESISTOR IS OPTIONAL.
06304-054
The AD9271 architecture consists of a pipelined ADC that is
divided into three sections: a 4-bit first stage followed by eight
1.5-bit stages and a 3-bit flash. Each stage provides sufficient
overlap to correct for flash errors in the preceding stages. The
quantized outputs from each stage are combined into a 12-bit
result in the digital correction logic. The pipelined architecture
permits the first stage to operate on a new input sample and the
remaining stages to operate on preceding samples. Sampling
occurs on the rising edge of the clock.
Figure 50. Single-Ended 3.3 V CMOS Sample Clock
Clock Duty Cycle Considerations
If a low jitter clock is available, another option is to ac-couple a
differential PECL signal to the sample clock input pins as shown
in Figure 47. The AD951x family of clock drivers offers excellent
jitter performance.
Typical high speed ADCs use both clock edges to generate a
variety of internal timing signals. As a result, these ADCs may
be sensitive to the clock duty cycle. Commonly, a 5% tolerance
is required on the clock duty cycle to maintain dynamic
performance characteristics. The AD9271 contains a duty cycle
Rev. PrA | Page 28 of 58
Preliminary Technical Data
AD9271
stabilizer (DCS) that retimes the nonsampling edge, providing
an internal clock signal with a nominal 50% duty cycle. This
allows a wide range of clock input duty cycles without affecting
the performance of the AD9271. When the DCS is on, noise
and distortion performance are nearly flat for a wide range of
duty cycles. However, some applications may require the DCS
function to be off. If so, keep in mind that the dynamic range
performance can be affected when operated in this mode. See the
Memory Map section for more details on using this feature.
The duty cycle stabilizer uses a delay-locked loop (DLL) to
create the nonsampling edge. As a result, any changes to the
sampling frequency require approximately eight clock cycles
to allow the DLL to acquire and lock to the new rate.
Clock Jitter Considerations
High speed, high resolution ADCs are sensitive to the quality of the
clock input. The degradation in SNR at a given input frequency
(fA) due only to aperture jitter (tJ) can be calculated by
SNR Degradation = 20 × log 10[1/2 × π × fA × tJ]
In this equation, the rms aperture jitter represents the root mean
square of all jitter sources, including the clock input, analog input
signal, and ADC aperture jitter. IF undersampling applications
are particularly sensitive to jitter (see Figure 51).
The clock input should be treated as an analog signal in cases
where aperture jitter may affect the dynamic range of the AD9271.
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, such as the Valpey Fisher VFAC3 series.
If the clock is generated from another type of source (by gating,
dividing, or other methods), it should be retimed by the
original clock at the last step.
Refer to the AN-501 Application Note and the AN-756
Application Note for more in-depth information about jitter
performance as it relates to ADCs (visit www.analog.com).
130
RMS CLOCK JITTER REQUIREMENT
120
100
16 BITS
90
14 BITS
80
12 BITS
70
60
50
10 BITS
8 BITS
40
30
1
0.125ps
0.25ps
0.5ps
1.0ps
2.0ps
10
100
ANALOG INPUT FREQUENCY (MHz)
1000
06304-038
SNR (dB)
110
Figure 51. Ideal SNR vs. Input Frequency and Jitter
Rev. PrA | Page 29 of 58
AD9271
Preliminary Technical Data
In power-down mode, low power dissipation is achieved by
shutting down the reference, reference buffer, PLL, and biasing
networks. The decoupling capacitors on REFT and REFB are
discharged when entering power-down mode and must be
recharged when returning to normal operation. As a result, the
wake-up time is related to the time spent in the power-down
mode; shorter cycles result in proportionally shorter wake-up
times. With the recommended 0.1 μF and 4.7 μF decoupling
capacitors on REFT and REFB, it takes approximately 1 sec to
fully discharge the reference buffer decoupling capacitors and
xx μs to restore full operation.
Power Dissipation and Power-Down Mode
As shown in Figure 52, the power dissipated by the AD9271 is
proportional to its sample rate. The digital power dissipation
does not vary much because it is determined primarily by the
DRVDD supply and bias current of the LVDS output drivers.
800
700
600
Currents (mA)
500
400
There are a number of other power-down options available
when using the SPI port interface. The user can individually
power down each channel or put the entire device into standby
mode. This allows the user to keep the internal PLL powered up
when fast wake-up times (~xxx ns) are required. See the
Memory Map section for more details on using these features.
25MSPS Speed Grade
40MSPS Speed Grade
50MSPS Speed Grade
300
IDRVDD
200
100
0
0
10
20
30
40
50
60
Sampling Frequency (MSPS)
Digital Outputs and Timing
Figure 52. Supply Current vs. fSAMPLE for fIN = 7.5 MHz
The AD9271 differential outputs conform to the ANSI-644 LVDS
standard on default power-up. This can be changed to a low power,
reduced signal option similar to the IEEE 1596.3 standard using the
SDIO/ODM pin or via the SPI. This LVDS standard can further
reduce the overall power dissipation of the device by approximately
xx mW. See the SDIO Pin section or Table 16 in the Memory
Map section for more information. The LVDS driver current is
derived on-chip and sets the output current at each output equal
to a nominal 3.5 mA. A 100 Ω differential termination resistor
placed at the LVDS receiver inputs results in a nominal 350 mV
swing at the receiver.
190
180
170
Power/channel (mW)
160
150
140
130
120
25MSPS Speed Grade
40MSPS Speed Grade
110
50MSPS Speed Grade
100
0
10
20
30
40
50
60
Sampling Frequency (MSPS)
Figure 53. Power per Channel vs. fSAMPLE for fIN = 7.5 MHz
By asserting the PDWN pin high, the AD9271 is placed in
power-down mode. In this state, the ADC typically dissipates
xx mW. During power-down, the LVDS output drivers are placed
in a high impedance state. The AD9271 returns to normal
operating mode when the PDWN pin is pulled low. This pin is
both 1.8 V and 3.3 V tolerant.
The AD9271 LVDS outputs facilitate interfacing with LVDS
receivers in custom ASICs and FPGAs that have LVDS capability
for superior switching performance in noisy environments.
Single point-to-point net topologies are recommended with a
100 Ω termination resistor placed as close to the receiver as
possible. No far-end receiver termination and poor differential
trace routing may result in timing errors. It is recommended
that the trace length is no longer than 24 inches and that the
differential output traces are kept close together and at equal
lengths. An example of the FCO and data stream with proper
trace length and position can be found in Figure 54.
By asserting the STBY pin high, the AD9271 is placed in a
standby mode. In this state, the ADC typically dissipates
xx mW. During standby, the entire part is powered down except
the internal references. The LVDS output drivers are placed in a
high impedance state. This mode is well suited for applications
that require power savings because it allows the device to be
powered down when not in use and then quickly powered up.
The time to power this device back up is also greatly reduced. The
AD9271 returns to normal operating mode when the STBY pin
is pulled low. This pin is both 1.8 V and 3.3 V tolerant.
Rev. PrA | Page 30 of 58
Preliminary Technical Data
AD9271
Figure 54. LVDS Output Timing Example in ANSI Mode (Default)
An example of the LVDS output using the ANSI standard (default)
data eye and a time interval error (TIE) jitter histogram with
trace lengths of less than 24 inches on regular FR-4 material is
shown in Figure 55. Figure 56 shows an example of when the
trace lengths exceed 24 inches on regular FR-4 material. Notice
that the TIE jitter histogram reflects the decrease of the data eye
opening as the edge deviates from the ideal position; therefore,
the user must determine if the waveforms meet the timing budget
of the design when the trace lengths exceed 24 inches. Additional
SPI options allow the user to further increase the internal
termination (and therefore increase the current) of all eight
outputs in order to drive longer trace lengths (see Figure 57).
Even though this produces sharper rise and fall times on the
data edges, is less prone to bit errors, and improves frequency
distribution (see Figure 57), the power dissipation of the DRVDD
supply increases when this option is used.
In cases that require increased driver strength to the DCO and
FCO outputs because of load mismatch Register 15 allows the
user to double the drive strength. To do this, set the appropriate
bit in Register 5. Note that this feature cannot be used with Bit 4
and Bit 5 in Register 15 because these bits take precedence over
this feature. See the Memory Map section for more details.
Figure 56. Data Eye for LVDS Outputs in ANSI Mode with Trace Lengths of
Greater than 24 Inches on Standard FR-4
Figure 57. Data Eye for LVDS Outputs in ANSI Mode with 100 Ω Termination
on and Trace Lengths of Greater than 24 Inches on Standard FR-4
The format of the output data is offset binary by default. An
example of the output coding format can be found in Table 11.
If it is desired to change the output data format to twos
complement, see the Memory Map section.
Table 11. Digital Output Coding
Code
4095
2048
2047
0
(VIN+) − (VIN−), Input
Span = 2 V p-p (V)
+1.00
0.00
−0.000488
−1.00
Digital Output Offset Binary
(D11 ... D0)
1111 1111 1111
1000 0000 0000
0111 1111 1111
0000 0000 0000
Data from each ADC is serialized and provided on a separate
channel. The data rate for each serial stream is equal to 12 bits
times the sample clock rate, with a maximum of 600 Mbps
(12 bits × 50 MSPS = 600 Mbps). The lowest typical conversion
rate is 10 MSPS. However, if lower sample rates are required for
a specific application, the PLL can be set up for encode rates
lower than 10 MSPS via the SPI. This allows encode rates as low
as 5 MSPS. See the Memory Map section for details on enabling
this feature.
Figure 55. Data Eye for LVDS Outputs in ANSI Mode with Trace Lengths of
Less than 24 Inches on Standard FR-4
Rev. PrA | Page 31 of 58
AD9271
Preliminary Technical Data
Two output clocks are provided to assist in capturing data from
the AD9271. The DCO is used to clock the output data and is
equal to six times the sampling clock (CLK) rate. Data is
clocked out of the AD9271 and must be captured on the rising
and falling edges of the DCO that supports double data rate
(DDR) capturing. The frame clock out (FCO) is used to signal
the start of a new output byte and is equal to the sampling clock
rate. See the timing diagram shown in Figure 2 for more
information.
Table 12. Flex Output Test Modes
Output Test
Mode Bit
Sequence
0000
0001
Pattern Name
Off (default)
Midscale short
0010
+Full-scale short
0011
−Full-scale short
0100
Checkerboard
0101
0110
0111
PN sequence long1
PN sequence short1
One/zero word toggle
1000
1001
User input
One/zero bit toggle
1010
1× sync
1011
One bit high
1100
Mixed frequency
1
Digital Output Word 1
N/A
1000 0000 (8 bits)
10 0000 0000 (10 bits)
1000 0000 0000 (12 bits)
10 0000 0000 0000 (14 bits)
1111 1111 (8 bits)
11 1111 1111 (10 bits)
1111 1111 1111 (12 bits)
11 1111 1111 1111 (14 bits)
0000 0000 (8 bits)
00 0000 0000 (10 bits)
0000 0000 0000 (12 bits)
00 0000 0000 0000 (14 bits)
1010 1010 (8 bits)
10 1010 1010 (10 bits)
1010 1010 1010 (12 bits)
10 1010 1010 1010 (14 bits)
N/A
N/A
1111 1111 (8 bits)
11 1111 1111 (10 bits)
1111 1111 1111 (12 bits)
11 1111 1111 1111 (14 bits)
Register 0x19 to Register 0x1A
1010 1010 (8 bits)
10 1010 1010 (10 bits)
1010 1010 1010 (12 bits)
10 1010 1010 1010 (14 bits)
0000 1111 (8 bits)
00 0001 1111 (10 bits)
0000 0011 1111 (12 bits)
00 0000 0111 1111 (14 bits)
1000 0000 (8 bits)
10 0000 0000 (10 bits)
1000 0000 0000 (12 bits)
10 0000 0000 0000 (14 bits)
1010 0011 (8 bits)
10 0110 0011 (10 bits)
1010 0011 0011 (12 bits)
10 1000 0110 0111 (14 bits)
Digital Output Word 2
N/A
Same
Subject
to Data
Format
Select
N/A
Yes
Same
Yes
Same
Yes
0101 0101 (8 bits)
01 0101 0101 (10 bits)
0101 0101 0101 (12 bits)
01 0101 0101 0101 (14 bits)
N/A
N/A
0000 0000 (8 bits)
00 0000 0000 (10 bits)
0000 0000 0000 (12 bits)
00 0000 0000 0000 (14 bits)
Register 0x1B to Register 0x1C
N/A
No
Yes
Yes
No
No
No
N/A
No
N/A
No
N/A
No
All test mode options, except PN Sequence Short and PN Sequence Long, can support 8- to 14-bit word lengths in order to verify data capture to the receiver.
Rev. PrA | Page 32 of 58
Preliminary Technical Data
AD9271
When using the serial port interface (SPI), the DCO phase can
be adjusted in 60° increments relative to the data edge. This
enables the user to refine system timing margins if required.
The default DCO timing, as shown in Figure 2, is 90° relative to
the output data edge.
An 8-, 10-, and 14-bit serial stream can also be initiated from
the SPI. This allows the user to implement different serial streams
and test the device’s compatibility with lower and higher resolution
systems. When changing the resolution to an 8- or 10-bit serial
stream, the data stream is shortened. When using the 14-bit
option, the data stream stuffs two 0s at the end of the normal
14-bit serial data.
When using the SPI, all of the data outputs can also be inverted
from their nominal state. This is not to be confused with
inverting the serial stream to an LSB-first mode. In default
mode, as shown in Figure 2, the MSB is represented first in the
data output serial stream. However, this can be inverted so that
the LSB is represented first in the data output serial stream (see
Figure 3).
There are 12 digital output test pattern options available that
can be initiated through the SPI. This is a useful feature when
validating receiver capture and timing. Refer to Table 12 for the
output bit sequencing options available. Some test patterns have
two serial sequential words and can be alternated in various
ways, depending on the test pattern chosen. It should be noted
that some patterns may not adhere to the data format select
option. In addition, customer user patterns can be assigned in
the 0x19, 0x1A, 0x1B, and 0x1C register addresses. All test mode
options, except PN Sequence Short and PN Sequence Long can
support 8- to 14-bit word lengths in order to verify data capture
to the receiver.
The PN Sequence Short pattern produces a pseudorandom bit
sequence that repeats itself every 29 – 1 or 511 bits. A
description of the PN sequence and how it is generated can be
found in section 5.1 of the ITU-T 0.150 (05/96) standard. For
the AD9271, the only discrepancy from the ITU standard is that
the starting value is a specific value instead of all ones. See
Table 10 for initial values.
The PN Sequence Long pattern produces a pseudorandom bit
sequence that repeats itself every 223 – 1 or 8,388,607 bits. A
description of the PN sequence and how it is generated can be
found in section 5.6 of the ITU-T 0.150 (05/96) standard. The
only two discrepancies between the ITU standard and the
AD9271 PN Sequence Long implementation are as follows.
First, the starting value is a specific value instead of all ones.
Second, the AD9271 inverts the bit stream with relation to the
ITU standard. See Table 10 for initial values.
Table 10. PN Sequence
Initial Value
First 3 output samples
(MSB 1st)
PN Sequence
Short
0x0df
0xdf9, 0x353, 0x301
PN Sequence
Long
0x29b80a
0x591, 0xfd7, 0a3
Consult the Memory Map section for information on how to
change these additional digital output timing features through the
serial port interface or SPI.
SDIO Pin
This pin is required to operate the SPI port interface. It has an
internal 30 kΩ pull-down resistor that pulls this pin low and is
only 1.8 V tolerant. If applications require that this pin be driven
from a 3.3 V logic level, insert a 1 kΩ resistor in series with this
pin to limit the current.
SCLK Pin
This pin is required to operate the SPI port interface. It has an
internal 30 kΩ pull-down resistor that pulls this pin low and is
both 1.8 V and 3.3 V tolerant.
CSB Pin
This pin is required to operate the SPI port interface. It has an
internal 70 kΩ pull-down resistor that pulls this pin low and is
both 1.8 V and 3.3 V tolerant.
RBIAS Pin
To set the internal core bias current of the ADC, place a resistor
(nominally equal to 10.0 kΩ) to ground at the RBIAS pin. The
resistor current is derived on-chip and sets the ADC’s AVDD
current to a nominal xxx mA at 50 MSPS. Therefore, it is
imperative that at least a 1% tolerance on this resistor be used to
achieve consistent performance.
Voltage Reference
A stable and accurate 0.5 V voltage reference is built into the
AD9271. This is gained up internally by a factor of 2, setting
VREF to 1.0 V, which results in a full-scale differential input span
of 2 V p-p for the ADC. The VREF is set internally by default;
however, the VREF pin can be driven externally with a 1.0 V
reference to achieve more accuracy.
When applying the decoupling capacitors to the VREF, REFT,
and REFB pins, use ceramic low ESR capacitors. These capacitors
should be close to reference pins and on the same layer of the
PCB as the AD9271. The recommended capacitor values and
configurations for the AD9271 reference pin can be found in
Figure 58.
Rev. PrA | Page 33 of 58
AD9271
Preliminary Technical Data
External Reference Operation
Table 13. Reference Settings
SENSE
Voltage
AVDD
Resulting
VREF (V)
N/A
AGND to 0.2 V
1.0
The use of an external reference may be necessary to enhance
the gain accuracy of the ADC or improve thermal drift characteristics. Figure 61 shows the typical drift characteristics of the
internal reference in 1 V mode.
Internal Reference Operation
A comparator within the AD9271 detects the potential at the
SENSE pin and configures the reference. If SENSE is grounded,
the reference amplifier switch is connected to the internal
resistor divider (see Figure 58), setting VREF to 1 V.
The REFT and REFB pins establish their input span of the ADC
core from the reference configuration. The analog input fullscale range of the ADC equals twice the voltage at the reference
pin for either an internal or an external reference configuration.
VIN+
VIN–
When the SENSE pin is tied to AVDD, the internal reference is
disabled, allowing the use of an external reference. The external
reference is loaded with an equivalent 6 kΩ load. An internal
reference buffer generates the positive and negative full-scale
references, REFT and REFB, for the ADC core. Therefore, the
external reference must be limited to a nominal of 1.0 V.
5
0
-5
Vref Error (%)
Selected
Mode
External
Reference
Internal,
2 V p-p FSR
Resulting
Differential
Span (V p-p)
2 × external
reference
2.0
-10
-15
REFT
ADC
CORE
0.1µF
0.1µF
+
-20
4.7µF
REFB
-25
0
0.5
1
1.5
0.1µF
VREF
2
2.5
3
3.5
Current Load (mA)
Figure 60. VREF Accuracy vs. Load, AD9271-50
1µF
0.1µF
SELECT
LOGIC
0.5V
0.02
SENSE
0
-0.02
Figure 58. Internal Reference Configuration
-0.06
VREF ERROR (%)
06304-064
-0.04
-0.08
-0.1
-0.12
VIN+
-0.14
VIN–
REFT
ADC
CORE
-0.18
+
4.7µF
-0.2
-40
0.1µF*
SELECT
LOGIC
0
20
40
Figure 61. Typical VREF Drift, AD9271-50
0.5V
06304-065
SENSE
*OPTIONAL.
-20
TEMPERATURE (oC)
0.1µF
VREF
AVDD
0.1µF
REFB
EXTERNAL
REFERENCE
1µF*
0.1µF
-0.16
Figure 59. External Reference Operation
Rev. PrA | Page 34 of 58
60
80
Preliminary Technical Data
AD9271
There are three pins that define the serial port interface, or SPI,
to this particular ADC. They are the SCLK, SDIO, and CSB
pins. The SCLK (serial clock) is used to synchronize the read
and write data presented to the ADC. The SDIO (serial data
input/output) is a dual-purpose pin that allows data to be sent
to and read from the internal ADC memory map registers. The
CSB (chip select bar) is an active low control that enables or
disables the read and write cycles (see Table 14).
Table 14. Serial Port Pins
Pin
SCLK
SDIO
CSB
Function
Serial Clock. The serial shift clock input. SCLK is used to
synchronize serial interface reads and writes.
Serial Data Input/Output. A dual-purpose pin. The typical
role for this pin is as an input or output, depending on
the instruction sent and the relative position in the
timing frame.
Chip Select Bar (Active Low). This control gates the read
and write cycles.
The falling edge of the CSB in conjunction with the rising edge
of the SCLK determines the start of the framing sequence. During
an instruction phase, a 16-bit instruction is transmitted, followed
by one or more data bytes, which is determined by Bit Fields
W0 and W1. An example of the serial timing and its definitions
can be found in Figure 63 and Table 15. In normal operation,
CSB is used to signal to the device that SPI commands are to be
received and processed. When CSB is brought low, the device
processes SCLK and SDIO to process instructions. Normally,
CSB remains low until the communication cycle is complete.
However, if connected to a slow device, CSB can be brought
high between bytes, allowing older microcontrollers enough
time to transfer data into shift registers. CSB can be stalled
when transferring one, two, or three bytes of data. When W0
and W1 are set to 11, the device enters streaming mode and
continues to process data, either reading or writing, until the
CSB is taken high to end the communication cycle. This allows
complete memory transfers without having to provide additional
instructions. Regardless of the mode, if CSB is taken high in the
middle of any byte transfer, the SPI state machine is reset and
the device waits for a new instruction.
In addition to word length, the instruction phase determines if
the serial frame is a read or write operation, allowing the serial
port to be used to both program the chip and read the contents
of the on-chip memory. If the instruction is a readback operation,
performing a readback causes the serial data input/output (SDIO)
pin to change direction from an input to an output at the
appropriate point in the serial frame.
Data can be sent in MSB- or LSB-first mode. MSB-first mode
is the default at power-up and can be changed by adjusting the
configuration register. For more information about this and
other features, see the user manual Interfacing to High Speed
ADCs via SPI.
HARDWARE INTERFACE
The pins described in Table 14 compose the physical interface
between the user’s programming device and the serial port of
the AD9271. The SCLK and CSB pins function as inputs when
using the SPI interface. The SDIO pin is bidirectional, functioning
as an input during write phases and as an output during readback.
In cases where multiple SDIO pins share a common connection,
care should be taken to ensure that proper VOH levels are met.
Figure 62 shows the number of SDIO pins that can be connected
together, assuming the same load as the AD9271 and the
resulting VOH level.
1.800
1.795
1.790
1.785
1.780
1.775
1.770
1.765
1.760
1.755
1.750
1.745
1.740
1.735
1.730
1.725
1.720
1.715
0
10
20
30
40
50
60
70
Figure 62. SDIO Pin Loading
Rev. PrA | Page 35 of 58
80
90
NUMBER OF SDIO PINS CONNECTED TOGETHER
100
05967-037
The AD9271 serial port interface allows the user to configure
the signal chain for specific functions or operations through a
structured register space provided inside the chip. This offers
the user added flexibility and customization depending on the
application. Addresses are accessed via the serial port and can
be written to or read from via the port. Memory is organized
into bytes that can be further divided down into fields, as documented in the Memory Map section. Detailed operational
information can be found in the Analog Devices, Inc., user
manual Interfacing to High Speed ADCs via SPI.
In addition to the operation modes, the SPI port can be
configured to operate in different manners. For applications
that do not require a control port, the CSB line can be tied and
held high. This places the remainder of the SPI pins in their
secondary mode as defined in the Serial Port Interface (SPI)
section. CSB can also be tied low to enable 2-wire mode. When
CSB is tied low, SCLK and SDIO are the only pins required for
communication. Although the device is synchronized during
power-up, caution must be exercised when using this mode to
ensure that the serial port remains synchronized with the CSB
line. When operating in 2-wire mode, it is recommended to use
a 1-, 2-, or 3-byte transfer exclusively. Without an active CSB
line, streaming mode can be entered but not exited.
VOH
SERIAL PORT INTERFACE (SPI)
AD9271
Preliminary Technical Data
when the CSB is strapped to AVDD during device power-up.
See the section for details on which pin-strappable functions are
supported on the SPI pins.
This interface is flexible enough to be controlled by either serial
PROMS or PIC mirocontrollers. This provides the user an
alternative method, other than a full SPI controller, to program
the ADC (see the AN-812 Application Note).
If the user chooses not to use the SPI interface, these pins serve
a dual function and are associated with secondary functions
tDS
tS
tHI
tCLK
tDH
tH
tLO
CSB
SCLK DON’T CARE
R/W
W1
W0
A12
A11
A10
A9
A8
A7
D5
D4
D3
D2
D1
D0
DON’T CARE
06304-068
SDIO DON’T CARE
DON’T CARE
Figure 63. Serial Timing Details
Table 15. Serial Timing Definitions
Parameter
tDS
tDH
tCLK
tS
tH
tHI
tLO
tEN_SDIO
Minimum Timing (ns)
5
2
40
5
2
16
16
1
tDIS_SDIO
5
Description
Setup time between the data and the rising edge of SCLK
Hold time between the data and the rising edge of SCLK
Period of the clock
Setup time between CSB and SCLK
Hold time between CSB and SCLK
Minimum period that SCLK should be in a logic high state
Minimum period that SCLK should be in a logic low state
Minimum time for the SDIO pin to switch from an input to an output relative to the
SCLK falling edge (not shown in Figure 63).
Minimum time for the SDIO pin to switch from an output to an input relative to the
SCLK rising edge (not shown in Figure 63).
Rev. PrA | Page 36 of 58
Preliminary Technical Data
AD9271
MEMORY MAP
READING THE MEMORY MAP TABLE
Each row in the memory map table has eight address locations.
The memory map is roughly divided into three sections: chip
configuration register map (Address 0x00 to Address 0x02), device
index and transfer register map (Address 0x05 and Address 0xFF),
and program register map (Address 0x08 to Address 0x25).
The left most column of the memory map indicates the register
address number, and the default value is shown in the right most
column. The (MSB) Bit 7 column is the start of the default hexadecimal value given. For example, Address 0x09, clock, has a
default value of 0x01, meaning that Bit 7 = 0, Bit 6 = 0, Bit 5 = 0,
Bit 4 = 0, Bit 3 = 0, Bit 2 = 0, Bit 1 = 0, and Bit 0 = 1, or 0000 0001 in
binary. This setting is the default for the duty cycle stabilizer in
the on condition. By writing a 0 to Bit 6 of this address followed
by an 0x01 in Register 0xFF (transfer bit), the duty cycle stabilizer
turns off. It is important to follow each writing sequence with a
transfer bit to update the SPI registers. For more information on
this and other functions, consult the user manual Interfacing to
High Speed ADCs via SPI.
RESERVED LOCATIONS
Undefined memory locations should not be written to except
when writing the default values suggested in this data sheet.
Addresses that have values marked as 0 should be considered
reserved and have a 0 written into their registers during power-up.
DEFAULT VALUES
After a reset, critical registers are automatically loaded with
default values. These values are indicated in Table 16, where an
X refers to an undefined feature.
LOGIC LEVELS
An explanation of various registers follows: “Bit is set” is
synonymous with “bit is set to Logic 1” or “writing Logic 1 for
the bit.” Similarly, “clear a bit” is synonymous with “bit is set to
Logic 0” or “writing Logic 0 for the bit.”
Rev. PrA | Page 37 of 58
AD9271
Preliminary Technical Data
Table 16. Memory Map Register
Addr.
Bit 7
(Hex) Parameter Name
(MSB)
Chip Configuration Registers
00
chip_port_config
0
01
chip_id
02
chip_grade
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
LSB first
1 = on
0 = off
(default)
Soft
reset
1 = on
0 = off
(default)
1
1
Soft
reset
1 = on
0 = off
(default)
LSB first
1 = on
0 = off
(default)
Bit 0
(LSB)
Default
Value
(Hex)
0
0x18
Chip ID Bits 7:0
(AD9271 = 0x13), (default)
X
X
Child ID 6:4
(identify device
variants of Chip ID)
00 = 50 MSPS
(default)
01 = 40 MSPS
11 = 25 MSPS
Device Index and Transfer Registers
04
device_index_2
X
X
X
X
05
device_index_1
X
X
FF
device_update
X
X
Clock
Channel
DCO
1 = on
0 = off
(default)
X
Clock
Channel
FCO
1 = on
0 = off
(default)
X
ADC Functions
08
modes
X
X
X
X
09
clock
X
X
X
X
0D
test_io
User test mode
00 = off (default)
01 = on, single
alternate
10 = on, single once
11 = on, alternate once
Reset PN
long
gen
1 = on
0 = off
(default)
Reset
PN
short
gen
1 = on
0 = off
(default)
Read
only
Default Notes/
Comments
The nibbles
should be
mirrored so that
LSB- or MSB-first
mode registers
correctly
regardless of
shift mode.
Default is unique
chip ID, different
for each device.
This is a read-only
register.
Child ID used to
differentiate
graded devices.
X
X
X
X
0x00
Data
Channel
H
1 = on
(default)
0 = off
Data
Channel
D
1 = on
(default)
0 = off
X
Data
Channel
G
1 = on
(default)
0 = off
Data
Channel
F
1 = on
(default)
0 = off
Data
Channel
E
1 = on
(default)
0 = off
0x0F
Bits are set to
determine which
on-chip device
receives the next
write command.
Data
Channel
C
1 = on
(default)
0 = off
X
Data
Channel
B
1 = on
(default)
0 = off
X
Data
Channel
A
1 = on
(default)
0 = off
SW
transfer
1 = on
0 = off
(default)
0x0F
Bits are set to
determine which
on-chip device
receives the next
write command.
0x00
Synchronously
transfers data
from the master
shift register to
the slave.
Internal power-down mode
000 = chip run (default)
001 = full power-down
010 = standby
011 = reset
100 = CW mode (TGC PWDN)
X
X
X
Duty
cycle
stabilizer
1 = on
(default)
0 = off
Output test mode—see Table 12 in the
Digital Outputs and Timing section
0000 = off (default)
0001 = midscale short
0010 = +FS short
0011 = −FS short
0100 = checkerboard output
0101 = PN 23 sequence
0110 = PN 9
0111 = one/zero word toggle
1000 = user input
1001 = one/zero bit toggle
0x00
Determines
various generic
modes of chip
operation.
0x01
Turns the internal
duty cycle stabilizer
on and off.
0x00
When set, the test
data is placed on
the output pins in
place of normal
data. (Local,
expect for PN
sequence)
LNA
bypass
1 = on
0 = off
(default)
Rev. PrA | Page 38 of 58
Preliminary Technical Data
Addr.
(Hex)
Parameter Name
0F
Flex_channel_input
10
Flex_offset
11
Flex_gain
X
X
14
output_mode
X
15
output_adjust
X
0 = LVDS
ANSI
(default)
1 = LVDS
low power,
(IEEE
1596.3
similar)
X
16
output_phase
X
19
user_patt1_lsb
1A
Bit 7
(MSB)
Bit 6
AD9271
Bit 5
Bit 4
Bit 0
(LSB)
Bit 3
Bit 2
Bit 1
1010 = 1× sync
1011 = one bit high
1100 = mixed bit frequency
(format determined by output_mode)
X
X
X
X
Filter cutoff frequency control
0000 = 0.7 × 1/3 × fSAMPLE
0001 = 0.8 × 1/3 × fSAMPLE
0010 = 0.9 × 1/3 × fSAMPLE
0011 = 1.0 × 1/3 × fSAMPLE
0100 = 1.1 × 1/3 × fSAMPLE
0101 = 1.2 × 1/3 × fSAMPLE
0110 = 1.3 × 1/3 × fSAMPLE
X
X
6-bit LNA offset adjustment
Table = TBD
X
Antialiasing filter
cutoff (global)
0x20
LNA force offset
correction
(local)
LNA gain
adjustment
(global)
LNA gain
00 = 5×
01 = 6×
10 = 8×
00 = offset binary
(default)
01 = twos
complement
0x01
0x00
Configures the
outputs and the
format of the data.
X
0x00
Determines LVDS
or other output
properties.
Primarily functions
to set the LVDS
span and
common-mode
levels in place of
an external
resistor.
On devices that
utilize global
clock divide,
determines which
phase of the
divider output is
used to supply
the output clock.
Internal latching
is unaffected.
X
X
Output
invert
1 = on
0 = off
(default)
Output driver
termination
00 = none (default)
01 = 200 Ω
10 = 100 Ω
11 = 100 Ω
X
X
X
X
X
0x03
B7
B6
B5
B4
0011 = output clock phase adjust
(0000 through 1010)
(Default: 180° relative to DATA edge)
0000 = 0° relative to DATA edge
0001 = 60° relative to DATA edge
0010 = 120° relative to DATA edge
0011 = 180° relative to DATA edge
0100 = 240° relative to DATA edge
0101 = 300° relative to DATA edge
0110 = 360° relative to DATA edge
0111 = 420° relative to DATA edge
1000 = 480° relative to DATA edge
1001 = 540° relative to DATA edge
1010 = 600° relative to DATA edge
1011 to 1111 = 660° relative to DATA edge
B3
B2
B1
B0
user_patt1_msb
B15
B14
B13
B12
B11
B10
B9
B8
0x00
1B
user_patt2_lsb
B7
B6
B5
B4
B3
B2
B1
B0
0x00
1C
user_patt2_msb
B15
B14
B13
B12
B11
B10
B9
B8
0x00
X
Rev. PrA | Page 39 of 58
Default Notes/
Comments
0x30
X
X
X
Default
Value
(Hex)
DCO
and FCO
2× drive
strength
1 = on
0 = off
(default)
0x00
User-defined
pattern, 1 LSB
(global).
User-defined
pattern, 1 MSB
(global).
User-defined
pattern, 2 LSB.
(global)
User-defined
pattern, 2 MSB
(global).
AD9271
Addr.
(Hex)
21
Parameter Name
serial_control
22
serial_ch_stat
2B
Preliminary Technical Data
Bit 7
(MSB)
LSB first
1 = on
0 = off
(default)
Bit 6
X
Bit 5
X
Bit 4
X
X
X
X
Flex_filter
X
Enable
automatic
low-pass
tuning
1 = on
0 = off
(default)
2C
Analog_Input
X
2D
Cross_point_Switch
X
Bit 0
(LSB)
Bit 2
Bit 1
000 = 12 bits (default, normal
bit stream)
001 = 8 bits
010 = 10 bits
011 = 12 bits
100 = 14 bits
X
Bit 3
<10
MSPS,
low
encode
rate
mode
1 = on
0 = off
(default)
X
X
X
X
X
X
X
X
X
X
X
X
X
Crosspoint switch enable
0 0000 = CDW0p/n
0 0001 = CDW1p/n
0 0010 = CDW2p/n
0 0011 = CDW3p/n
0 0100 = CDW4p/n
0 0101 = CDW5p/n
0 0111 = power down CW channel
1 0000 = CDW0p SE
1 0001 = CDW1p SE
1 0010 = CDW2p SE
1 0011 = CDW3p SE
1 0100 = CDW4p SE
1 0101 = CDW5p SE
1 0111 = power down CW channel
1 1000 = CDW0n SE
1 1001 = CDW1n SE
1 1010 = CDW2n SE
1 1011 = CDW3n SE
1 1100 = CDW4n SE
1 1101 = CDW5n SE
1 1111 = power down CW channel
Rev. PrA | Page 40 of 58
Default
Value
(Hex)
0x00
Default Notes/
Comments
Serial stream
control. Default
causes MSB first
and the native bit
stream (global).
Channel Channel
poweroutput
down
reset
1 = on
1 = on
0 = off
0 = off
(default) (default)
High-pass filter
cutoff
00 = dc (default)
01 = 700 kHz
10 = 350 kHz
0x00
Used to power
down individual
sections of a
converter (local).
0x00
Filter cutoff
(global)
X
0x00
LNA active
termination/input
impedance
(global)
0x07
Crosspoint switch
enable (local)
LOSW
1 = on
0 = off
(default)
Preliminary Technical Data
AD9271
Power and Ground Recommendations
When connecting power to the AD9271, it is recommended
that two separate 1.8 V supplies be used: one for analog (AVDD)
and one for digital (DRVDD). The AD9271 also requires a
3.3 V supply (CWVDD) as well for the crosspoint section. If
only one 1.8 V supply is available, it should be routed to the
AVDD first and then tapped off and isolated with a ferrite bead
or a filter choke preceded by decoupling capacitors for the
DRVDD. The user should employ several decoupling capacitors
on all supplies to cover both high and low frequencies. These
should be located close to the point of entry at the PC board
level and close to the parts with minimal trace lengths.
A single PC board ground plane should be sufficient when
using the AD9271. With proper decoupling and smart partitioning of the PC board’s analog, digital, and clock sections,
optimum performance is easily achieved.
exposed continuous copper plane on the PCB should mate to
the AD9271 exposed paddle, Pin 0. The copper plane should
have several vias to achieve the lowest possible resistive thermal
path for heat dissipation to flow through the bottom of the PCB.
These vias should be solder filled or plugged.
To maximize the coverage and adhesion between the ADC and
PCB, partition the continuous copper plane by overlaying a silkscreen on the PCB into several uniform sections. This provides
several tie points between the two during the reflow process. Using
one continuous plane with no partitions only guarantees one tie
point between the AD9271 and PCB. See Figure 64 for a PCB
layout example. For more detailed information on packaging
and the PCB layout, see the AN-772 Application Note.
SILKSCREEN PARTITION
PIN 1 INDICATOR
It is required that the exposed paddle on the underside of the
ADC is connected to analog ground (AGND) to achieve the
best electrical and thermal performance of the AD9271. An
Rev. PrA | Page 41 of 58
06304-069
Exposed Paddle Thermal Heat Slug Recommendations
Figure 64. Typical PCB Layout
AD9271
Preliminary Technical Data
EVALUATION BOARD
is needed in addition to the other supplies. The 3.3 V supply, or
AVDD_3.3 V, should have a 1 A current capability.
The AD9271 evaluation board provides all of the support circuitry
required to operate the ADC in its various modes and configurations. The LNA is driven differentially through a transformer.
Figure 65 shows the typical bench characterization setup used
to evaluate the ac performance of the AD9271. It is critical that
the signal sources used for the analog input and clock have very
low phase noise (<1 ps rms jitter) to realize the optimum
performance of the signal chain. Proper filtering of the analog
input signal
to remove harmonics and lower the integrated or broadband
noise at the input is also necessary to achieve the specified noise
performance.
To bias the crosspoint switch circuitry or CW section, separate
+5 V and −5 V supplies are required. These should have 1 A
current capability each. This section cannot be biased from a
6 V, 2 A wall supply. Separate supplies are required.
INPUT SIGNALS
When connecting the clock and analog source, use clean signal
generators with low phase noise, such as Rohde & Schwarz SMHU
or HP8644 signal generators or the equivalent. Use a 1 m, shielded,
RG-58, 50 Ω coaxial cable for making connections to the evaluation board. Enter the desired frequency and amplitude from the
specifications tables. The evaluation board is set up to be clocked
from the crystal oscillator, OSC401. If a different or external clock
source is desired, follow the instructions for CLOCK outlined in
the Default Operation and Jumper Selection Settings section.
Typically, most Analog Devices evaluation boards can accept
~2.8 V p-p or 13 dBm sine wave input for the clock. When
connecting the analog input source, it is recommended to use a
multipole, narrow-band, band-pass filter with 50 Ω
terminations. Analog Devices uses TTE and K&L Microwave,
Inc., band-pass filters. The filter should be connected directly to
the evaluation board.
See Figure x to Figure x for the complete schematics and layout
diagrams that demonstrate the routing and grounding techniques
that should be applied at the system level.
POWER SUPPLIES
This evaluation board comes with a wall-mountable switching
power supply that provides a 6 V, 2 A maximum output. Simply
connect the supply to the rated 100 V ac to 240 V ac wall outlet
at 47 Hz to 63 Hz. The other end is a 2.1 mm inner diameter
jack that connects to the PCB at P701. Once on the PC board,
the 6 V supply is fused and conditioned before connecting to
three low dropout linear regulators that supply the proper bias
to each of the various sections on the board.
OUTPUT SIGNALS
The default setup uses the HSC-ADC-FPGA-8 high speed
deserialization board to deserialize the digital output data and
convert it to parallel CMOS. These two channels interface
directly with the Analog Devices standard dual-channel FIFO
data capture board (HSC-ADC-EVALB-DC). Two of the eight
channels can then be evaluated at the same time. For more
information on channel settings on these boards and their
optional settings, visit www.analog.com/FIFO.
When operating the evaluation board in a nondefault condition,
L702 to L704 can be removed to disconnect the switching
power supply. This enables the user to bias each section of the
board individually. Use P501 to connect a different supply for
each section. At least one 1.8 V supply is needed with a 1 A current
capability for AVDD_DUT and DRVDD_DUT; however, it is
recommended that separate supplies be used for both analog
and digital domains. To operate the evaluation board using the
SPI and alternate clock options, a separate 3.3 V analog supply
WALL OUTLET
100V TO 240V AC
47Hz TO 63Hz
VFAC3
OSCILLATOR CLK
–
+
–
+
–
+
AVDD_3.3V
GND
3.3V_D
GND
1.5V_FPGA
GND
VCC
3.3V
+
AD9271
CW OUTPUT
1.5V
–
CHA TO CHH
12-BIT
SERIAL
LVDS
EVALUATION BOARD
HSC-ADC-FPGA-8
HIGH SPEED
DESERIALIZATION
BOARD 2 CH
SPI
Figure 65. Evaluation Board Connection
Rev. PrA | Page 42 of 58
12-BIT
PARALLEL
CMOS
SPI
HSC-ADC-EVALB-DC
FIFO DATA
CAPTURE
BOARD
USB
CONNECTION
SPI
PC
RUNNING
ADC
ANALYZER
AND SPI
USER
SOFTWARE
SPI
06304-070
ROHDE & SCHWARZ,
FS5A20
SPECTRUM
ANALYZER
BAND-PASS
FILTER
3.3V
3.3V
+
GND
ANALOG INPUT
ROHDE & SCHWARZ,
SMHU,
2V p-p SIGNAL
SYNTHESIZER
1.8V
–
DRVDD_DUT
1.8V
+
GND
–
GND
SWITCHING
POWER
SUPPLY
AVDD_DUT
6V DC
2A MAX
Preliminary Technical Data
AD9271
The evaluation board is already set up to be clocked from the
crystal oscillator, OSC401. This oscillator is a low phase noise
oscillator from Valpey Fisher (VFAC3-BHL-50MHz). If a
different clock source is desired, remove R403, set Jumper
J401 to disable the oscillator from running, and connect the
external clock source to the SMA connector, P401.
DEFAULT OPERATION AND JUMPER SELECTION
SETTINGS
The following is a list of the default and optional settings or
modes allowed on the AD9271 Rev. A evaluation board.
•
•
POWER: Connect the switching power supply that is
supplied in the evaluation kit between a rated 100 V ac
to 240 V ac wall outlet at 47 Hz to 63 Hz and P701.
AIN: The evaluation board is set up for a transformercoupled analog input with optimum 50 Ω impedance
matching out to 18 MHz (see Figure 66). For a different
bandwidth response, change the 22 pF capacitor at the
LNA (LI-x) analog input.
Figure 66. Evaluation Board Full Power Bandwidth
•
A differential LVPECL clock driver can also be used to
clock the ADC input using the AD9515 (U401). Populate
R406 and R407 with 0 Ω resistors and remove R415 and
R416 to disconnect the default clock path inputs. In addition,
populate C405 and C406 with a 0.1 μF capacitor and remove
C409 and C410 to disconnect the default cloth path outputs.
The AD9515 has many pin-strappable options that are set
to a default mode of operation. Consult the AD9515 data
sheet for more information about these and other options.
VREF: VREF is set to 1.0 V by tying the SENSE pin to
ground, R317. This causes the ADC to operate in 2.0 V p-p
full-scale range. A separate external reference option using
the ADR510 or ADR520 is also included on the evaluation
board. Populate R311 and R315 with 0 Ω resistors and
remove C307. Proper use of the VREF options is noted in
the Voltage Reference section.
•
RBIAS: RBIAS has a default setting of 10 kΩ (R301) to
ground and is used to set the ADC core bias current. To
further lower the core power (excluding the LVDS driver
supply), change the resistor setting. However, performance
of the ADC may degrade depending on the resistor chosen.
See RBIAS section for more information.
•
CLOCK: The default clock input circuitry is derived from a
simple transformer-coupled circuit using a high bandwidth
1:1 impedance ratio transformer (T401) that adds a very
low amount of jitter to the clock path. The clock input is
50 Ω terminated and ac-coupled to handle single-ended
sine wave types of inputs. The transformer converts the
single-ended input to a differential signal that is clipped
before entering the ADC clock inputs.
•
PDWN: To enable the power-down feature, short P303 to
the on position (AVDD) on the PDWN pin.
•
STDBY: To enable the standby feature, simply short P302
to the on position (AVDD) on the STDBY pin.
•
GAIN: To change the gain on the VGA, drive these pins
from 0 V to 1 V on J301. This changes the VGA gain from
0 dB to 30 dB. This feature can also be driven from the
R335 and R336 on-board resistive dividers by installing a
0 Ω resistor in R337.
•
Non-SPI Mode: For users who wish to operate the DUT
without using SPI, remove the jumpers on J501. This
disconnects the CSB, SCLK, and SDIO pins from the control
bus, allowing the DUT to operate in its simplest mode. Each
of these pins has internal termination and will float to its
respective level. Note that the device will only work in its
default condition.
•
CWD+,CWD−: To view muiltple CW outputs, jumper
together the appropriate outputs on P403 and P404. All
outputs are summed together on IOP and ION buses, fed
to a 1:4 impedance ratio transformer, and buffered so that
the user can view the output on a spectrum analyzer. This
can be configured to be viewed in single-ended mode
(default) or in differential mode. To set the voltage for the
appropriate number of channels to be summed, change the
value of R447 and R448 on the primary transformer
(T402).
•
D+, D−: If an alternative data capture method to the setup
described in Figure 67 is used, optional receiver terminations,
R318, R320 to R330, can be installed next to the high speed
backplane connector.
Rev. PrA | Page 43 of 58
Rev. PrA | Page 44 of 58
AIN CHB
AIN CHA
R104
0-DNP
J102
R150
0-DNP
J101
Figure 67. Evaluation Board Schematic, DUT Analog Inputs
R112
0-DNP
R138
0-DNP
R110
50-DN
P
R137
0-DNP
R149
0-DNP
R101
50-DN
P
C118
0.1UF-DN
P
GNDB
CT B
0-DNP
R111
C117
0.1UF-DN
P
GND A
CT A
0
R102
T10 1
1
T10 2
R143
10K-DN
P
0-DNP
0-DNP
R155
R151
0
6
2
4
CTB
R154 CT A
R130
0
6
R144
10K-DN
P
AVDD_DU T
3
5
4
2
R142
10K-DN
P
ADT1-1W T
R141
10K-DN
P
AVDD_DU T
3
5
1
ADT1-1W T
1
R159
50
1
R158
50
0.1UF
C105
0.1UF
C122
0.1UF
C101
0.1UF
C121
0.1UF
C107
0
R115
C106
2 2 PF
0
R106
C102
2 2 PF
0.1UF
R107
200
R117
R118
0-DNP
0.1UF-DN
P
C108
R116
1K-DNP
R109
0-DNP
C104
0.1UF-DN
P
200
R108
1K-DNP
LGB
LIB
LOSW B
LO- B
LGA
LIA
LOSW A
LO- A
AIN CHD
AIN CHC
R122
0-DNP
J104
R113
0-DNP
J103
R131
0-DNP
R140
0-DNP
R128
50-DN
P
R121
0-DNP
R139
0-DNP
R119
50-DN
P
C120
0.1UF-DN
P
GND D
CTD
0-DNP
R129
C119
0.1UF-DN
P
GNDC
CT C
0-DNP
R103
T10 3
1
T10 4
R147
10K-DN
P
0-DNP
R157
R153
0
6
2
4
10K-DN
P
R148
AVDD_DU T
3
5
0-DNP
R156
R152
0
6
2
4
R146
10K-DN
P
ADT1-1W T
R145
10K-DN
P
AVDD_DU T
3
5
1
ADT1-1W T
CTD
CTC
1
R161
50
1
R160
50
0.1UF
C113
0.1UF
C124
0.1UF
C109
0.1UF
C123
C114
2 2 PF
0.1UF
C115
0
R133
0
R124
C110
2 2 PF
0.1UF
C111
R125
R134
R136
0-DNP
0.1UF-DN
P
C116
200
R135
1K-DNP
R127
0-DNP
C112
0.1UF-DN
P
200
R126
1K-DNP
LGD
LID
LOSW D
LO- D
LGC
LI C
LOSW C
LO- C
06304-086
C103
AD9271
Preliminary Technical Data
Rev. PrA | Page 45 of 58
AIN CHF
AIN CHE
R222
0-DNP
J202
R212
0-DNP
J201
Figure 68. Evaluation Board Schematic, DUT Analog Inputs (Continued)
R230
0-DNP
R238
0-DNP
R210
50-DN
P
R221
0-DNP
R203
0-DNP
R201
50-DN
P
C218
0.1UF-DN
P
GND F
CTF
0-DNP
R211
C217
0.1UF-DN
P
GNDE
CTE
0-DNP
R202
4
0-DNP
R254
T202
4
2
6
R244
10K-DN
P
R204
10K-DN
P
CTF
CTE
R255
0-DNP
AVDD_DU T
R250
0
ADT1-1W T
1
5
3
R243
10K-DN
P
R242
10K-DN
P
AVDD_DU T
R249
0
ADT1-1W T
1
6
2
3
5
T201
1
1
R259
50
R258
50
0.1UF
C205
0.1UF
C222
0.1UF
C201
0.1UF
C221
0.1UF
C207
0
R215
C206
2 2 PF
0
R206
C202
2 2 PF
0.1UF
R207
200
R217
R218
0-DNP
0.1UF-DN
P
C208
R216
1K-DNP
R209
0-DNP
C204
0.1UF-DN
P
200
R208
1K-DNP
LGF
LIF
LOSW F
LO- F
LGE
LIE
LOSW E
LO- E
AIN CHH
AIN CHG
R241
0-DNP
J204
R231
0-DNP
J203
R253
0-DNP
R240
0-DNP
R228
50-DN
P
R237
0-DNP
R239
0-DNP
R219
50-DN
P
C220
0.1UF-DN
P
GND H
CTH
0-DNP
R229
C219
0.1UF-DN
P
GNDG
CTG
0-DNP
R213
T203
4
2
6
R256
0-DNP
T204
4
2
6
R257
0-DNP
R248
10K-DN
P
R247
10K-DN
P
AVDD_DU T
R252
0
ADT1-1W T
1
5
3
R246
10K-DN
P
R245
10K-DN
P
AVDD_DU T
R251
0
ADT1-1W T
1
5
3
CTH
CTG
1
1
R261
50
R260
50
0.1UF
C213
0.1UF
C224
0.1UF
C209
0.1UF
C223
0.1UF
C215
0
R233
C214
2 2 PF
0
R224
C210
2 2 PF
0.1UF
C211
R225
200
R235
R236
0-DNP
0.1UF-DN
P
C216
R234
1K-DNP
R227
0-DNP
C212
0.1UF-DN
P
200
R226
1K-DNP
LGH
LIH
LOSW H
LO- H
LGG
LIG
LOSW G
LO- G
06304-087
C203
Preliminary Technical Data
AD9271
AVDD_DU T
CLK
CLK
AVDD_CH H
LGH
LIH
LOSW H
LO- H
AVDD_CH G
LGG
LIG
LOSW G
LO-G
AVDD_CHF
LGF
LIF
LOSW F
LO- F
AVDD_CH E
LGE
LIE
25
24
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
U301
CVDD
CLK +
CLK -
AVDDH
AVDDH
LGH
LIH
LOSW H
LO- H
AVDD G
AVDD G
LGG
LIG
LOSW G
LO-G
AVDDF
AVDDF
LGF
LIF
LOSW F
LO- F
AVDD E
AVDD E
LGE
LIE
10 1
PAD
LOSW E
10 0
LOSW E
DRVD D
26
DRVDD_DU T
LO- E
99
LO-E
D-H
27
CH H
CWD5+
28
CWD5 97
CWD5 D-G
98
CWD5+
D+H
CH H
29
CHG
CWD4+
96
CWD4+
D+G
30
CHG
CWD4 95
CWD4 D-F
31
CH F
CWD3+
94
CWD3+
0-DN P
AVDD_3.3 V
AVDD_DUT
0.1U F
CWD3 -
AD9271
0.1UF
C309
CWD2 -
P302
AVDD_DU T
C308
0.1UF
CWD1 -
R30 5
CWD2+
2
1
R32 5
1K
BERG69157-10 2
10 0
R30 3
LOSW D
AVDD_DU T
R32 6
1K
AVDD D
LGD
LID
J301
P303
SCL K
SDIO
CSB
AVDD A
AVDD A
LGA
LIA
LOSW A
LO-A
AVDD B
AVDD B
LGB
LIB
LOSW B
LO-B
AVDD C
AVDD C
LGC
LIC
LOSW C
LO- C
AVDD D
BERG69157-10 2
2
1
R304
100-DNP
GGND
50
R30 2
GAIN DRIVE INPUT
CWD0+
Referenc e
Decoupling
VREF_DU T
FCO-
93
CWD3 33
D+F
32
CH F
D-E
CHE
10K
D+D
92
RAVD D
91
REF T
DCO 35
DC O
D+E
90
REFB
89
VREF
88
38
DCO +
36
DC O
37
FCO
FCO+
FCO
D-D
39
CHD
40
CHD
D-C
41
CH C
34
CHE
RBIA S
87
VSENSE_DU T
R30 1
SENS E
86
GAIN +
85
GAIN -
84
CWVDD
D+ C
42
CH C
83
CWD2+
D-B
43
CH B
82
CWD2 -
CWD1+
45
D+ B
44
CH B
81
CWD1+
80
46
D-A
CH A
CWD1 D+ A
79
CWD0+
DRVD D
47
LO-D
77
LO-D
76
LOSW D
CWD0 78
CWD0 STDBY
48
Rev. PrA | Page 46 of 58
CH A
Figure 69. Evaluation Board Schematic, DUT, VREF, and Digital Output Interface
DRVDD_DU T
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
R31 9
1K
0-DN P
R33 7
AVDD_DU T
SCLK_DU T
SDIO_DU T
CSB_DUT
R33 8
10 K
AVDD_DU T
AVDD_CHA
LGA
LIA
LOSW A
LO-A
AVDD_CHB
LGB
LIB
LOSW B
LO-B
AVDD_CHC
LGC
LIC
LOSW C
LO- C
AVDD_CH D
LGD
LID
R331
100-DNP
IN
CW
C303
0.1U F
PWDN
C30 1
DVDD
C302
4.7UF
49
C304
0.1U F
AVDD_DUT
8K
U30 2
470K-DN
P
AD R510_2
1V
OPTIONAL
EXT REF
TRIM/NC
R30 8
R336
10K
0
0.1UF
C30 5
VOU T
AVDD_DU T
B
B
B
CSB3 _ CH
CSB4 _ CH
SD O_ CH
60
C6
A5
1A 1
21
A2
2
22
A3
3
23
A4
4
24
5
25
A6
6
26
A7
7
27
A8
8
28
A9
9
29
A1 0
10
30
C1
31
51
C2
32
52
C3
33
53
3 4C 4
54
35
C5
55
36
56
C7
37
57
3 8C 8
58
C9
39
59
C1 0
40
1
2
3
4
5
6
7
8
9
GNDAB 1
GNDAB 2
GNDAB 3
GNDAB 4
GNDAB 5
GNDAB 6
GNDAB 7
GNDAB 8
GNDAB 9
GNDAB1
GNDCD
GNDCD
GNDCD
GNDCD
GNDCD
GNDCD
GNDCD
GNDCD
GNDCD
GNDCD1
0
0
R31 1
0-DN P
45
46
47
16
17
18
19
20
41
42
43
12
13
14
T
ext ern al
Remove
u s in g
Vre f
wh e n
DN P
R31 7
0
R31 6
DN P
R31 5
DN P
Vref Sel ec t
SDO_CH A
CSB2_CH A
CSB1_CH A
SDI_CHA
1U F
R31 3
R324
100-DNP
R327
100-DNP
R328
100-DNP
R329
100-DNP
R330
100-DNP
R323
100-DNP
R322
100-DNP
R321
100-DNP
R320
100-DNP
R318
100-DNP
SCLK_CH A
CHH
CHG
CHF
CHE
CH D
CH C
CH B
C30 7
VREF_DU
B 11 1
B2
B3
B4
B 51 5
B6
B7
B8
B9
B1 0
D1
D2
D3
D 44 4
D5
D6
D7
CH A
FC O
DC O
s
0
Ou t pu t
Opti on al
Termi n ati on
R205-R21
0.1UF
C3 0 7
49
50
D 84 8
D9
D1 0
T
C30 6
DN P
R31 2
ReferenceCircuitry
B
SDI_ CH
R310
10K-DN P
R30 9
1K
NC
B
SCLK_CH
CHH
CHG
CHF
CHE
CH D
CH C
CH B
CH A
FC O
DC O
P3 0 1
Digital Outputs
Vref=1 V
)
VSENSE_DU
= E xt ern a l
Vref=0.5V(1+R313/R312
Vref
T
06304-088
R33 5
AVDD_DU
50
AD9271
Preliminary Technical Data
CW
G ND
Figure 70. Evaluation Board Schematic, Clock and CW Doppler Circuitry
Enc
Clock Circuit
Enc
Inpu t
Encod e
P401
DN P
10
12
P402
AVDD_3.3V
ION
C401
0.1UF
OE
50
R40 4
0
R40 3
OUT GND
VCC
R40 5
0
C40 3
0.1UF
0.1UF
C40 2
5
3
AVDD _3.3 V
0
R44 6
Optional Clock
Oscillator
AVDD_3.3V
IOP
1
6
5
4
OPT_CLK
0
R416
0
R41 5
OPT_CLK
OPT_CLK
ENABLEOSC201
R40 8
DN P
0
C411
0.1UF
ADT1-1WT
1
4
2
6
10 K
T401
R41 3
R40 9
DN P
R41 2
3
5
75 0
R45 3
R41 1
50-DN P
0
R417
R418
0
R41 0
10 K
C421
0.1UF
AVDD_3.3V
R46 6
0-DN P
DN P
0-DNP
R407
0-DNP
R406
R44 9
0-DN P
50
R45 5
C419
0.1UF
-5V
CWD2
R45 0
0
0
R45 2
0
R45 1
R46 2
0-DN P
R46 5
1
2
3
CWD1
ADTT4-1
T402
3
DISABLEOSC201
OPT_CLK
R40 2
10 K
R40 1
10 K
R44 8
12 5
R44 7
12 5
R46 0
0-DN P
CWD1
SYNCB
CLKB
CLK
1
5
3
2
U401
R41 4
4.12 K
R46 4
0-DN P
R46 1
0-DN P
GND_PAD
S9
S8
SIGNAL=DNC;27,28
SIGNAL=AVDD_3.3V;4,17,20,21,24,26,29,3
0
S10
R46 3
0-DN P
CWD0+
CWD1+
CWD2+
CWD3+
CWD4+
CWD5+
CWD2
AOUT
C422
0.1UF
J403
S7
S6
S5
S4
S3
S2
S1
OUT1B
OUT1
OUT0B
OUT0
S0
0.1UF
C409
C410
0.1UF
18
19
22
23
R42 0
24 0
OPTIONAL CLOCK DRIVE CIRCUIT
75 0
R45 4
+5V
AD9515
AVDD_3.3V
AD812AR
C420
0.1UF
50
R45 8
31
R45 9
0-DN P
1
J402
32
RSET
33
AOUT
VREF
6
S9
8
S10
7
VS
S8
9
S7
10
S0
GND
S6
11
S5
12
S4
13
S3
14
S2
15
S1
16
Rev. PrA | Page 47 of 58
25
CW DOPPLER CIRCUITRY
0.1UF-DN P
C40 8
0.1UF-DN P
C40 7
0.1UF-DN P
C40 6
0.1UF-DN P
C40 5
12
11
10
9
8
7
CLK
LVDSOUTPUT
CLK
LVPECLOUTPUT
CLK
CWD0-
CWD1-
CWD2-
C412
0.1UF
C413
0.1UF
S5
AVDD_3.3V
S4
AVDD_3.3V
S3
AVDD_3.3V
S2
AVDD_3.3V
S1
AVDD_3.3V
S0
AVDD_3.3V
AVDD_3.3V
12
11
10
9
8
7
6
5
4
6
CWD3-
3
CWD4-
4
5
3
2
1
CWD5-
P403
2
1
ION
P404
CLIPSINEOUT(DEFAULT
)
CLK
R42 3
10 0
R42 1
24 0
R42 2
10 0
IOP
C414
0.1UF
DNP
R434
DNP
R432
DNP
R430
DNP
R428
DNP
R426
DNP
R424
C415
0.1UF
0
0
0
0
0
0
C416
0.1UF
R435
R433
R431
R429
R427
R425
0
0
0
0
0
0
C417
0.1UF
C418
0.1UF
S10
AVDD_3.3V
S9
AVDD_3.3V
S8
AVDD_3.3V
S7
AVDD_3.3V
S6
AVDD_3.3V
DNP
R444
DNP
R442
DNP
R440
DNP
R438
R436
0
0
0
0
0
R445
R443
R441
R439
DNP
R437
AD9515 Pin-strap setting s
0
0
0
0
0
Preliminary Technical Data
AD9271
06304-089
U70 4
ADP33339AKC-1.
ADP33339AKC-1.
3
INPUT
DNP: DO NOT POPULAT E
C71 6
1U F
PWR_OU T
1U F
C71 4
PWR_OU T
U70 7
3
INPUT
8
8
R71 5
10 K
2
OUTPUT1
OUTPUT4
SCLK_CHA
2
OUTPUT1
OUTPUT4
10 K
R71 4
SDI_CHA
R71 1
10 K
Y2 4
3A2
DUT_ DRVD D
1U F
4
C71 9
C71 7
1U F
CSB_DUT
AVDD_DUT
SCLK_DUT
AVDD_DUT
PWR_ I N
1K
ADP33339AKC-3.
3
INPUT
U70 5
1K
R71 0
AVDD_3.3V
AVDD_DUT
R71 3
1U F
L70 6
10U H
D UT_AVD D
Y2 4
3A2
L70 5
10U H
5
VCC
2
GND
U703
Y1 6
NC7WZ1 6
1A1
1K
R71 2
C71 5
4
5
VCC
2
GND
U702
Y1 6
NC7WZ0 7
C702
C703
1A1
SDIO_DUT
0.1UF
0.1UF
SDO_CHA
SPI CIRCUITRY FROM FIFO
CSB1_CHA
GND
1
GND
Figure 71. Evaluation Board Schematic, Power Supply Inputs and SPI Interface Circuitry
1
Rev. PrA | Page 48 of 58
3
GND
1
3
2
2
OUTPUT1
OUTPUT4
1U F
C72 0
4
WEILANDZ5.531.3325.0
3
2
1
P511
+/- 5V Power
Inpu t
7.5VPOWE
R
CON00
5
2.5MMJACK
P7 0 1
10UF
C704
C50 3
10U F
C50 1
10U F
SMDC110F
F701
GN D Test Point s
L50 2
10U H
L50 1
10U H
Power Supply Inpu t
6V, 2A ma x
1
1
1
1
L70 7
10U H
3.3V_AVD D
1
1
1
1
D701
AVDD_3.3V
3 PSG
C73 1
0.1UF
C74 1
0.1UF
0.1UF
C75 1
0.1UF
0.1UF
C74 6
DRVDD_DU
0.1UF
C74 7
AVDD_DUT
CG 6
CG 5
CG 4
CB 2
T
0.1UF
L70 4
10U H
10U H
L70 2
L70 3
10U H
C74 3
0.1UF
C74 2
0.1UF
C73 5
0.1UF
AVDD_ CH C
C74 8
C73 4
0.1UF
AVD D_ CH D
C73 3
0.1UF
AVDD _ CH E
C73 2
0.1UF
AVDD_ CH F
C74 5
AVDD _ CH A
C74 0
0.1UF
0.1UF
C74 4
AVDD_ CH B
0.1UF
DUT_ DRVD D
DUT_AVD D
6
Decoupling Capacitor s
AVDD_ CH G
6
5
4
3
2
P501
1
3.3V_AVDD
FLTHMURATABNX01
Optional Powe r
Inpu t
C73 0
AVDD_ CH H
C50 4
0.1UF
-5 V
C50 2
0.1UF
+5 V
2A
L70 1
1 BIAS
PWR_IN
AVD D _3.3 V
C71 2
0.1UF
DRVDD_DU
C70 8
0.1UF
T
AVDD_DU T
+1.8 V
+1.8 V
+3.3 V
AVDD_CHH
AVDD_CHG
AVDD_CHF
AVDD_CHE
AVDD_CHD
AVDD_CHC
AVDD_CHB
AVDD_CHA
AVDD_DUT
2A
2A
2A
C71 0
0.1UF
R71 6
24 0
D705
D704
D703
10U F
GREEN
C71 1
C70 7
10U F
C70 9
10U F
2A
D702
CR702
1
2
1
P502
BERG69157-102
2
1
P509
BERG69157-102
2
1
P508
BERG69157-102
2
1
P507
BERG69157-102
2
1
P506
BERG69157-102
2
1
P505
BERG69157-102
2
1
P504
BERG69157-102
2
1
P503
BERG69157-102
PWR_OUT
AD9271
Preliminary Technical Data
06304-090
AD9271
06304-081
Preliminary Technical Data
06304-082
Figure 72. Evaluation Board Layout, Top Side
Figure 73. Evaluation Board Layout, Ground Plane (Layer 2)
Rev. PrA | Page 49 of 58
Preliminary Technical Data
06304-083
AD9271
06304-084
Figure 74. Evaluation Board Layout, Power Plane (Layer 3)
Figure 75. Evaluation Board Layout, Power Plane (Layer4)
Rev. PrA | Page 50 of 58
AD9271
06304-085
Preliminary Technical Data
06304-080
Figure 76. Evaluation Board Layout, Ground Plane (Layer 5)
Figure 77. Evaluation Board Layout, Bottom Side
Rev. PrA | Page 51 of 58
AD9271
Preliminary Technical Data
Table 17. Evaluation Board Bill of Materials (BOM)1
Item
1
2
Qnty.
per
Board
1
REFDES
AD9271BSVZ_REVC
Device
PCB
Pkg.
PCB
Value
PCB
Mfg.
Mfg. Part Number
71
C101, C103, C105,
C107, C109, C111,
C113, C115, C121 to
C124, C201, C203,
C205, C207, C209,
C211, C213, C215,
C221 to C224, C301,
C303 to C306, C308
to C309, C401 to
C403, C409 to C422,
C502, C504, C702 to
C703, C708, C710,
C712, C730 to C735,
C740 to C748, C751
Capacitor
C0402
0.1 μF 10 V
ceramic X5R
0402
Panasonic
ECJ-0EB1A104K
3
8
C102, C106, C110,
C114, C202, C206,
C210, C214
Capacitor
C0402
Ceramic 22 pF
5% 50 V NP0
0402
AVX
04025A220JAT2A
4
1
C302
Capacitor
C0603
Ceramic 4.7 μF
6.3 V X5R 0603
AVX
C0603C475K9PACTU
5
7
C307, C714 to C717,
C719 to C720
Capacitor
C0603
1 μF 6.3 V ceramic
X5R 0603
Panasonic
ECJ-1VB0J105K
6
5
C501, C503, C707,
C709, C711
Capacitor
C0603
Ceramic 10 μF
6.3 V X5R 0603
Panasonic
ECJ-1VB0J106M
7
1
C704
Capacitor
C6032
10 μF, 6032-28,
tantalum, 16 V,
10% tol
Kemet
T491C106K016AS
8
1
CR401
Diode
SOT23
Schottky
GP LN 20 mA
AVAGO (Agilent)
HSMS-2812-TR1G
9
1
CR702
LED
LED0603
Green USS
Type 0603 4 V,
5 m candela
Panasonic
LNJ314G8TRA
10
5
D701 to 705
Diode
SMBJ
Rectifier SIL 2 A
50 V DO-214AA
Micro
Commercial Co.
S2A-TP
11
1
F701
Fuse
Polyswitch 1.10
A reset fuse SMD
Tyco/Raychem
NANOSMDC110F-2
12
13
J101 to J104, J201
to J204, J301, J402
to J403, P401 to
P402
Connector
CNSAMTEC-SMA-J-
CONN-PCB coax
SMA end launch
Samtec/Johnson
SMA-J-P-X-ST-EM1/
142-0711-821
13
1
J401
Connector
CNBERG1X3H205LD
Header, 3-pin,
male, single row,
straight
Samtec
TSW-103-08-G-S
14
1
J501
Connector
CNBERG2X4H350LD
Header, 8-pin,
male, double
row, straight
Samtec
TSW-105-08-T-D
Rev. PrA | Page 52 of 58
Preliminary Technical Data
Item
15
Qnty.
per
Board
AD9271
REFDES
Device
Pkg.
Value
Mfg.
Mfg. Part Number
10
P302 to P303,
P502 to P509
Connector
CNBERG69157-102
100 mil header
jumper, 2-pin
Samtec
TSW-102-07-G-S
16
2
P403 to P404
Connector
CNBERG2X6H330LD
100 mil header,
male, 2 × 6
double row
straight
Samtec
TSW-110-08-G-D/
TSW-106-08-G-D
17
8
L501 to L502,
L702 to L707
Ferrite Bead
L1210
Bead core
3.2 × 2.5 × 1.6
SMD 1210, 10 μH
Panasonic
EXC-CL3225U1
18
1
L701
Choke coil
Filter, BNX016-01,
EMIFIL LC block
Murata
BNX016-01
19
1
OSC401
Oscillator
Crystal, dual
footprint, see eng
Valpey Fisher
VFAC3-BHL-50MHz
20
1
P301
Connector
Header, right
angle, 2-pair,
25 mm, header
assembly
Tyco/AMP
6469169-1
21
1
P701
Connector
0.08", PCMT
DC power,
PC mount
Switchcraft
RAPC722X
23
38
R102, R103, R106,
R111, R115, R124,
R129, R130, R133,
R151, R152, R153,
R202, R206, R211,
R213, R215, R224,
R229, R233, R249
R252, R305, R317,
R403, R405, R415 to
R418, R446, R450 to
R452, R465, R466
Resistor
R0402
0 Ω 1/16 W 5%
0402 SMD
Panasonic
ERJ-2GE0R00X
24
8
R108, R117, R126,
R135, R208, R217,
R226, R235
Resistor
R0402
200 Ω 1/16 W
0.5% 0402 SMD
Yageo America
RR0510P-201-D
25
12
R158 to R161, R258
to R261, R302, R404,
R455, R458
Resistor
R0402
49.9 Ω 1/16 W
0.5% 0402 SMD
Susumu Co.
RR0510R-49R9-D
26
9
R301, R338, R401 to
R402, R410, R413,
R711, R714 to R715
Resistor
R0402
10 kΩ 1/16 W
5% 0402 SMD
Panasonic
ERJ-2GEJ103X
27
3
R303, R422 to R423
Resistor
R0402
100 Ω 1/16 W
1% 0402 SMD
Panasonic
ERJ-2RKF1000V
28
1
R308
Resistor
R0402
470 kΩ 1/16 W
5% 0402 SMD
Panasonic
RC0402JR-07470KL
29
7
R309, R319, R325,
R326, R710, R712,
R713
Resistor
R0402
1.00 kΩ 1/16 W
1% 0402 SMD
Panasonic
ERJ-2RKF1001X
30
1
R335
Resistor
R0402
8.06 kΩ 1/16 W
1% 0402 SMD
Yageo
RC0402FR-078K06L
OSC14P4_CB3
Rev. PrA | Page 53 of 58
AD9271
Preliminary Technical Data
Qnty.
per
Board
REFDES
Device
Pkg.
Value
Mfg.
Mfg. Part Number
2
R310, R336
Potentiometer
3-lead
10 kΩ, one
turn, SMT
Murata
PVA2A103A01R00
32
1
R414
Resistor
R0402
4.12 kΩ 1/16 W
1% 0402 SMD
Panasonic
ERJ-2RKF4121X
33
3
R420 to R421, R716
Resistor
R0402
Thick film, SMT
0402, 240
34
11
R424, R427, R429,
R431, R433, R435 to
R436, R439, R441,
R443, R445
Resistor
R0201
0.0 Ω 1/20 W
5% 0201 SMD
Panasonic
ERJ-1GE0R00C
35
2
R447 to R448
Resistor
R0402
124 Ω 1/16 W
0.1% 0402 SMD
Susumu Co.
RG10P124BCT-ND
36
2
R453 to R454
Resistor
R0402
750 Ω 1/16 W
0.1% 0402 SMD
Susumu Co.
RG10P750BCT-ND
37
9
T101 to T104, T201
to T204, T401
Transformer
MINICD542
XFMR RF
Mini Circuits
ADT1-1WT
38
1
T402
Transformer
MINICKCD637
ADTT4-1, CD542
Mini Circuits
ADTT4-1
39
1
U301
IC
SV-100-3
Octal LNA/
VGA/AAF/ADC
Analog Devices
AD9271BSVZ
40
1
U302
IC
SOT23
ADR510, 1.0 V
precision low
noise shunt V REF
Analog Devices
ADR510
41
1
U401
IC
LFCSP32-5X5-LP
AD9515, CLK
DIST, 32 LFCSP,
5 × 5 mm
Analog Devices
AD9515
42
1
U402
IC
SO8
AD812AR,
dual, current
feedback
op amp, SO8
Analog Devices
AD812AR
43
1
U702
IC
SC88
NC7WZ07,
dual buffer, SC88
Fairchild
NC7WZ07P6X_NL
44
1
U703
IC
SC88
NC7WZ16P6X,
UHS dual buffer,
SC88
Fairchild
NC7WZ16P6X_NL
45
2
U704, U707
IC
SOT223-2
Regulator,
high accuracy,
ADP3339AKC-1.8,
1.8 V
Analog Devices
ADP3339AKC-1-8
46
1
U705
IC
SOT223-2
Regulator,
high accuracy,
ADP3339AKC-3.3,
3.3 V
Analog Devices
ADP3339AKC-3-3
Item
31
Rev. PrA | Page 54 of 58
Preliminary Technical Data
Item
47
48
1
AD9271
Qnty.
per
Board
REFDES
Device
Pkg.
Value
Mfg.
Mfg. Part Number
4
MP101 to MP104
Assembly
Insert into
four large holes
on corners of
board from the
bottom side
CBSB-14-01,
7/8" height,
standoffs for
circuit board
support, no
adhesive
Richco
CBSB-14-01
6
MP105 to MP108
Assembly
Place into
J502-509
SNT-100-BK-G-H,
100 mil jumpers
Samtec
SNT-100-BK-G-H
This BOM is RoHS compliant.
Rev. PrA | Page 55 of 58
AD9271
Preliminary Technical Data
OUTLINE DIMENSIONS
0.75
0.60
0.45
16.00 BSC SQ
1.20
MAX
14.00 BSC SQ
100
1
76
75
76
75
100
1
PIN 1
EXPOSED
PAD
TOP VIEW
(PINS DOWN)
0° MIN
1.05
1.00
0.95
0.15
0.05
SEATING
PLANE
0.20
0.09
7°
3.5°
0°
0.08 MAX
COPLANARITY
25
26
51
50
BOTTOM VIEW
(PINS UP)
51
25
50
26
0.50 BSC
LEAD PITCH
VIEW A
9.50 SQ
0.27
0.22
0.17
VIEW A
ROTATED 90° CCW
080706-A
COMPLIANT TO JEDEC STANDARDS MS-026-AED-HD
NOTES:
THE PACKAGE HAS A CONDUCTIVE HEAT SLUG TO HELP DISSIPATE HEAT AND ENSURE RELIABLE OPERATION OF
THE DEVICE OVER THE FULL INDUSTRIAL TEMPERATURE RANGE. THE SLUG IS EXPOSED ON THE BOTTOM OF
THE PACKAGE AND ELECTRICALLY CONNECTED TO CHIP GROUND. IT IS RECOMMENDED THAT NO PCB SIGNAL
TRACES OR VIAS BE LOCATED UNDER THE PACKAGE THAT COULD COME IN CONTACT WITH THE CONDUCTIVE
SLUG. ATTACHING THE SLUG TO A GROUND PLANE WILL REDUCE THE JUNCTION TEMPERATURE OF THE
DEVICE WHICH MAY BE BENEFICIAL IN HIGH TEMPERATURE ENVIRONMENTS.
Figure 78. 100-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
(SV-100-3)
Dimensions shown in millimeters
ORDERING GUIDE
Model
AD9271BSVZ-501
AD9271BSVZRL7-501
AD9271BSVZ-401
AD9271BSVZRL7-401
AD9271BSVZ-251
AD9271BSVZRL7-251
AD9271-50EBZ1
1
Temperature
Range
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
−40°C to +85°C
Package Description
100-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
100-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP] Tape and Reel
100-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
100-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP] Tape and Reel
100-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP]
100-Lead Thin Quad Flat Package, Exposed Pad [TQFP_EP] Tape and Reel
Evaluation Board
Z = Pb-free part.
Rev. PrA | Page 56 of 58
Package
Option
SV-100-3
SV-100-3
SV-100-3
SV-100-3
SV-100-3
SV-100-3
Preliminary Technical Data
AD9271
NOTES
Rev. PrA | Page 57 of 58
AD9271
Preliminary Technical Data
NOTES
©2007 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
PR06304-0-3/07(PrA)
Rev. PrA | Page 58 of 58