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Evaluation Board User Guide
One Technology Way • P. O . Box 9106 • Norwood, MA 02062-9106, U.S.A. • Tel : 781.329.4700 • Fax : 781.461.3113 • www.analog.com
UG-016
Evaluating the AD9276 and AD9277 Octal LNA/VGA/AAF/12-/14-Bit ADCs
and CW I/Q Demodulators
FEATURES
Full featured evaluation board for the AD9276 and the
AD9277
SPI and alternate clock options
Internal and external reference options
VisualAnalog and SPI Controller software interfaces
EQUIPMENT NEEDED
Analog signal source and antialiasing filter
2 switching power supplies (6.0 V, 2.5 A) CUI EPS060250UH-
PHP-SZ, provided
Linear bench top dc voltage source (0 V to 1.6 V), not
required for CW Doppler mode
PC running Windows® 98 (2nd edition), Windows 2000,
Windows ME, or Windows XP
USB 2.0 port, recommended (USB 1.1 compatible)
AD9276 and AD9277 evaluation board
HSC-ADC-EVALCZ FPGA-based data capture kit
For CW Doppler mode: spectrum analyzer
DOCUMENTS NEEDED
AD9276 and AD9277 data sheets
TYPICAL MEASUREMENT SETUP
HSC-ADC-EVALCZ data sheet, High Speed Converter
Evaluation Platform (FPGA-based data capture kit)
AN-905 Application Note, VisualAnalog Converter Evaluation
Tool Version 1.0 User Manual
AN-878 Application Note, High Speed ADC SPI Control Software
AN-877 Application Note, Interface to High Speed ADCs via SPI
SOFTWARE NEEDED
VisualAnalog
SPI Controller
GENERAL DESCRIPTION
This document describes the evaluation board for the AD9276
and AD9277, which provides all of the support circuitry required
to operate the AD9276 and AD9277 in their various modes and
configurations. The application software used to interface with
the devices is also described.
The AD9276 and AD9277 data sheets, available at
www.analog.com, provide additional information and should be
consulted when using the evaluation board. All documents and
software tools are available at http://www.analog.com/fifo. For
any questions, send an email to highspeed.converters@analog.com.
Figure 1. AD9276-65EBZ/AD9276-80KITZ/AD9277-50EBZ Evaluation Board and HSC-ADC-EVALCZ Data Capture Board
See the last page for an important warning and disclaimers. Rev. 0 | Page 1 of 28
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TABLE OF CONTENTS
Features .............................................................................................. 1
Equipment Needed ........................................................................... 1
Documents Needed .......................................................................... 1
Software Needed ............................................................................... 1
General Description ......................................................................... 1
Typical Measurement Setup ............................................................ 1
Evaluation Board Hardware ............................................................ 3
Power Supplies .............................................................................. 3
Input Signals .................................................................................. 3
Output Signals ............................................................................... 3
10/09—Revision 0: Initial Version
Default Operation and Jumper Selection Settings ....................5
Evaluation Board Software Quick Start Procedures .....................6
Configuring the Board For TGC MODE ...................................6
Using the Software for Testing .....................................................6
Using the Integrated I/Q Demodulator
(CW Doppler Mode) ....................................................................9
Evaluation Board Schematics and Artwork ................................ 11
Ordering Information .................................................................... 23
Bill of Materials ........................................................................... 23
ESD Caution................................................................................ 28
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Evaluation Board User Guide UG-016
EVALUATION BOARD HARDWARE
The evaluation board for the AD9276 and AD9277 provides all of
the support circuitry required to operate the AD9276 and
AD9277 in their various modes and configurations. Figure 2
shows the typical bench characterization setup used to evaluate
the performance of the AD9276 and AD9277. 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 necessary to achieve the specified noise performance
(see the AD9276 or AD9277 data sheet).
See the Evaluation Board Software Quick Start Procedures
section to get started and Figure 21 to Figure 32 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, 2.5 A maximum output. 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 P601. Once on the PC board, the 6 V
supply is fused and conditioned before connecting to low dropout
linear regulators that supply the proper bias to each of the various
sections on the board.
When operating the evaluation board in a nondefault condition,
L602, L603, L604, L605, L606, L607, L608, and L609 can be
removed to disconnect the switching power supply. This enables
the user to bias each section of the board individually. Use P602,
P603, and P606 to connect a different supply for each section. At
least one 1.8 V supply is needed with a 1 A current capability for
1.8 V AVDD and 1.8 V DRVDD; however, it is recommended that
separate supplies be used for both analog and digital domains.
An additional supply is also required to supply 3.0 V to the DUT,
3.0 V AVDD2. This should also have a 1 A current capability. To
operate the evaluation board using the SPI and alternate clock
options, a separate 3.3 V analog supply is needed in addition to
the other supplies. The 3.3 V supply, or 3.3 V AVDD, should have a
1 A current capability. To bias the CW I/Q demodulator section
and differential gain drive circuitry, separate +5 V and −5 V
supplies are required at P606. These should each have 1 A current
capability.
INPUT SIGNALS
When connecting the TGC (time gain compensation) ADC
clock, 4LO and analog source, use clean signal generators with
low phase noise, such as Rohde and Schwarz SMA or HP8644B
signal generators or the equivalent. Use a 1 meter shielded, RG-58,
50 Ω coaxial cable for making connections to the evaluation
board. Enter the desired frequency and amplitude (refer to the
specifications in the AD9276 or AD9277 data sheet). In the
default condition, the evaluation board is set up to clock the ADC
from the crystal oscillator, OSC501, when in the TGC mode.
If a different or external ADC clock source is desired, follow the
instructions in the Clock section. Typically, most Analog Devices,
Inc., 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.
OUTPUT SIGNALS
The default TGC setup uses the FIFO5 high speed, dual-channel
FIFO data capture board (HSC-ADC-EVALCZ). Two of the
eight TGC channels can then be evaluated at the same time. For
more information on channel settings on these boards and their
optional settings, visit http://www.analog.com/fifo.
The default I/Q demodulator setup uses two AD8021 amplifiers
for I-V conversion and two ADA4841 amplifiers for gain and
filtering. The analog outputs can be evaluated using an oscilloscope
or spectrum analyzer.
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UG-016 Evaluation Board User Guide
W
ALL OUTLET
100V TO 240V AC
47Hz TO 63Hz
SWITCHING
POWER
SUPPLY
SWITCHING
SIGNAL
SYNTHESIZER
ANALOG I N P UT
SYNTHESIZER
SIGNAL
POWER
SUPPLY
4LO INPUT
6V DC
2A MAX
6V DC
2A MAX
AGILENT
POWER SUPPLY
GAIN CONTROL
INPUT
SIGNAL
SYNTHESIZER
OPTIONAL
CLOCK
INPUT
CW I/Q
OUTPUTS
SPECTRUM
ANALYZER
Figure 2. Evaluation Board Connection
OR
OSCILLOSCOPE
PC
RUNNING ADC
ANALYZER
OR VISUAL ANALOG
USER SOFTWARE
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Evaluation Board User Guide UG-016
DEFAULT OPERATION AND JUMPER SELECTION SETTINGS
This section explains the default and optional settings or modes
allowed on the evaluation board for the AD9276 and AD9277.
Power Circuitry
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 P601.
Analog Input Front-End Circuit
The evaluation board is set up for single-ended Kelvin
connection analog input with an optimum 50 Ω impedance
match of 18 MHz of bandwidth. For a different bandwidth
response, use the manual tune feature and antialiasing filter
settings.
VREF
VREF is set to 1.0 V. This causes the ADC to operate with the
internal reference in the 2.0 V p-p full-scale range. A separate
external reference option using the ADR130 is also included on
the evaluation board. Populate R320 with a 0 Ω resistor and remove
C301. Note that ADC full-scale ranges less than 2.0 V p-p are
not supported by the AD9276 and AD9277.
RBIAS
RBIAS has a default setting of 10 kΩ (R304) to ground and is used
to set the ADC core bias current. However, note that using other
than a 10 kΩ, 1% resistor for RBIAS may degrade the performance
of the device, depending on the resistor chosen.
Clock Circuitry
The default clock input circuitry is derived from a simple
transformer-coupled circuit using a high bandwidth 1:1
impedance ratio transformer (T501) 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.
The evaluation board is already set up to be clocked from the
crystal oscillator, OSC501. This oscillator is a low phase noise
oscillator from Valpey Fisher (VFAC3HL-40MHz). If a different
clock source is desired, remove R503, set Jumper J501 to disable
the oscillator from running, and connect the external clock
source to the SMA connector, J503.
A differential LVPECL clock driver can also be used to clock the
ADC input using the AD9516 (U501). Populate C528 and C529
with 0.1 µF capacitors and remove C506 and C507 to disconnect
the default clock path inputs. In addition, populate C511 and C512
with a 0.1 F capacitor. The AD9516 has many SPI-selectable
options that are set to a default mode of operation. Consult the
AD9516 data sheet for more information about these and other
options.
PDWN
To enable the power-down feature, short P301 (Pin 3 to Pin 4)
to the on position (AVDD) on the PDWN pin.
STBY
To enable the standby feature, short P301 (Pin 1 to Pin 2) to the
on position (AVDD) on the STBY pin.
GAIN+, GAIN−
To change the VGA attenuation, drive the GAIN+ pin from 0 V
to 1.6 V on J401 using a linear supply. This uses the single-ended
method to change the VGA gain from 0 dB to 42 dB. U411 is
available for users who wish to drive the gain pins (GAIN±)
differentially. Install R426, R435, and R436 and remove C456,
C457, and R440 to connect the amplifier correctly. In differential
mode, a linear supply from −0.8 V to +0.8 V on J401 is required
to change the VGA gain from 0 dB to 42 dB.
If an external source is not available, remove R425, and install
R438 to use the on-board resistive divider (R439) for gain
adjustment in the single-ended case.
CWI/Q+, CWI/Q−
To view the CWI+/CWI− and/or CWQ+/CWQ− outputs,
configure the AD9276 and AD9277 to be in CW mode and
enable each channel via the SPI Controller program. Apply a
13 dBm, 20 MHz reference clock (4LO) on J303. Each enabled
channel is summed and is available through J402/J403.
DOUTx+, DOUTx−
If an alternative data capture method to the setup described in
Figure 2 is used, optional receiver terminations, R604 to R613, can
be installed next to the high-speed backplane connector, P604.
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EVALUATION BOARD SOFTWARE QUICK START PROCEDURES
This section provides quick start procedures for using the AD9276
and AD9277, either on the evaluation board or at the system
level design. Both the default and optional settings are described.
CONFIGURING THE BOARD FOR TGC MODE
Before using the software for testing, configure the evaluation
board as follows:
1. Connect the evaluation board and the HSC-ADC-EVALCZ
as shown in Figure 1 and Figure 2.
2. Connect one 6 V, 2.5 A switching power supply (such as
the CUI, Inc., EPS060250UH-PHP-SZ supplied) to the
evaluation board.
3. Connect one 6 V, 2.5 A switching power supply (such as
the CUI EPS060250UH-PHP-SZ supplied) to the HSCADC-EVALCZ board.
4. Connect the USB cable to J6 on the HSC-ADC-EVALCZ
board to the PC.
5. On the evaluation board, place jumpers on all five pin pairs
of J404 to connect the SPI bus.
6. On the evaluation board, ensure that J501 (OSC_EN) is
jumpered to the OFF setting to use the on-board 40 MHz
Valpey Fisher VFAC3 oscillator.
7. On the evaluation board, use a clean signal generator with
low phase noise to provide an input signal to the desired
channel. Use a 1 meter, shielded, RG-58, 50 Ω coaxial cable
to connect the signal generator. For best results, use a
narrow-band band-pass filter with 50 Ω terminations and
an appropriate center frequency (Analog Devices uses
TTE, Allen Avionics, and K&L band-pass filters).
USING THE SOFTWARE FOR TESTING
Set Up the ADC Data Capture Block
After configuring the evaluation board, set up the ADC data
capture block using the following steps:
1. Open VisualAnalog™ on a PC. AD9276 or AD9277 should
be listed in the status bar of the New Canvas window.
Select the template that corresponds to the type of testing
to be performed (see Figure 3).
2. After the template is selected, a message box opens, asking
3. To view different channels or change features to settings
Figure 3. VisualAnalog, New Canvas Dialog Box
if the default configuration can be used to program the
FPGA (see Figure 4). Click Ye s , and the window closes.
If a different program is desired, follow Step 3.
Figure 4. VisualAnalog, New Canvas Message Box
other than the default settings, click the Expand Display
button located on the top right corner of the VisualAnalog
window, as shown in Figure 5 and Figure 6.
This process is described in the AN-905 Application Note,
VisualAnalog Converter Evaluation Tool Version 1.0 User
Manual. After you are finished, click the Collapse Display
button.
EXPAND DISPLAY BUTTON
Figure 5. VisualAnalog Window Toolbar, Expand Display Button
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Set Up the SPI Controller
After the ADC data capture board setup has been completed,
set up the SPI Controller:
1. Open the SPI Controller software by going to the Start
menu or double-clicking the SPI Controller software
desktop icon. If prompted for a configuration file, select
the appropriate one. If not, check the title bar at the top of
the SPI Controller window to determine which configuration
is loaded. If necessary, choose Cfg Open from the File
menu and select the appropriate configuration Note that
the CHIP ID(1) field should be filled to indicate whether
the correct SPI Controller configuration file is loaded (see
Figure 8).
08282-006
Figure 6. VisualAnalog, Main Window Expanded Display
4. Program the FPGA of the HSC-ADC-EVALCZ board to a
setting other than the default setting as described in Step 3.
Then expand the VisualAnalog display and click the Settings
button in the ADC Data Capture block (see Figure 6). The
ADC Data Capture Settings box opens (see Figure 7).
Figure 7. ADC Data Capture Settings, Board Settings Tab
5. Select the Board Settings tab and browse to the appropriate
programming file. If you are using an encode rate <28 MSPS,
select Octal_Low_Speed.bin. If you are using an encode
rate >28 MSPS, select Octal_High_Speed.bin. Next, click
Program; the DONE LED in the HSC-ADC-EVALCZ board
should then turn on. If more than two channels are required
to be displayed, select High_Speed_Octal_synchronous_
capture.bin. This canvas allows the user to display all the
channels at once. The drawback is that each FFT display is
only 8k points.
Exit the ADC Data Capture Settings box by clicking OK.
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Figure 8. SPI Controller, CHIP ID(1) Box
2. Click the New DUT button in the SPI Controller (see
Figure 9).
NEW DUT BUT TON
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Figure 9. SPI Controller, New DUT Button
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3. In the ADCBase 0 tab of the SPI Controller, find the CHIP
GRADE(2) box. Use the drop-down list box to select the
correct speed mode, if necessary. See the AD9276 or AD9277
data sheet, the AN-878 Application Note, and the AN-877
Application Note for reference.
Figure 10. SPI Controller, CHIP GRADE(2)
4. In the ADCBase 0 tab of the SPI Controller, find the
HIGHPASS(2B) box. Click the Manual Tune button to
calibrate the antialiasing filter. See the AD9276 or AD9277
data sheet, the AN-878 Application Note, and the AN-877
Application Note for reference.
Figure 11. SPI Controller, HIGHPASS(2B)
08282-011
5. In the Chan A tab of SPI Controller, find the OFFSET(10)
box. Use the drop-down list box labeled Offset Adj to
perform an offset correction to the LNA if the LNA power
08282-010
setting BIAS_CURR_A(12) is set low. The default value
is 32.
08282-012
Figure 12. SPI Controller, OFFSET(10)
6. Click the Run button in the VisualAnalog toolbar.
Rev. 0 | Page 8 of 28
RUN BUTTON
Figure 13. VisualAnalog Window Toolbar, Run Button
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Adjust the Amplitude of the Input Signal
Next, adjust the amplitude of the input signal for each channel
as follows:
1. Adjust the amplitude of the input signal so that the
fundamental is at the desired level (examine the Fund
Power reading in the left panel of the VisualAnalog FFT
window). If the gain pin voltage is too low, it is not possible
to reach full scale without distortion. Use a higher gain setting
or a lower input level to avoid distortion. This also depends
on the PGA gain setting, which can be 30 dB, 27 dB, 24 dB
(default), or 21 dB. See Figure 14 and Figure 15.
Figure 14. VisualAnalog, FFT Graph, Gain = 0 V
08282-014
3. Click the disk icon within the Graph box to save the
performance plot. See Figure 16.
0
–20
–40
–60
–80
AMPLITUDE ( d BF S)
–100
–120
–140
0 5 10 15 20
Figure 16. Typical FFT, AD9276 and AD9277
FREQUENCY (MHz )
fIN = 5MHz @ –1dBFS
LNA = 21.6dB
PGA = 24dB
V
= 1.6V
GAIN
LPF = 1 × 1/3 × F
HPF = FLP ÷ 20.7
SAMPLE
08282-016
USING THE INTEGRATED I/Q DEMODULATOR (CW DOPPLER MODE)
To examine the spectrum of the CW Doppler integrated I/Q
demodulator output, use the following procedure:
1. Complete the steps in the Configuring the Board and
Using the Software for Testing sections to ensure that the
evaluation board is set up correctly.
2. Optionally, remove the voltage source from the gain pin,
J401. It does not affect the CW Doppler output.
3. Use a 1 meter, shielded, RG-58, 50 Ω coaxial cable to
connect the spectrum analyzer to J402 and/or J403.
8. Connect a 20 MHz signal source to J303, 4LO input. Use a
clean signal generator with low phase noise to provide an
input clock signal. Use a 1 meter, shielded, RG-58, 50 Ω
coaxial cable to connect the signal generator.
9. Connect an analog input signal, 5.0123 MHz for example,
to ChA, J101. Use a clean signal generator with low phase
noise to provide an input signal to the desired channel. Use
a 1 meter, shielded, RG-58, 50 Ω coaxial cable to connect
the signal generator. For best results, use a narrow-band
band-pass filter with 50 Ω terminations and an appropriate
center frequency (Analog Devices uses TTE, Allen
Avionics, and K&L band-pass filters).
4. In the ADCBase 0 tab of the SPI Controller, find the
MODES(8) box. Select the CW Mode option (see
Figure 17).
Figure 15. VisualAnalog, FFT Graph, Gain = 1.6 V
2. If another channel needs to be evaluated, change the
channel setting within the ADC Data Capture block.
Channels A and B are the default displayed channels ADC
Data Capture Settings box under the General tab. Clock
Frequency and the number of samples can also be changed.
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6. An example of the CW Doppler output, as shown in Figure 19
and Figure 20, can be seen in the frequency and time domain,
respectively. Make sure to set the analog input level appropriately to achieve full scale throughout the signal chain.
100Hz
100Hz
12.5s
RF ATT
UNIT
30dB
dBm
1SA
A
08282-032
RBWMARKER 1 [T1]
REF Lv1
0dBm
0
–10
–20
–30
1AVG
–40
–50
–60
–70
–80
–90
–100
–110
–120
START 20Hz 2.498kHz STOP 25kHz
–1.91dBm
13.38605210kHz
1
VBW
SWT
Figure 19. Typical Spectrum Analyzer Display of CWD Output
TEK RUN: 2.50MS/s SAMPLE
T
[]
Figure 17. SPI Controller, MODES(8) Box
5. In the Chan X tab of the SPI Controller, where X is the
channel to which an analog input is applied, find the
CW_IQ_DEMOD_PH(2D) box. Select the CW Channel
Enabl check box to enable the channel. Then select the
phase rotation of the channel using the I/Q Demoduator
Phase drop-down menu.
Figure 18. SPI Controller, CW_IQ_DEMOD_PH(2D) Box
08282-017
T
3
CH3 100mVΩ
M20.0µs CH3 8mV
C3 FREQ
12.330kHz
UNSTABLE
HISTOGRAM
C3 p-p
576mV
08282-033
Figure 20. Typical Oscilloscope Display of CWD Output
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EVALUATION BOARD SCHEMATICS AND ARTWORK
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Figure 21. DUT Analog Input Circuits
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Figure 22. DUT Analog Input Circuits (Continued)
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Figure 23. DUT, VREF, and Decoupling
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Figure 24. I/Q Demodulator, SPI, and Gain Drive Circuitry
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Figure 25. Clock Circuitry
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Figure 26. Power Supply, Digital Output Interface
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Figure 27. Top Side
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Figure 28. Ground Plane (Layer 2)
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Figure 29. Power Plane (Layer 3)
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Figure 30. Power Plane (Layer 4)
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Figure 31. Ground Plane (Layer 5)
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Figure 32. Bottom Side
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ORDERING INFORMATION
BILL OF MATERIALS
Table 1.
Qty Reference Designator Description Manufacturer Part Number
103 C101, C102, C106, C110, C111, C115, C120, C121, C125, C130, C131,
C136, C201, C202, C206, C210, C211, C215, C220, C221, C225, C230,
C231, C236, C302, C303, C304, C307, C308, C309, C310, C311, C312,
C313, C314, C315, C316, C317, C318, C319, C320, C326, C327, C328,
C329, C330, C404, C413, C415, C418, C419, C420, C421, C422, C423,
C424, C431, C437, C439, C442, C443, C444, C445, C446, C447, C448,
C450, C451, C453, C454, C455, C456, C457, C458, C459, C462, C463,
C501, C502, C503, C504, C505, C506, C507, C510, C518, C519, C520,
C521, C522, C523, C527, C530, C531, C532, C533, C534, C615, C617,
C619, C621, C627, C629
4 C624, C625, C634, C635 Capacitor, 1 μF, 0402,
1 C509 Capacitor, 0.22 μF, 0402,
1 C636 Capacitor, 100 pF, 0402,
2 C449, C452 Capacitor, 1000 pF, 0402,
5 C401, C407, C425, C430, C630 Capacitor, 1500 pF, 0402,
6 C408, C409, C410, C432, C433, C434 Capacitor, 150 pF, 0402,
4 C411, C412, C435, C436 Capacitor, 2700 pF, 0402,
1 C515 Capacitor, 3900 pF, 0402,
1 C631 Capacitor, 33 pF, 0402,
4 C403, C405, C427, C428 Capacitor, 5 pF, 0603, 50 V,
4 C603, C606, C609, C612 Capacitor, 10000 pF,
1 C516 Capacitor, 22000 pF,
1 C301 Capacitor, 1 μF, 0603,
10 C602, C604, C605, C607, C608, C610, C611, C613, C622, C623 Capacitor, 4.7 μF, 0603,
10 C414, C416, C438, C440, C614, C616, C618, C620, C626, C628 Capacitor, 10 μF, 0603,
1 C632 Capacitor, 4.7 μF, 0805,
1 C633 Capacitor, 47 μF, 0805,
6 C402, C406, C426, C429, C460, C461 Capacitor, 22 μF, 0805,
1 C601 Capacitor, 10 μF, 6032-28,
5 CR301, CR302, CR303, CR304, CR601 LED, 0603, green Panasonic LNJ314G8TRA
10 D101, D102, D103, D104, D201, D202, D203, D204, D301, D501 Diode Schottky GP LN
5 D601, D602, D603, D604, D605 Diode, silicon rectifier,
1 D606 MOSFET P-CH 30 V 3.1 A
1 D607 Diode, Schottky, 2 A, 20 V Diodes Inc DF LS220L-7
1 F601 Polyswitch 1.10 A reset
Capacitor, 0.1 μF, 0402,
X5R, ceramic, 10 V
6.3 V, ceramic, X5R
6.3 V, ceramic
50 V, Ceramic
50 V, ceramic, X7R
25 V, ceramic, X7R
25 V, ceramic, X7R
25 V, ceramic, X7R
25 V ceramic, X7R
25 V ceramic, X7R
ceramic, NPO
0402, 16 V, ceramic, X7R
0402, 25 V, ceramic, Y5V
16 V, ceramic, X5R
6.3 V, ceramic, X5R
6.3 V, ceramic, X5R
6.3 V, ceramic X5R
6.3 V, Ceramic, X5R
6.3 V, ceramic, X5R
tantalum, SMT, 16 V, 10%
20 V SOT-23 200 mA SS
SMBJ, 2 A, 50 V
SOT-23
fuse SMD
Panasonic ECJ-0EB1A104K
Panasonic ECJ-0EB0J105M
Panasonic ECJ-0EB0J224K
Murata GRM1555C1H101JD01B
Panasonic ECJ-0EB1H102K
Panasonic ECJ-0EB1E152K
Panasonic ECJ-0EB1H151K
Panasonic ECJ-0EB1E272K
Panasonic ECJ-0EB1E392K
Panasonic ECJ-0EC1H330J
Yageo CC0603CRNP09BN5R0
Panasonic ECJ-0EB1C103K
Panasonic ECJ-0EF1E223Z
Panasonic ECJ-BVB1C105M
Panasonic ECJ-1VB0J475M
Panasonic ECJ-1VB0J106M
Murata GRM21BR61E475KA12L
Taiyo Yuden JMK212BJ476MG-T
Panasonic ECJ-2FB0J226M
Kemet T491C106K016AT
Fairchild MMBD4148SE
Microcommerical S2A-TP
Vishay SI2343DS-TI-E3
Tyco/Raychem NANOSMDC110F-2
Rev. 0 | Page 23 of 28
Page 24
UG-016 Evaluation Board User Guide
Qty Reference Designator Description Manufacturer Part Number
15 J101, J102, J103, J104, J201, J202, J203, J204, J401, J402, J403, J303,
J503, J504, J505
1 J305 Header, 4 pin double row,
1 J404 Header, 5 pin double row,
1 J501 Header, 3 pin single row,
1 J502 Header, 3 pin double row,
2 J301, TP501 Header, 2 pin double row,
1 J304 Header, 2 pin single row,
1 P601 Power supply connector Switchcraft RAPC722X
2 P604, P605 Connector, 60 pin RA Tyco 6469169-1
3 P602, P603, P606 Terminal block, 4-pin, ST Weiland Z5.531.3425.0
14 L401, L402, L602, L603, L604, L605, L606, L607, L608, L609, L610, L611,
L612, L613
1 L601 EMI filter LC block choke
1 L614 Inductor, 4.7 μH,
1 OSC501 Clock oscillator, ACMOS/
15 R101, R115, R130, R145, R201, R215, R230, R245, R319, R425, R498,
R499, R504, R531, R532
28 R102, R116, R131, R146, R202 R216, R231, R246, R503, R505, R506,
R507, R508, R509, R510, R511, R519, R526, R527, R451, R453, R455,
R456, R457, R458, R460, R462, R535
8 R107, R121, R136, R151, R207, R221, R236, R251 Resistor, 348 Ω, 0402,
10 R301, R302, R305, R441, R442, R443, R405, R417, R449, R450 Resistor, 1.00 kΩ, 0402,
20 R303, R304, R306, R403, R415, R444, R445, R446, R466, R467, R501,
R502, R514, R515, R516, R538, R539, R602, R615
6 R407, R409, R410, R419, R421, R422 Resistor, 20.0 kΩ, 0402,
6 R307, R308, R309, R310, R321, R517 Resistor, 5.1 kΩ, 0402,
5 R427, R429, R520, R521, R528 Resistor, 200 Ω, 0402,
2 R428, R430 Resistor, 221 Ω, 0402,
3 R440, R522, R523 Resistor, 100 Ω, 0402,
2 R431, R432 Resistor, 24 Ω, 0402,
2 R534, R536 Resistor, 24.9 Ω, 0402,
4 R401, R404, R413, R416 Resistor, 2.00 kΩ, 0402,
1 R447 Resistor, 27 Ω, 0402,
1 R433 Resistor, 33 kΩ, 0402,
1 R434 Resistor, 10.5 kΩ, 0402,
1 R437 Resistor, 8.66 kΩ, 0402,
1 R439 Potentiometer, 10 kΩ sq
1 R518 Resistor, 4.12 kΩ, 0402,
SMA, end launch, coax Samtec SMA-J-P-H-ST-EM1
male, 100 mil, straight
male, 100 mil, straight
male, 100 mil, straight
male, 100 mil, straight
male, 100 mil, straight
male, 100 mil, straight
Inductor, ferrite bead,
50 Ω 3 A 1206
coil
shielded power
LSTTL compatible
Resistor, 49.9 Ω, 0402,
1/16 W, 1%
Resistor, 0 Ω, 0402,
1/16 W, 1%
1/16 W, 1%
1/16 W, 1%
Resistor, 10.0 kΩ, 0402,
1/16 W, 1%
1/16 W, 5%
1/16 W, 5%
1/16 W, 1%
1/16 W, 1%
1/16 W, 1%
1/16 W, 1%
1/16 W, 1%
1/16 W, 1%
1/16 W, 1%
1/16 W, 5%
1/16 W, 1%
1/16 W, 1%
cermet top
1/16 W, 1%
Samtec TSW-104-07-G-D
Samtec TSW-105-07-G-D
Samtec TSW-103-07-G-S
Samtec TSW-103-07-G-D
Samtec TSW-102-07-G-D
Samtec TSW-102-07-G-S
Muarata BLM31PG500SN1L
Murata BNX016-01
Coilcraft LPS5015-472MLB
Valpey Fisher VFAC3H-L-40MHz
Panasonic ERJ-2RKF49R9X
Panasonic ERJ-2GE0R00X
Panasonic ERJ-2RKF3480X
Panasonic ERJ-2RKF1001X
Panasonic ERJ-2RKF1002X
Panasonic ERJ-2GEJ203X
Panasonic ERJ-2GEJ512X
Panasonic ERJ-2RKF2000X
Panasonic ERJ-2RKF2210X
Panasonic ERJ-2GEJ101X
Panasonic ERJ-2RKF24R0X
Panasonic ERJ-2RKF24R9X
Panasonic ERJ-2RKF2001X
Panasonic ERJ-2RKF27R0X
Panasonic ERJ-2GEJ333X
Panasonic ERJ-2RKF1052X
Panasonic ERJ-2RKF8661X
Copal CT94EW103
Panasonic ERJ-2RKF4121X
Rev. 0 | Page 24 of 28
Page 25
Evaluation Board User Guide UG-016
Qty Reference Designator Description Manufacturer Part Number
3 R540, R541, R601 Resistor, 249 Ω, 0402,
1 R603 Resistor, 1.91 kΩ, 0402,
1 R614 Resistor, 64.9 kΩ, 0402 Panasonic ERJ-2RKF6492X
1 R616 Resistor, 0.047 Ω, 0805,
1 R617 Resistor, 16.9 kΩ, 0402 Panasonic ERJ-2RKF1692X
12 L403, L404, L405, L406, L407, L408, L409, L410, L411, L412, L413, L414 Resistor, 0 Ω, 0603
2 T301, T501 Transformer, RF, 1:1 Minicircuits ADT1-1WT+
2 U403, U408 IC, amp, low PWR, noise,
1 U304 IC, voltage REF, precision
4 U401, U402, U406, U407 IC, amp, low noise high
2 U404, U409 IC, ADC, 18-bit, 1 MSPS
2 U405, U410 IC, VREF, prec micropwr,
1 U411 IC, ADC driver, ultra-low
1 U501 IC, clock gen, 14-output,
1 U601 IC, regulator 3.3 V, low
1 U602 IC, regulator 3.0 V, low
2 U603, U604 IC, regulator 1.8 V, low
1 U605 IC, regulator 0.8 V to
1 U608 IC-ADI high ACC. 500 mA
1 U412 IC, buffer, tinylogic UHS
1 U413 IC, buffer, tinylogic UHS
1 U606 IC, regulator, 500 mA
1 U607 IC-ADI current-mode
1 U302 IC-ADI ultrafast SIGe ECL
1 U301 IC ADI AD9276BSVZ
10 MP101, MP102, MP103, MP104, MP105, MP106, MP107, MP108,
MP109, MP110
4 MP111, MP112, MP113, MP114 Part of assembly Insert/Snap into
Do Not Install
20 C305, C306, C511, C512, C513, C514, C528, C529, C464, C465, C466,
C467, C468, C469, C470, C471, C472, C473, C474, C475
3 C524, C525, C526 Capacitor, 100 pF, 0402,
1/16 W, 1%
1/16 W, 1%
1/4 W, 2%
1/10 W, 5%
distortion, SO8
series, SOT23_6
speed, SO8
PuLSAR 7.0 mW, RM10
low dropout, SO8
distortion diff, LFCSP16
2.8 GHZ VCO, QFN64
dropout CMOS, SO8
dropout CMOS, SO8
dropout CMOS, SO8
5.0 V, low dropout
CMOS, SO8
anycap low drop 2.5 V reg
dual, SC70
dual, SC70
neg LDO
step-down dc-to-dc
controller
clock/data buffers
Part of assembly Place into J404
Capacitor, 0.1 μF, 0402,
X5R, ceramic, 10 V
50 V, ceramic, X7R
Panasonic ERJ-2RKF2490X
Panasonic ERJ-2RKF1911X
Susumu RL1220T-R047
Panasonic ERJ-3GEY0R00V
ADI ADA4841-2YRZ
ADI ADR130BUJZ
ADI AD8021ARZ
ADI AD7982BRMZ
ADI ADR434ARZ
ADI ADA4938-1ACPZ-R7
ADI AD9516-0BCPZ
ADI ADP1706ARDZ-3.3-R7
ADI ADP1706ARDZ-3.0-R7
ADI ADP1706ARDZ-1.8-R7
ADI ADP1708ARDZ-R7
ADI ADP3335ACPZ-2.5R7
FAIRCHILD NC7WZ07P6X
FAIRCHILD NC7WZ16P6X
Linear
Technology
ADI ADP1864AUJZ-R7
ADI ADCLK905
(Pin 1-2, 3-4, 5-6,
7-8,9-10), J301
(Pin 1-2, 3-4), J304
(Pin 1-2), J502
(Pins 3-4), J501
(Pins 2-3)
the large holes
from the bottom
side of board
Panasonic ECJ-0EB1A104K
Panasonic ECJ-0EB1H101K
LT1175CST-5#PBF
100 mil jumpers
14 mm height, dual
locking standoffs for
circuit board support
Rev. 0 | Page 25 of 28
Page 26
UG-016 Evaluation Board User Guide
Qty Reference Designator Description Manufacturer Part Number
8 C105, C114, C124, C135, C205, C214, C224, C235 Capacitor, 47 pF, 0402,
2 C417, C441 Capacitor, 1 μF, 0805,
3 L501, L502, L503 Inductor, 10 nH, SMT
12 R106, R120, R135, R150, R213, R220, R235, R250, R408, R420, R452,
R454
2 R402, R414 Resistor, 10.0 kΩ, 0402,
9 R320, R426, R435, R436, R438, R464, R465, R533, R537 Resistor, 0 Ω, 0402,
13 R604, R605, R606, R607, R608, R609, R610, R611, R612, R613, R329,
R459, R463
2 R406, R418 Resistor, 10.0 kΩ, 0402,
1 R513 Resistor, 49.9 Ω, 0402,
4 R411, R412, R423, R424 Resistor, 20 Ω, 0402,
4 TP1, TP2, TP3, TP4 Conn-PCB test point, blk Keystone
X5R, ceramic, 50 V
16 V, ceramic, Y5V
L7144
Resistor, 1.00 kΩ, 0402,
1/16 W, 1%
1/16 W, 1%
1/16 W, 1%
Resistor, 100 Ω, 0402,
1/16 W, 1%
1/16 W, 1%
1/16 W, 1%
1/16 W, 1%
Panasonic ECJ-0EC1H470J
Panasonic ECJ-2VF1C105Z
Coilcraft 0603CS-10NXJLW
Panasonic ERJ-2RKF1001X
Panasonic ERJ-2RKF1002X
Panasonic ERJ-2GE0R00X
Panasonic ERJ-2GEJ101X
Panasonic ERJ-2RKF20R0X
5001
Electronics Corp
Rev. 0 | Page 26 of 28
Page 27
Evaluation Board User Guide UG-016
NOTES
Rev. 0 | Page 27 of 28
Page 28
UG-016 Evaluation Board User Guide
NOTES
ESD CAUTION
Evaluation boards are only intended for device evaluation and not for production purposes. Evaluation boards are supplied “as is” and without warranties of any kind, express,
implied, or statutory including, but not limited to, any implied warranty of merchantability or fitness for a particular purpose. No license is granted by implication or otherwise under
any patents or other intellectual property by application or use of evaluation boards. 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. Analog Devices reserves the
right to change devices or specifications at any time without notice. Trademarks and registered trademarks are the property of their respective owners. Evaluation boards are not
authorized to be used in life support devices or systems.
©
2009 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
UG08282-0-10/09(0)
Rev. 0 | Page 28 of 28
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