HSC-ADC-EVALB-SC/HSC-ADC-EVALB

High Speed ADC USB FIFO Evaluation Kit
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
FEATURES
FUNCTIONAL BLOCK DIAGRAM
STANDARD
USB 2.0
HSC-ADC-EVALB-SC
OR
HSC-ADC-EVALB-DC
SINGLE OR DUAL
HIGH-SPEED ADC
EVALUATION BOARD
FILTERED
ANALOG
INPUT
REG
ADC
EQUIPMENT NEEDED
Analog signal source and antialiasing filter
Low jitter clock source
High speed ADC evaluation board and ADC data sheet
PC running Windows 98 (2nd ed.), Windows 2000,
Windows Me, or Windows XP
Latest version of ADC Analyzer
USB 2.0 port recommended (USB 1.1-compatible)
PRODUCT DESCRIPTION
The high speed ADC FIFO evaluation kit includes the latest
version of ADC Analyzer and a buffer memory board to capture
blocks of digital data from the Analog Devices high speed
analog-to-digital converter (ADC) evaluation boards. The FIFO
board is connected to the PC through a USB port and is used
with ADC Analyzer to quickly evaluate the performance of high
speed ADCs. Users can view an FFT for a specific analog input
and encode rate to analyze SNR, SINAD, SFDR, and harmonic
information.
The evaluation kit is easy to set up. Additional equipment needed
includes an Analog Devices high speed ADC evaluation board,
a signal source, and a clock source. Once the kit is connected
and powered, the evaluation is enabled instantly on the PC.
Two versions of the FIFO are available. The HSC-ADC-EVALBDC is used with multichannel ADCs and converters with demultiplexed digital outputs. The HSC-ADC-EVALB-SC evaluation
board is used with single-channel ADCs. See Table 1 to choose
the FIFO appropriate for your high speed ADC evaluation
board.
CHB FIFO,
32K,
133MHz
n
TIMING
CIRCUIT
USB
CTLR
CHA FIFO,
32K,
133MHz
n
CLOCK
CIRCUIT
PS
+3.0V
REG
SPI
SPI
CLOCK INPUT
120-PIN CONNECTOR
05870-001
PS
LOGIC
Buffer memory board for capturing digital data
used with high speed ADC evaluation boards
to simplify evaluation
32 kB FIFO depth at 133 MSPS (upgradable)
Measures performance with ADC Analyzer™
Real-time FFT and time domain analysis
Analyzes SNR, SINAD, SFDR, and harmonics
Simple USB port interface (2.0)
Supporting ADCs with serial port interfaces (SPI®)
On-board regulator circuit, no power supply required
6 V, 2 A switching power supply included
Compatible with Windows® 98 (2nd ed.), Windows 2000,
Windows Me, and Windows XP
Figure 1.
PRODUCT HIGHLIGHTS
1. Easy to Set Up. Connect the included power supply and
signal sources to the two evaluation boards. Then connect
to the PC and evaluate the performance instantly.
2. ADIsimADC™. ADC Analyzer supports virtual ADC
evaluation using ADI proprietary behavioral modeling
technology. This allows rapid comparison between multiple
ADCs, with or without hardware evaluation boards. For more
information, see AN-737 at www.analog.com/ADIsimADC.
3. USB Port Connection to PC. PC interface is a USB 2.0
connection (1.1-compatible) to the PC. A USB cable is
provided in the kit.
4. 32 kB FIFO. The FIFO stores data from the ADC for processing.
A pin-compatible FIFO family is used for easy upgrading.
5. Up to 133 MSPS Encode Rate on Each Channel. Singlechannel ADCs with encode rates up to 133 MSPS can be used
with the FIFO board. Multichannel and demultiplexed output
ADCs can also be used with the FIFO board with clock rates
up to 266 MSPS.
6. Supports ADC with Serial Port Interface or SPI. Some ADCs
include a feature set that can be changed via the SPI. The FIFO
supports these SPI-driven features through the existing USB
connection to the computer without additional cabling needed.
Rev. 0
Information furnished by Analog Devices is believed to be accurate and reliable. However, no
responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other
rights of third parties 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
©2006 Analog Devices, Inc. All rights reserved.
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
TABLE OF CONTENTS
Features .............................................................................................. 1
Clocking with Interleaved Data................................................ 10
Equipment Needed........................................................................... 1
Connecting to the HSC-ADC-FPGA-4/-8 ............................. 10
Product Description......................................................................... 1
Connecting to the DEMUX BRD ............................................ 10
Functional Block Diagram .............................................................. 1
Upgrading FIFO Memory......................................................... 10
Product Highlights ........................................................................... 1
Jumpers ............................................................................................ 11
Revision History ............................................................................... 2
Default Settings........................................................................... 11
FIFO Evaluation Board Easy Start.................................................. 3
Evaluation Board ............................................................................ 13
Requirements ................................................................................ 3
Power Supplies............................................................................ 13
Easy Start Steps ............................................................................. 3
Connection and Setup ............................................................... 13
Virtual Evaluation Board Easy Start With ADIsimADC ............ 4
FIFO Schematics and PCB Layout ............................................... 14
Requirements ................................................................................ 4
Schematics................................................................................... 14
Easy Start Steps ............................................................................. 4
PCB Layout ................................................................................. 21
FIFO 4.1 Data Capture Board Features ......................................... 5
Bill of Materials............................................................................... 23
FIFO 4.1 Supported ADC Evaluation Boards .......................... 6
Ordering Information.................................................................... 25
Theory of Operation ........................................................................ 9
Ordering Guide .......................................................................... 25
Clocking Description................................................................... 9
ESD Caution................................................................................ 25
SPI Description............................................................................. 9
REVISION HISTORY
2/06—Revision 0: Initial Version
Rev. 0 | Page 2 of 28
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
FIFO EVALUATION BOARD EASY START
REQUIREMENTS
•
FIFO evaluation board, ADC Analyzer, and USB cable
•
High speed ADC evaluation board and ADC data sheet
•
Power supply for ADC evaluation board
•
Analog signal source and appropriate filtering
•
Low jitter clock source applicable for specific ADC
evaluation, typically <1 ps rms
•
PC running Windows 98 (2nd ed.), Windows 2000,
Windows Me, or Windows XP
•
PC with a USB 2.0 port recommended (USB 1.1compatible)
6.
Once the cable is connected to both the computer and the
FIFO board, and power is supplied, the USB drivers start
to install. To complete the total installation of the FIFO
drivers, you need to complete the new hardware sequence
two times. The first Found New Hardware Wizard opens
with the text message This wizard helps you install
software for…Pre-FIFO 4.1. Click the recommended
install, and go to the next screen. A hardware installation
warning window should then be displayed. Click Continue
Anyway. The next window that opens should finish the PreFIFO 4.1 installation. Click Finish. Your computer should
go through a second Found New Hardware Wizard, and
the text message, This wizard helps you install software
for…Analog Devices FIFO 4.1, should be displayed.
Continue as you did in the previous installation and click
Continue Anyway. Then click Finish on the next two
windows. This completes the installation.
7.
(Optional) Verify in the device manager that Analog
Devices, FIFO4.1 is listed under the USB hardware.
8.
Apply power to the evaluation board and check the voltage
levels at the board level.
9.
Connect the appropriate analog input (which should be
filtered with a band-pass filter) and low jitter clock signal.
Make sure the evaluation boards are powered on before
connecting the analog input and clock.
EASY START STEPS
Note: You need administrative rights for the Windows
operating systems during the entire easy start procedure.
It is recommended to complete every step before reverting
to a normal user mode.
1.
2.
Install ADC Analyzer from the CD provided in the FIFO
evaluation kit or download the latest version on the Web.
For the latest updates to the software, check the Analog
Devices website at www.analog.com/hsc-FIFO.
Connect the FIFO evaluation board to the ADC evaluation
board. If an adapter is required, insert the adapter between
the ADC evaluation board and the FIFO board. If using
the HSC-ADC-EVALB-SC model, connect the evaluation
board to the bottom two rows of the 120-pin connector,
closest to the installed IDT FIFO chip. If using an ADC
with a SPI interface, remove the two 4-pin corner keys so
that the third row can be connected.
3.
Connect the provided USB cable to the FIFO evaluation
board and to an available USB port on the computer.
4.
Refer to Table 5 for any jumper changes. Most evaluation
boards can be used with the default settings.
5.
After verification, connect the appropriate power supplies
to the ADC evaluation boards. The FIFO evaluation board
is supplied with a wall mount switching power supply that
provides a 6 V, 2 A maximum output. Connect the supply
end to the rated 100 ac to 240 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 J301. Refer to the instructions
included in the ADC data sheet for more information
about the ADC evaluation board’s power supply and other
requirements.
10. Start ADC Analyzer.
11. Choose an existing configuration file for the ADC
evaluation board or create one.
12. Click Time Data in ADC Analyzer (left-most button under
the menus). A reconstruction of the analog input is
displayed. If the expected signal does not appear, or if there
is only a flat red line, refer to the ADC Analyzer data sheet
at www.analog.com/hsc-FIFO for more information.
Rev. 0 | Page 3 of 28
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
VIRTUAL EVALUATION BOARD EASY START WITH ADIsimADC
REQUIREMENTS
5.
In the ADC Modeling dialog box, click the Device tab and
then click the … (Browse) button, adjacent to the dialog
box. This opens a file browser and displays all of the
models found in the default directory: c:\program
files\adc_analyzer\models. If no model files are found,
follow the on-screen directions or see Step 1 to install
available models. If you have saved the models somewhere
other than the default location, use the browser to navigate
to that location and select the file of interest.
No hardware is required. However, if you wish to compare
results of a real evaluation board and the model, you can switch
easily between the two, as outlined in the following Easy Start
Steps section.
6.
From the menu, click Config > FFT. In the FFT
Configuration dialog box, ensure that the Encode
Frequency is set for a valid rate for the simulated device
under test. If set too low or too high, the model does not run.
EASY START STEPS
7.
Once a model has been selected, information about the
model displays on the Device tab of the ADC Modeling
dialog box. After ensuring that you have selected the right
model, click the Input tab. This lets you configure the
input to the model. Click either Sine Wave or Two Tone
for the input signal.
8.
Click Time Data (left-most button under the pull-down
menus). A reconstruction of the analog input is displayed.
The model can now be used just as a standard evaluation
board would be.
9.
The model supports additional features not found when
testing a standard evaluation board. When using the
modeling capabilities, it is possible to sweep either the
analog amplitude or the analog frequency. For more
information consult the ADC Analyzer User Manual at
www.analog.com/hsc-FIFO.
Requirements include
•
Completed installation of ADC Analyzer, Version 4.5.17 or
later.
•
ADIsimADC product model files for the desired converter.
Models are not installed with the software, but they can be
downloaded from the ADIsimADC Virtual Evaluation
Board website at no charge.
1.
To get ADC model files, go to www.analog.com/ADIsimADC
for the product of interest. Download the product of
interest to a local drive. The default location is c:\program
files\adc_analyzer\models.
2.
Start ADC Analyzer (see the ADC Analyzer User Manual).
3.
From the menu, click Config > Buffer > Model as the
buffer memory. In effect, the model functions in place of
the ADC and data capture hardware.
4.
After selecting the model, click the Model button (located
next to the Stop button) to select and configure which
converter is to be modeled. A dialog box appears in the
workspace, where you can select and configure the
behavior of the model.
Rev. 0 | Page 4 of 28
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
FIFO 4.1 DATA CAPTURE BOARD FEATURES
6V SWITCHING
POWER SUPPLY
CONNECTION
IDT72V283 32k ⋅
16-BIT 133MHz FIFO
TIMING ADJUSTMENT
JUMPERS
ON BOARD +3.3V
REGULATOR
120-CONNECTOR
(PARALLEL CMOS
INPUTS)
OPTIONAL POWER
CONNECTION
IDT72V283 32k ⋅
16-BIT 133MHz FIFO
USB CONNECTION
TO COMPUTER
OPTIONAL SERIAL
PORT INTERFACE
CONNECTOR
RESET SWITCH
WHEN ENCODE RATE
IS INTERRUPTED
Figure 2. FIFO Components (Top View)
Rev. 0 | Page 5 of 28
µCONTROLLER CRYSTAL
CLOCK = 24MHz,
OFF DURING
DATA CAPTURE
05870-002
OPEN SOLDER MASK
ON ALL DATA AND
CLOCK LINES FOR
EASY PROBING
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
120-CONNECTOR
(PARALLEL CMOS
INPUTS)
TIMING ADJUSTMENT
JUMPERS
EPROM TO LOAD
USB FIRMWARE
DRIVER CIRCUIT FOR
SERIAL PORT INTERFACE
(SPI) LINES
CYPRESS Fx2 HIGH SPEED
USB 2.0 µCONTROLLER
05870-003
OPTIONAL SERIAL
PORT INTERFACE
(SPI) CONNECTOR
Figure 3. FIFO Components (Bottom View)
FIFO 4.1 SUPPORTED ADC EVALUATION BOARDS
The evaluation boards in Table 1 can be used with the high speed ADC FIFO evaluation kit. Some evaluation boards require an adapter between
the ADC evaluation board connector and the FIFO connector. If an adapter is needed, send an email to highspeed.converters@analog.com with
the part number of the adapter and a mailing address.
Table 1. HSC-ADC-EVALB-DC- and HSC-ADC-EVALB-SC-Compatible Evaluation Boards 1
Evaluation Board Model
AD6644ST/PCB
AD6645-80/PCB
AD6645-105/PCB
AD9051/PCB
AD9200SSOP-EVAL
AD9200TQFP-EVAL
AD9201-EVAL
AD9203-EB
AD9212-65EB1
AD9215BCP-65EB
AD9215BCP-80EB
AD9215BCP-105EB
AD9215BRU-65EB
AD9215BRU-80EB
AD9215BRU-105EB
AD9216-80PCB
AD9216-105PCB
Description of ADC
14-bit, 65 MSPS ADC
14-bit, 80 MSPS ADC
14-bit, 105 MSPS ADC
10-bit, 60 MSPS ADC
10-bit, 20 MSPS ADC
10-bit, 20 MSPS ADC
Dual 10-bit, 20 MSPS ADC1
10-bit, 40 MSPS ADC
Octal 10-bit, 65 MSPS ADC
10-bit, 65 MSPS ADC
10-bit, 80 MSPS ADC
10-bit, 105 MSPS ADC
10-bit, 65 MSPS ADC
10-bit, 80 MSPS ADC
10-bit, 105 MSPS ADC
Dual 10-bit, 80 MSPS ADC
Dual 10-bit, 105 MSPS ADC
FIFO Board Version
SC
SC
SC
SC
SC
SC
SC
SC
DC
SC
SC
SC
SC
SC
SC
DC
DC
Rev. 0 | Page 6 of 28
Comments
Requires AD9051FFA
Requires AD922xFFA
Requires AD922xFFA
Requires AD922xFFA
Requires AD922xFFA
Requires HSC-ADC-FPGA-8
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
Evaluation Board Model
AD9218-105PCB
AD9218-65PCB
AD9219-65EB1
AD9220-EB
AD9222-65EB1
AD9226-EB
AD9226QFP-EB
AD9228-65EB1
AD9229-65EB1
AD9233-80EB
AD9233-105EB
AD9233-125EB
AD9234-EB
AD9235BCP-20EB
AD9235BCP-40EB
AD9235BCP-65EB
AD9235-20PCB
AD9235-40PCB
AD9235-65PCB
AD9236BRU-80EB
AD9236BCP-80EB
AD9237BCP-20EB
AD9237BCP-40EB
AD9237BCP-65EB
AD9238BST-20PCB
AD9238BST-40PCB
AD9238BST-65PCB
AD9238BCP-20EB
AD9238BCP-40EB
AD9238BCP-65EB
AD9240-EB
AD9241-EB
AD9243-EB
AD9244-40PCB
AD9244-65PCB
AD9245BCP-20EB
AD9245BCP-40EB
AD9245BCP-65EB
AD9245BCP-80EB
AD9246-80EB
AD9246-105EB
AD9246-125EB
AD9248BST-65EB
AD9248BCP-20EB
AD9248BCP-40EB
AD9248BCP-65EB
AD9259-50EB1
AD9260-EB
AD9280-EB
AD9281-EB
AD9283/PCB
AD9287-100EB1
AD9289-65EB1
AD9411/PCB
Description of ADC
10-bit, 105 MSPS ADC
10-bit, 65 MSPS ADC
Quad 10-bit, 65 MSPS ADC
12-bit, 10 MSPS ADC
Octal 12-bit, 65 MSPS ADC
12-bit, 65 MSPS ADC
12-bit, 65 MSPS ADC
Quad 12-bit, 65 MSPS ADC
Quad 12-bit, 65 MSPS ADC
12-bit, 80MSPS ADC
12-bit, 105MSPS ADC
12-bit, 125MSPS ADC
12-bit, 150MSPS ADC
12-bit, 20 MSPS ADC
12-bit, 40 MSPS ADC
12-bit, 65 MSPS ADC
12-bit, 20 MSPS ADC
12-bit, 40 MSPS ADC
12-bit, 65 MSPS ADC
12-bit, 80 MSPS ADC
12-bit, 80 MSPS ADC
12-bit, 20 MSPS ADC
12-bit, 40 MSPS ADC
12-bit, 65 MSPS ADC
Dual 12-bit, 20 MSPS ADC
Dual 12-bit, 40 MSPS ADC
Dual 12-bit, 65 MSPS ADC
Dual 12-bit, 20 MSPS ADC
Dual 12-bit, 40 MSPS ADC
Dual 12-bit, 65 MSPS ADC
14-bit, 40 MSPS ADC
14-bit, 1.25 MSPS ADC
14-bit, 3 MSPS ADC
14-bit, 40 MSPS ADC
14-bit, 65 MSPS ADC
14-bit, 20 MSPS ADC
14-bit, 40 MSPS ADC
14-bit, 65 MSPS ADC
14-bit, 80 MSPS ADC
14-bit, 80 MSPS ADC
14-bit, 105 MSPS ADC
14-bit, 125 MSPS ADC
Dual 14-bit, 65 MSPS ADC
Dual 14-bit, 20 MSPS ADC
Dual 14-bit, 40 MSPS ADC
Dual 14-bit, 65 MSPS ADC
Quad 14-bit, 50 MSPS ADC
16-bit, 2.5 MSPS ADC
8-bit, 32 MSPS ADC
Dual 8-bit, 28 MSPS ADC
8-bit, 100 MSPS ADC
Quad 8-bit, 100 MSPS ADC
Quad 8-bit, 65 MSPS ADC
10-bit, 200 MSPS ADC
FIFO Board Version
DC
DC
DC
SC
DC
SC
SC
DC
DC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
Comments
Requires HSC-ADC-FPGA-4/-8
Requires AD922xFFA
Requires HSC-ADC-FPGA-8
Requires AD922xFFA
Requires AD922xFFA
Requires HSC-ADC-FPGA-4/-8
Requires HSC-ADC-FPGA-4/-8
SC
DC
DC
DC
DC
DC
DC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
DC
DC
DC
DC
DC
SC
SC
SC
SC
DC
DC
DC
Rev. 0 | Page 7 of 28
Requires AD922xFFA
Requires AD922xFFA
Requires AD922xFFA
Requires HSC-ADC-FPGA-4/-8
Requires AD922xFFA
Requires AD922xFFA
Requires AD922xFFA
Requires AD9283FFA
Requires HSC-ADC-FPGA-4/-8
Requires HSC-ADC-FPGA-9289
Requires DEMUX BRD
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
Evaluation Board Model
AD9430-CMOS/PCB
AD9430-LVDS/PCB2
AD9432/PCB
AD9433/PCB
AD9444-CMOS/PCB
AD9444-LVDS/PCB
AD9445-IF-LVDS/PCB
AD9445-BB-LVDS/PCB
AD9446-80LVDS/PCB
AD9446-100LVDS/PCB
AD9460-80EB-IF
AD9460-80EB-BB
AD9460-105EB-IF
AD9460-105EB-BB
AD9461-130EB-IF
AD9461-130EB-BB
AD9480-LVDS/PCB2
AD9481-PCB
AD10200/PCB
AD10201/PCB
AD10226/PCB
AD10265/PCB
AD10465/PCB
AD10677/PCB
AD10678/PCB
AD15252/PCB
AD15452/PCB
1
2
Description of ADC
12-bit, 210 MSPS ADC
12-bit, 210 MSPS ADC
12-bit, 105 MSPS ADC
12-bit, 125 MSPS ADC
14 bit, 80 MSPS ADC
14 bit, 80 MSPS ADC
14-bit, 125 MSPS ADC
14-bit, 125 MSPS ADC
16-bit, 80 MSPS ADC
16-bit, 100 MSPS ADC
16-bit, 80 MSPS ADC
16-bit, 80 MSPS ADC
16-bit, 105 MSPS ADC
16-bit, 105 MSPS ADC
16-bit, 130 MSPS ADC
16-bit, 130 MSPS ADC
8-bit, 250 MSPS ADC
8-bit, 250 MSPS ADC
Dual 12-bit, 105 MSPS ADC
Dual 12-bit, 105 MSPS ADC
Dual 12-bit, 125 MSPS ADC
Dual 12-bit, 65 MSPS ADC
Dual 14-bit, 65 MSPS ADC
16-bit, 65 MSPS ADC
16-bit, 80 MSPS ADC
12-bit, Dual 65 MSPS ADC
12-bit, Quad 65 MSPS ADC
FIFO Board Version
DC
DC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
SC
DC
DC
DC
DC
DC
DC
DC
SC
SC
DC
DC
The high speed ADC FIFO evaluation kit can be used to evaluate two channels at a time.
If a DEMUX BRD is needed, send an email to highspeed.converters@analog.com.
Rev. 0 | Page 8 of 28
Comments
Requires DEMUX BRD
Requires DEMUX BRD
Requires GS09066
Requires GS09066
Requires GS09066
Requires GS09066
Requires GS09066
Requires GS09066
Requires GS09066
Requires HSC-ADC-FPGA-4/-8
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
THEORY OF OPERATION
The FIFO evaluation board can be divided into several circuits,
each of which plays an important part in acquiring digital data
from the ADC and allows the PC to upload and process that
data. The evaluation kit is based around the IDT72V283 FIFO
chip from Integrated Device Technology, Inc (IDT). The system
can acquire digital data at speeds up to 133 MSPS and data
record lengths up to 32 kB using the HSC-ADC-EVALB-SC
FIFO evaluation kit. The HSC-ADC-EVALB-DC, which has
two FIFO chips, is available to evaluate multichannel ADCs or
demultiplexed data from ADCs sampling faster than 133 MSPS.
A USB 2.0 microcontroller communicating with ADC Analyzer
allows for easy interfacing to newer computers using the USB 2.0
(USB 1.1-compatible) interface.
The process of filling the FIFO chip or chips and reading the
data back requires several steps. First, ADC Analyzer initiates
the FIFO chip fill process. The FIFO chips are reset, using a
master reset signal (MRS). The USB microcontroller is then
suspended, which turns off the USB oscillator and ensures that
it does not add noise to the ADC input. After the FIFO chips
completely fill, the full flags from the FIFO chips send a signal
to the USB microcontroller to wake up the microcontroller
from suspend. ADC Analyzer waits for approximately 30 ms
and then begins the readback process.
During the readback process, the acquisition of data from
FIFO 1 (U201) or FIFO 2 (U101) is controlled via Signal OEA
and Signal OEB. Because the data outputs of both FIFO chips
drive the same 16-bit data bus, the USB microcontroller
controls the OEA and OEB signals to read data from the correct
FIFO chip. From an application standpoint, ADC Analyzer
sends commands to the USB microcontroller to initiate a read
from the correct FIFO chip, or from both FIFO chips in dual or
demultiplexed mode.
CLOCKING DESCRIPTION
Each channel of the buffer memory requires a clock signal to
capture data. These clock signals are normally provided by the
ADC evaluation board and are passed along with the data
through Connector J104 (Pin 37 for both Channel A and
Channel B). If only a single clock is passed for both channels,
they can be connected together by Jumper J303.
Jumpers J304 and J305 at the output of the LVDS receiver allow
the output clock to be inverted by the LVDS receiver. By default,
the clock outputs are inverted by the LVDS receiver.
The single-ended clock signal from each data channel is
buffered and converted to a differential CMOS signal by two
gates of a low voltage differential signal (LVDS) receiver, U301.
This allows the clock source for each channel to be CMOS,
TTL, or ECL.
The clock signals are ac-coupled by 0.1 μF capacitors.
Potentiometer R312 and Potentiometer R315 allow for fine
tuning the threshold of the LVDS gates. In applications where
fine-tuning the threshold is critical, these potentiometers can be
replaced with a higher resistance value to increase the
adjustment range. Resistors R301, R302, R303, R304, R311,
R313, R314, and R316 set the static input to each of the
differential gates to a dc voltage of approximately 1.5 V.
At assembly, Solder Jumper J310 to Solder Jumper J313 are set
to bypass the potentiometer. For fine adjustment using the pot,
the solder jumpers must be removed, and R312 and R315 must
be populated.
U302, an XOR gate array, is included in the design to let users
add gate delays to the FIFO memory chip clock paths. They are
not required under normal conditions and are bypassed at
assembly by Jumper J314 and Jumper J315. Jumper J306 and
Jumper J307 allow the clock signals to be inverted through an
XOR gate. In the default setting, the clocks are not inverted by
the XOR gate.
The clock paths described above determine the WRT_CLK1 and
WRT_CLK2 signals at each FIFO memory chip (U101 and
U201). The timing options above should let you choose a clock
signal that meets the setup and hold time requirements to
capture valid data.
A clock generator can be applied directly to S1 and/or S3. This
clock generator should be the same unit that provides the clock
for the ADC. These clock paths are ac-coupled, so that a sine
wave generator can be used. DC bias can be adjusted by
R301/R302 and R303/R304.
The DS90LV048A differential line receiver is used to square the
clock signal levels applied externally to the FIFO evaluation
board. The output of this clock receiver can either directly drive
the write clock of the IDT72V283 FIFO(s), or first pass through
the XOR gate timing circuitry described above.
SPI DESCRIPTION
The Cypress IC (U502) supports the HSC SPI standard to allow
programming of ADCs that have SPI-accessible register maps.
U102 is a buffer that drives the 4-wire SPI (SCLK, SDI, SDO,
CSB 1 ) through the 120-pin connector (J104) on the third or top
row. J502 is an auxiliary SPI connector to monitor the SPI
signals connected directly to the Cypress IC. For more
information on this and other functions, consult the user
manual titled Interfacing to High Speed ADCs via SPI at
www.analog.com/hsc-FIFO.
1
Note that CSB1 is the default CSB line used.
Rev. 0 | Page 9 of 28
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
The SPI interface designed on the Cypress IC can communicate
with up to five different SPI-enabled devices. The CLK and data
lines are common to all SPI devices. The correct device is
chosen to communicate by using one of the five active low chip
select pins. This functionality is controlled by selecting a SPI
channel in the software.
CLOCKING WITH INTERLEAVED DATA
ADCs with very high data rates can exceed the capability of a
single buffer memory channel (~133 MSPS). These converters
often demultiplex the data into two channels to reduce the rate
required to capture the data. In these applications, ADC Analyzer
must interleave the data from both channels to process it as a
single channel. The user can configure the software to process
the first sample from Channel A, the second from Channel B,
and so on, or vice versa. The synchronization circuit included in
the buffer memory forces a small delay between the write enable
signals (WENA and WENB) to the FIFO memory chips (Pin 1,
U101, and U201), ensuring that the data is captured in one
FIFO before the other. Jumper J401 and Jumper J402 determine
which FIFO receives WENA and which FIFO receives WENB.
CONNECTING TO THE HSC-ADC-FPGA-4/-8
ADCs that have serial LVDS outputs require another board that
is connected between the ADC evaluation board and the FIFO
data capture card. This board converts the serial data into
parallel CMOS so that the FIFO data capture card can accept
the data. For more detailed information on this board, refer to
the HSC-ADC-FPGA datasheet at www.analog.com/hsc-FIFO.
CONNECTING TO THE DEMUX BRD
ADCs that have parallel LVDS outputs require another board
that is connected between the ADC evaluation board and the
FIFO data capture card. This board converts parallel LVDS to
parallel CMOS, using both channels of the FIFO data capture
card. For more detailed information on this board, send an
email to highspeed.converters@analog.com
UPGRADING FIFO MEMORY
The FIFO evaluation board includes one or two 32 kB FIFOs
that are capable of 133 MHz clock signals, depending on the
model number. Pin-compatible FIFO upgrades are available
from IDT. See Table 2 for the IDT part number matrix.
Table 2. IDT Part Number Matrix
Part Number
IDT72V283-L7-5PF (Default )
IDT72V293-L7-5PF
IDT72V2103-L7-5PF
IDT72V2113-L7-5PF
IDT72V283-L6PF
IDT72V293-L6PF
IDT72V2103-L6PF
IDT72V2113-L6PF
FIFO Depth
32 kB
64 kB
132 kB
256 kB
32 kB
64 kB
132 kB
256 kB
For more information, visit www.idt.com.
Rev. 0 | Page 10 of 28
FIFO Speed
133 MHz
133 MHz
133 MHz
133 MHz
166 MHz
166 MHz
166 MHz
166 MHz
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
JUMPERS
Use the legends in Table 3 and Table 4 to configure the jumpers. On the FIFO evaluation board, Channel A is associated with the bottom
IDT FIFO chip, and Channel B is associated with the top IDT FIFO chip (closest to the Analog Devices logo).
Table 3. Jumper Legend
Position
In
Out
Position 1 or Position 3
Description
Jumper in place (2-pin header).
Jumper removed (2-pin header).
Denotes the position of a 3-pin header. Position 1 is marked on the board.
Table 4. Solder Jumper Legend
Position
In
Out
Description
Solder pads should be connected with 0 Ω resistor.
Solder pads should not be connected with 0 Ω resistor.
DEFAULT SETTINGS
Table 5 lists the default settings for each model of the FIFO evaluation kit. The single channel (SC) model is configured to work with a
single channel ADC using the bottom FIFO, U201. The dual channel (DC) model is configured to work with demultiplexed ADCs (such
as the AD9430). Dual channel ADC settings are shown in a separate column, as are settings for the opposite (top) FIFO, U101 for a single
channel ADC. To align the timing properly, some evaluation boards require modifications to these settings. Refer to the Clocking
Description section in the Theory of Operation section for more information.
Another useful way to configure the jumper settings easily for various configurations is to consult ADC Analyzer under Help > About
HSC_ADC_EVALB, and click Set Up Default Jumper Wizard. Then click the configuration setting that applies to the application of
interest. A picture of the FIFO board is displayed for that application with a visual of the correct jumper settings already in place.
Table 5. Jumper Configurations
Jumper #
J303
J304
Single Channel
Settings, Default
(Bottom)
In
In
Demultiplexed
Settings
Out
In
Dual-Channel
Settings
Out
In
Single-Channel
Settings (Top) 1
In
In
J305
In
In
In
In
J306
Out
Out
Out
Out
J307
Out
Out
Out
Out
J310 to
J313
J314
In
In
In
In
In
In
In
In
J315
In
In
In
In
J316
J401
In
In
In
In
In
In
In
In
J402
Out
Out
Out
Out
J403
Out
Out
Out
Out
J404
In
In
In
In
J405
Out
In
Out
Out
Rev. 0 | Page 11 of 28
Description
Position 2 to Position 4, ties write clocks together
Position 1 to Position 2, POS3: invert clock out of
DS90 (U301)
Position 2 to Position 3, POS3: invert clock out of
DS90 (U301)
No invert to encode clock from XOR (U302),
0 Ω resistor
No invert to encode clock from XOR (U302),
0 Ω resistor
All solder jumpers are shorted with 0 Ω resistors
(bypass level shifting to input of DS90)
Position 1 to Position 2, one XOR gate timing
delay for top FIFO (U101)
Position 1 to Position 2, one XOR gate timing
delay for bottom FIFO (U201)
Power connected using switching power supply
Controls if top FIFO (U101) gets write enable
before or after bottom FIFO, 0 Ω resistor
Controls if top FIFO (U101) gets write enable
before or after bottom FIFO, 0 Ω resistor
Controls if bottom FIFO (U201) gets a write
enable before or after the top FIFO, 0 Ω resistor
Controls if bottom FIFO (U201) gets a write
enable before or after the top FIFO, 0 Ω resistor
When in, WRT_CLK1 is used to create write enable
signal for FIFOs, 0 Ω resistor (significant only for
interleave mode)
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
Jumper #
J406
Single Channel
Settings, Default
(Bottom)
In
Demultiplexed
Settings
In
Dual-Channel
Settings
In
Single-Channel
Settings (Top) 1
In
J503
In
In
In
In
J504
J505
Out
In
Out
In
Out
In
Out
In
J506
J602
J603
Out
Out
In
Out
Out
In
Out
Out
In
Out
Out
In
1
Description
WRT_CLK2 is used to create write enable signal
for FIFOs, 0 Ω resistor (significant only for
interleave mode)
Connect enable empty flag of top FIFO (U101)
to USB MCU, 0 Ω resistor
N/A
Connect enable full flag of top FIFO (U101)
to USB MCU, 0 Ω resistor
N/A
N/A
N/A
Some jumpers can be a 0 Ω resistor instead of a physical jumper. This is shown in Table 5 in the jumper description column.
Rev. 0 | Page 12 of 28
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
EVALUATION BOARD
The FIFO provides all of the support circuitry required to
accept two channels of an ADC’s digital parallel CMOS outputs.
Each of the various functions and configurations can be selected by
proper connection of various jumpers (see Table 5). When
using this in conjunction with an ADC evaluation board, 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
ultimate performance of the converter. 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.
When operating the evaluation board in a non-default
condition, J316 can be removed to disconnect the switching
power supply. This enables the user to bias the board
independently. Use P302 to connect an independent supply to
the board. A 3.3 V supply is needed with at least a 1 A current
capability.
CONNECTION AND SETUP
The FIFO board has a 120-pin (40-pin, triple row) connector
that accepts two 16-bit channels of parallel CMOS inputs (see
Figure 6). For those ADC evaluation boards that have only an
80-pin (40-pin, double row) connector, it is pertinent for the
lower two rows of the FIFO’s triple row connector to be connected
in order for the data to pass to either FIFO channel correctly.
The top or third row is used to pass SPI signals across to the
adjacent ADC evaluation board that supports this feature.
See Figure 5 to Figure 15 for complete schematics and layout plots.
POWER SUPPLIES
The FIFO board is supplied with a wall mount switching power
supply that provides a 6 V, 2 A maximum output. Connect the
supply to the rated 100 ac to 240 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 J301. On the PC board, the 6 V supply is then fused
and conditioned before connecting to the low dropout 3.3 V
linear regulator that supplies the proper bias to the entire board.
WALL OUTLET
100V TO 240V AC
47Hz TO 63Hz
ROHDE & SCHWARZ,
SMHU,
2V p-p SIGNAL
SYNTHESIZER
EVALUATION
BOARD
BAND-PASS
FILTER
XFMR
INPUT
CLK
CHB
PARALLEL
CMOS
OUTPUTS
SPI
HSC-ADC-EVALB-DC
FIFO DATA
CAPTURE
BOARD
PC
RUNNING
ADC
ANALYZER
USB
CONNECTION
SPI
SPI
Figure 4. Example Setup Using Quad ADC Evaluation Board and FIFO Data Capture Board
Rev. 0 | Page 13 of 28
05870-004
ROHDE & SCHWARZ,
SMHU,
2V p-p SIGNAL
SYNTHESIZER
CHB
PARALLEL
CMOS
OUTPUTS
+
VCC
SWITCHING
POWER
SUPPLY
–
GND
3.3V
6V DC
2A MAX
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
FIFO SCHEMATICS AND PCB LAYOUT
SCHEMATICS
ALLOW Fx2 TO CONTROL FIFO’S OUTPUT WIDTH
RCLK
REN1
61
EF1_TF
FF1_TF
REN
RCLK
63
RM
64
EF/OR
66
65
PFM
VCC
PAE
67
68
IP
70
69
BE
HF
FSEL1
71
72
FSEL0
73
OW
74
PAF
75
FF/IR
76
FWFT/SI
LD
77
78
MRS
79
PRS
GND
D11
Q10
VCC
D10
D9
Q9
D8
Q8
Q7
OE1
57
Q17
56
Q16
55
54
53
Q15
52
Q14
51
50
Q13
49
Q12
48
47
Q11
46
45
Q10
44
43
Q9
42
Q8
41
Q7
Q6
GND
59
58
40
39
60
Q6
Q5
38
Q5
Q4
37
Q4
VCC
Q3
35
36
34
Q2
GND
Q3
C107
0.1µF
Q2
Q1
32
C106
0.1µF
33
Q1
22
D1_6
U101
Q0
VCC
D7
20
D12
GND
19
Q11
31
D1_8
GND
30
18
GND
Q0
D1_9
D13
D0
17
Q13
Q12
D1
D1_10
VCC
D14
29
16
D15
28
D1_11
D16
D1_0
15
Q14
IDT72V283
TQFP80
TOP FIFO
CHANNEL B
D1_1
D1_12
VCC
D2
14
Q15
27
13
D17
D1_2
D1_13
GND
D3
12
GND
D4
D1_14
GND
26
11
IW
D1_3
D1_15
9
Q16
D5
10
DNC
25
D1_16
R108
DNP
Q17
D1_4
8
VCC
VCC
GND
D1_17
DNC
24
7
VCC
OE
23
6
RT
SEN
D1_5
5
WEN
D6
2
4
VCC
C101
0.1µF
C102
0.1µF
C103
0.1µF
C104
0.1µF
C105
0.1µF
Figure 5. PCB Schematic
Rev. 0 | Page 14 of 28
C108
0.1µF
C109
0.1µF
05870-005
R109
DNP
MRS
WRT_CLK1
80
1
WCLK
WEN1
21
E102
3
WRT_CLK1
R102
10kΩ
VCC
D1_7
POPULATE WITH PIN SOCKET
E101
R101
0Ω
62
PC2: TRISTATED, NORMAL 16-BIT DATA PATH
PC2: DRIVEN HIGH, 9-BIT OUTPUT ALLOWS
READING 18 BITS IN TWO READS.
PC2
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
CMOS INPUTS
J104
CLKB
J104
A1
A2
DUT_CLK1
A3
MSB
CHB
LSB
CLKA
A4
D1_15
A5
D1_14
A6
D1_13
A7
D1_12
A8
D1_11
A9
D1_10
A10
D1_9
A11
D1_8
A12
D1_7
A13
D1_6
A14
D1_5
A15
D1_4
A16
D1_3
A17
D1_2
A18
D1_1
A19
D1_0
A20
CTRL_B
D1_15
D1_14
D1_13
D1_12
D1_11
D1_10
D1_9
D1_8
D1_7
D1_6
D1_5
D1_4
D1_3
D1_2
D1_1
D1_0
CHA
LSB
B1
D1_17
B2
D1_16
C4
C5
B6
C6
B7
C7
B8
C8
B9
C9
B10
C10
B11
C11
B12
C12
B13
C13
B14
C14
B15
C15
B16
C16
B17
C17
B18
C18
C19
B19
D2_17
A22
B22
D2_16
D2_15
A25
D2_14
A26
D2_13
A27
D2_12
A28
D2_11
A29
D2_10
A30
D2_9
A31
D2_8
A32
D2_7
A33
D2_6
A34
D2_5
A35
D2_4
A36
D2_3
A37
D2_2
A38
D2_1
A39
D2_0
A40
CTRL_D
D2_15
D2_14
D2_13
D2_12
D2_11
D2_10
D2_9
D2_8
D2_7
D2_6
D2_5
D2_4
D2_3
D2_2
D2_1
D2_0
CTRL_D
C2
B5
B21
A24
D1_16
C1
C3
A21
DUT_CLK2
D1_17
B4
CTRL_A
CTRL_B
PLACEMENT OF HEADER KEY HERE
J104
B3
B20
A23
MSB
TEST POINTS
CTRL_A
D2_17
D2_16
C20
C21
C22
B23
C23
B24
C24
B25
C25
B26
C26
B27
C27
B28
C28
B29
C29
16
1
18
B30
C30
15
2
17
B31
C31
14
3
16
B32
C32
13
4
15
B33
C33
12
5
14
B34
C34
11
6
13
B35
C35
10
7
12
B36
C36
8
11
B37
C37
B38
C38
VCC
19
SDO
9
22
RZ101
20
OE2
VCC
A1
Y1
Y2
Y3
OE
A0
Y0
1
2
3
4
U102
A2
74VHC541MTC
5
CSB1
CSB2
A3
Y4
A4
Y5
A5
Y6
A6
Y7
A7
GND
10
6
7
8
SDI
SCLK
CSB3
CSB4
9
R103
10kΩ
R104
10kΩ
C39
B39
B40
ALL SPI LABELS ARE WITH
RESPECT TO THE DUT.
CTRL_C
CTRL_C
C40
PLACEMENT OF HEADER KEY HERE
Figure 6. Schematic (Continued)
Rev. 0 | Page 15 of 28
05870-006
TEST POINTS
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
RCLK
REN2
61
EF2
FF2
MRS
E201
R202
10kΩ
62
WRT_CLK2
R201
0Ω
REN
RCLK
63
RM
64
EF/OR
65
PFM
66
PAE
67
VCC
68
IP
70
69
BE
HF
FSEL1
71
72
FSEL0
74
73
OW
FF/IR
PAF
75
76
FWFT/SI
LD
77
78
MRS
79
D11
Q10
VCC
D10
D9
Q9
59
OE2
58
57
Q17
56
Q16
55
54
53
Q15
52
Q14
51
50
Q13
49
Q12
48
47
Q11
46
45
Q10
44
43
Q9
42
Q8
41
Q7
Q6
GND
60
40
39
Q5
38
Q5
Q1
Q4
37
Q4
35
36
34
Q3
22
D2_6
Q2
21
U201
VCC
Q7
Q3
VCC
Q2
Q8
GND
D8
D7
20
GND
32
19
D12
33
D2_8
Q11
Q1
18
GND
Q0
D2_9
GND
GND
17
D13
31
D2_10
Q13
Q12
30
16
VCC
D14
Q0
15
D2_11
D15
D0
D2_12
D16
D1
14
Q14
IDT72V283
TQFP80
BOTTOM FIFO
CHANNEL A
29
13
VCC
D2_0
D2_13
Q15
D2
12
D17
28
D2_14
GND
27
11
GND
D2_1
D2_15
GND
D2_2
10
IW
D3
D2_16
Q16
D4
9
DNC
26
8
Q17
D2_3
D2_17
VCC
D5
7
VCC
25
6
DNC
D2_4
5
OE
GND
4
RT
SEN
24
2
3
WEN
23
1
PRS
WEN2
D6
E202
WCLK
80
VCC
D2_7
R203
DNP
WRT_CLK2
Q6
VCC
D2_5
R204
DNP
VCC
C201
0.1µF
C202
0.1µF
C203
0.1µF
C204
0.1µF
C205
0.1µF
C206
0.1µF
C207
0.1µF
Figure 7. Schematic (Continued)
Rev. 0 | Page 16 of 28
C208
0.1µF
05870-007
POPULATE WITH PIN SOCKET
PC3
J311
J310
C310
0.1µF
05870-008
2
3
1
J301
PJ-102A
+
R316
331Ω
R315
DNP
C301
10µF
2.2A
F301
J313
J312
4
1
T103
C311
0.1µF
R304
331Ω
R303
331Ω
VCC
CR301
S2A
VCC
R302
331Ω
R301
331Ω
R314
331Ω
POWER SUPPLY INPUT 6V, 2A MAX
R313
331Ω
R312
DNP
R311
331Ω
VCC
PLACE JUMPERS BETWEEN PADS
ON TOP SIDE
FOR COHERENT SAMPLING
REMOVE R301-R304 AND
SHORT C302 AND C303
3
2
4
3
VI
1
ADJ
VO
4
EN
EN
VO
U301
RIN4–
RIN4+
RIN3–
RIN3+
RIN2–
RIN2+
RIN1–
VCC
13
DNP
2
GND
J302
C313
1µF
12
VCC
+
3
J305
1
J316
C308
0.1µF
+
DNP
C309
10µF
74VCX86
U302
74VCX86
U302
8
3
12
13
74VCX86
U302
VCC
74VCX86
C306
0.1µF
5
U302
9
20
15
17
19
REN1
MRS
VCC
18
13
OE1
CR303
16
14
11
EF1_F
12
8
10
7
6
FF1_F
5
2
4
3
WRT_CLK1
DNP
J308
1
R317
499Ω
11
6
E305
J315
E306
J314
1
SET 0, 1, OR 2 XOR
GATE DELAYS
CONTROLS
BOTTOM FIFO
3
WRT_CLK2
SET 0, 1, OR 2 XOR
GATE DELAYS
1
CONTROLS
3 TOP FIFO
WRT_CLK1
WENS
REN2
OE2
EF2
FF2
BOTTOM FIFO
WRT_CLK2
RCLK
AUX CLOCK SIGNAL MONITOR CONNECTOR
9
10
R310
1kΩ
R309
1kΩ
2
1
4
VCC
DNP
J307
J306
TOP FIFO
INVERT CLOCK 2
INVERT CLOCK 1
1 J304 3
INVERT CLOCK 2
10
11
14
C307
10µF
ROUT4
ROUT3
ROUT2
15
INVERT CLOCK 1
C305
0.1µF
ROUT1
DS90LV048A
6
9
RIN1+
VR301
ADP3339AKC-3.3
8
7
5
6
4
3
1
2
OPTIONAL POWER
INPUT HEADER
C312
1µF
SK33MSCT
CR302
REMOVE JUMPER FOR DUAL
CHANNEL CONFIGURATION
3
TOP FIFO
DUT_CLK1
BOTTOM FIFO
DUT_CLK2
J303
1
2
C303
0.1µF
C302
0.1µF
1
VCC
1
Rev. 0 | Page 17 of 28
2
Figure 8. Schematic (Continued)
2
POPULATE WITH
PIN SOCKET
E302 E301
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
Figure 9. Schematic (Continued)
Rev. 0 | Page 18 of 28
05870-009
WRT_CLK2
WRT_CLK1
WENS
C401
DNP
J406
DNP
J405
R401
20KΩ
2
1
R404
49.9Ω
R407
49.9Ω
R405
49.9Ω
R409
40.2Ω
R408
49.9Ω
U401
MC100EPT22
7
U401
MC100EPT22
3
6
4
R403
DNP
R402
DNP
VCC
CLK0
5
D1
9
C402
0.1µF
VCC
U402
D1
CLK
8
7
CLK
CLK0
4
6
D0
D0
VBB
VCC
C403
0.1µF
11
GND
CLK
D
CLK
D
Q
Q
C404
0.1µF
Q
S
R
Q
S
R
MC100EP29
3
VCC
10
2
1
R406
40.2Ω
S1
C405
0.1µF
12
14
13
Q1
R1
15
Q1
16
17
Q0
Q0
18
19
S0
R0
R410
49.9Ω
3
4
2
1
6
R415
40.2Ω
DNP
U403
MC100EPT23
7
U403
R414 MC100EPT23
49.9Ω
R412
40.2Ω
R413
49.9Ω
R411
49.9Ω
J402
J401
J404
DNP
J403
WEN2
WEN1
CONTROLS BOTTOM FIFO
CONTROLS TOP FIFO
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
C506
0.1µF
05870-010
VCC
FF2
1
14
7
U505
VCC
R521
332Ω
2
C510
0.1µF
VCC
R522
332Ω
4
C509
0.1µF
U505
FROM
TOP
FIFO VCC
FF1_TF 3
C508
0.1µF
FROM
BOT TOM
FIFO
C507
0.1µF
1
2
D
FF1_BHB
4
Q
Q
3
5
6
5 U505
MRS
C512
0.1µF
E505
E504
E503
CLR
GND
CLK
PRE
VCC
8
VCC
C511
0.1µF
U504
7
R518
10kΩ
EF1_BHB
R519
10kΩ
J505
J503
C505
12pF
C504
12pF
FF1_TF
2
1
C502
2.2µF
Y501
24MHz
2
L501
1
EF1_TF
VCC
C513
0.1µF
6
R524
0Ω
R523
2kΩ
VCC
C514
0.1µF
C516
0.1µF
C517
0.1µF
USB_VBUS
E502
R503
499Ω
FF2
EF2
RCLK
INTERLEAVE_FIRSTWORD
C515
0.1µF
CR501
J501
USB CONNECTION 4 3 2 1
DN P
J506
DN P
J504
3
GND
GROUND TEST POINTS
FROM
BOT TOM
FIFO
25
24
23
22
21
128
127
126
120
119
118
117
97
96
95
94
19
18
12
11
9
8
7
6
5
4
32
1
A15
A14
A13
A12
A11
A10
A9
A8
A7
A6
A5
A4
A3
A2
A1
A0
DMINUS
DPLUS
XTALIN
XTALOUT
RDY5
RDY4
RDY3
RDY2
RDY1/*SLWR
RDY0/*SLRD
IFCLK
VCC
CR502
R502
100kΩ
CLKOUT
C503
0.1µF
VCC
2
1
S501
U503
1
A0
2
A1
3
A2
4
VSS
SDA
SC L
WP
VCC
5
6
7
8
VCC
CS
4 FF_USB
WR
42
5
AGND
13
GND
3
99
41
+V
10
AVCC
2
DVCC
FF_USB
101
RD
2
4
3
+
S501 = RESET USB CONTROLLER
C501
1µF
R517
2kΩ
R516
2kΩ
VCC
INT5
SDI
CSB1
CSB2
CSB3
CSB4
CSB5
SDO
109
110
111
112
113
114
115
12
11
10
9
8
7
6
5
4
3
2
1
J502
DN P
CONTROL FIFO
OUTPUT WIDTH
OE2
AUX SPI PORT
CONNECTION
16
15
14
16
15
14
SCLK
108
79
78
77
76
PC3
Q17
PC2
74
75
Q16
73
R526 24.9Ω
INTERLEAVE_FIRSTWORD
OE1
CTRL_D
R525 24.9Ω
CTRL_C
R507 24.9Ω
R520 24.9Ω
CTRL_B
R506 24.9Ω
CTRL_ A
R505 24.9Ω
R504 24.9Ω
72
92
91
90
89
85
84
83
82
28
106
13
NC3
NC2
NC1
PE7/GPI FADR8
PE6/T2EX
PE5/INT6
PE2/T2OUT
PE1/T1OUT
PE0/T0OUT
PC0/GPIFADR0
PC1/GPIFADR1
PC2/GPIFADR2
PC3/GPIFADR3
PC4/GPIFADR4
PC5/GPIFADR5
PC6/GPIFADR6
PC7/GPIFADR7
PA7/*FLAG/SLCS
PA6/*PKTEND
PA5/FIFOADR1
PA4/FIFOADR0
PA3/*WU2
PA2/*SLOE
PA1/INT1
PA0/INT0
INT4
ALL SPI
LABELSARE PE3/RXD0OUT
WITH RESPECT PE4/RXD1OUT
TO THE DUT
VCC;17,26,43,48,64,68,81,100,107
GND;20;27;49;58;65;80;93;
116;125
U502
CY7C68013_128AXC
34
1
BKPT
50
40
RESET
PSEN
Q15
124
RESE RVED
33
R509 10kΩ
51
39
*WAKEU P
OE
TXD0
38
RXD0
SDA
Q14
123
69
R510 24.9Ω
52
36
53
SCL
35
EA
R508 10kΩ
37
TXD1
Q13
122
RXD1
Q12
121
PD7/FD15
Q11
105
PD6/FD14
Q9
Q10
FF2
31
T2
30
T1
FROM TOP FIFO
29
VCC
T0
59
D0
PD4/FD12
MRS
60
PD5/FD13
CTL0*FLAG A
R5 11 24.9Ω
70
R512 24.9Ω
WENS
CTL1/*FLAGB
71
CTL2/*FLAGC
REN1
D1
104
66
RENEXT R513 24.9Ω
61
PD3/FD 11
Q8
D2
103
R514 24.9Ω
D3
PD2/FD10
Q7
102
REN2
CTL3
67
CTL4
R515 24.9Ω
98
CTL5
REN2M
D4
62
PD1/FD9
Q6
57
D5
63
PD0/FD8
Q5
56
D6
86
PB7/FD7
Q4
55
PB6/FD6
Q3
54
PB5/FD5
Q2
47
PB4/FD4
Q1
46
PB3/FD3
Q0
PB2/FD2
45
PB1/FD1
44
PB0/FD0
D7
Rev. 0 | Page 19 of 28
87
Figure 10. Schematic (Continued)
88
U501
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
VCC
CONNECTIONS FOR 2M WORD EXTERNAL MEMORY
EXTERNAL MEMORY OVERRIDES ON BOARD MEMORIES WHEN PLUGGED IN. ONLY A SIDE DATA.
C601
0.1µF
DNP
D1_9
D1_10
D1_11
D1_12
D1_13
D1_14
D1_15
1
16
2
15
3
14
4
13
5
12
6
11
7
10
8
9
J601
DC8
DC9
DC10
DC11
DC12
DC13
DC14
DC15
RZ601
1
DC0
DC3
DC2
D1_0
D1_1
D1_2
D1_3
D1_4
D1_5
D1_6
D1_7
16
2
15
3
14
4
13
5
12
6
11
7
10
8
9
DC0
D1_17
R603
0Ω
R604
0Ω
4
36
QL0
2
37
QL1
3
38
QL2
4
5
DC6
5
39
DC8
6
40
QL4
6
DC7
7
41
QL5
7
DC11
8
42
QL6
8
43
QL7
9
DC13
DC1
9
10
44
DC14
11
45
DC15
DC2
DC4
12
46
DC3
DC5
13
47
DC16
14
48
DC1
DC4
DC5
DC9
15
49
DC6
DC17
16
50
17
51
18
52
DC7
RZ602
D1_16
3
RENEXT 1
QL3
DC10
1
2
U601
35
DC12
19
53
DC16
20
54
DC17
21
55
22
56
23
57
REN1
24
58
RCLK
EF1_BHB
25
59
FF1_BHB
26
60
MRS
27
61
WEN1
WRT_CLK1
28
62
QL0
29
63
QL1
30
64
QL2
QL3
31
65
QL4
32
66
QL5
33
67
QL6
34
68
QL7
Figure 11. Schematic (Continued)
Rev. 0 | Page 20 of 28
10
OUT_EN
VCC
Q0
D0
Q1
D1
Q2
D2
D3
Q3
D4
Q4
D5
Q5
Q6
D6
Q7
D7
GND
CLOCK
20
VCC
19
1
16 Q0
18
2
15 Q1
17
3
14 Q2
16
4
13 Q3
15
5
12 Q4
14
6
11 Q5
13
7
10 Q6
12
8
9
11
Q7
RZ605
74LCX574
J602
REN2M
J603
RCLK
DNP
J603: ALLOWS 2 MEG BUFFER TO READ BACK DATA
ON EACH RCLK EDGE.
J602: ALLOWS 2 MEG BUFFER TO READ BACK 1 DATA
ON EVERY 3RD RCLK EDGE. J602 IS FOR
BACKWARD COMPATABILITY IF NEEDED.
05870-011
D1_8
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
05870-012
PCB LAYOUT
05870-013
Figure 12. Layer 1—Primary Side
Figure 13. Layer 2—Ground Plane
Rev. 0 | Page 21 of 28
05870-014
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
05870-015
Figure 14. Layer 3—Power Plane
Figure 15. Layer 4—Secondary Side
Rev. 0 | Page 22 of 28
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
BILL OF MATERIALS
Table 6. HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC Bill of Materials
Item
1
Qty
42
Device
Capacitor
Package
402
Description
Ceramic, 0.1 μF, 16 V,
X5R, 10%
Manufacturer
Panasonic
Mfg Part Number
ECJ-0EB1C014K
3
Reference Designation
C101 to C109, C201 to C208,
C302, C303, C305, C306, C308,
C310, C311, C402 to C405,
C503, C506 to C517, C601
C301, C307, C309
2
Capacitor
6032-28
Kemet
T491C106K016AS
3
2
C312, C313
Capacitor
603
Panasonic
ECJ-1VB1A105K
4
1
C501
Capacitor
3216-18
Panasonic
ECS-T1CY105R
5
1
C502
Capacitor
805
Panasonic
ECJ-2FB1E225K
6
2
C504, C505
Capacitor
402
Panasonic
ECJ-0EC1H120J
7
1
CR301
Diode
DO-214AA
1
CR302
Diode
DO-214AB
9
2
CR303, CR501
LED
603
Micro Commercial
Group
Micro Commercial
Group
Panasonic
S2A
8
10
1
CR502
Diode
SOD-123
Diodes, Inc.
1N4148W-7
11
1
F301
Fuse
1210
Tyco, Raychem
NANOSMDC110F-2
12
1
J104
Connector
AMP
650874
13
1
J301
Connector
0.08”, PCMT
Switchcraft
SC1153
14
1
J303
Connector
4-pin
SAMTEC
TSW-1-10-08-GD
15
16
4
8
Connector
Connector
3-pin
603
SAMTEC
Panasonic
TWS-103-08-G-S
ERJ-3GEY0R00V
17
18
1
1
J304, J305, J314, J315
J310 to J313, J401, J404, J406,
J603
J316
J501
Connector
Connector
2-pin
4-pin
SAMTEC
AMP
TSW-1002-08-G-S
787780-1
19
1
L501
805
Steward
HZ0805E601R-00
20
21
5
8
402
402
Panasonic
Panasonic
ERJ-2GE0R00X
ERJ-2RKF1002X
22
10
Resistor
402
332 Ω, 1/16 W, 1%
Panasonic
ERJ-2RKF3320X
23
24
25
26
2
2
1
8
Resistor
Resistor
Resistor
Resistor
402
402
402
402
1 kΩ, 1/16 W, 1%
499 Ω, 1/16 W, 1%
20 kΩ, 1/16 W, 1%
49.9 Ω, 1/16 W, 1%
Panasonic
Panasonic
Panasonic
Panasonic
ERJ-2RKF1002X
ERJ-2RKF1001X
ERJ-2RKF4990X
ERJ-2RKF2002X
27
28
29
4
1
13
Resistor
Resistor
Resistor
402
402
402
40.2 Ω, 1/16 W, 1%
100 kΩ, 1/16 W, 1%
24.9 Ω, 1/16 W, 1%
Panasonic
Panasonic
Panasonic
ERJ-2RKF40R2X
ERJ-2RKF1003X
ERJ-2RKF24R9X
30
31
3
1
R101, R201, R524, R603, R604
R102 to R04, R202, R508, R509,
R518, R4519
R301 to R304, R311, R313,
R314, R316, R521, R522
R309, R310
R317, R503
R401
R404, R405, R407, R408, R410,
R411, R413, R414
R406, R409, R412, R415
R502
R504, R506, R507, R510 to R515,
R520, R525, R526
R516, R517, R523
RZ101
Ferrite
Bead
Resistor
Resistor
Tantalum, 10 μF, 16 V,
10%
Ceramic, 1 μF, 10 V,
X5R, 10%
Tantalum, 1 μF, 16 V,
20%
Ceramic, 2.2 μF, 25 V,
X5R 10%
Ceramic, 12 pF,
NPO, 50 V, 5%
Schottky diode,
50 V, 2 A, SMC
Schottky diode,
30 V, 3 A, SMC
Green, 4 V 5 m,
candela
Switching, 75 V,
150 mA
6.0 V, 2.2 A trip current
resettable fuse
120-pin, female,
PC mount, right angle
RAPC722, power
supply connector
Male, straight,
100 mil
Male, straight, 100 mil
2-pin solder jumper,
0 Ω, 1/10 W, 5%
Male, straight, 100 mil
USB, PC mount, right
angle, Type B, female
500 mA, 600 Ω @
100 MHz
0 Ω, 1/16 W, 5%
10 kΩ, 1/16 W, 1%
Resistor
Resistor
402
Panasonic
Panasonic
ERJ-2RKF2001X
EXB-2HV220JX
32
1
S501
Switch
2 kΩ, 1/16 W, 1%
Resistor array, 22 Ω,
1/4 W, 5%
Momentary (normally
open), 100 GE, 5 mm,
SPST
Panasonic
EVQ-PLDA15
Rev. 0 | Page 23 of 28
SK33MSCT
LNJ314G8TRA
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
Item
33
Qty
1
Reference Designation
T301
Device
Choke
Package
2020
34 1
2
U101, U201
IC
TQFP80
35
1
U102
IC
SOIC20
36
1
U301
IC
SOIC16
37
38
39
40
41
1
1
1
1
1
U302
U401
U402
U403
U501
IC
IC
IC
IC
IC
SOIC14
SO8M1
TSSOP20
SO8M1
SOT23L5
42
1
U502
IC
TQFP128
43
44
1
1
U503
U504
IC
IC
DIP8
DCT_8PIN_06,
5 mm
45
1
U505
IC
SOIC 14
46
1
U601
IC
DIP20/SOL
47
1
VR301
IC
SOT-223HS
48
49
1
6
Y501
See schematic for placement
Crystal
Connector
50
4
Standoff
51
2
Insert from bottom side of
board
See schematic for placement
Crystal
100 mil
jumper
Plastic mount
standoffs
Third-row
header key
1
Connector
Description
10 μH, 5 A, 50 V,
190 Ω @ 100 MHz
3.3 V,
IDT72V283L7-5PF
74VHC541,
octal buffer/line
driver, three-state
DS90LV048A
74VCX86
MC100EPT22D
MC100EP29DT
MC100EPT23D
NC7SZ32M5,
NC7SZ32, tiny log
UHS 2-input or gate
CY7C68013
Manufacturer
Murata
Mfg Part Number
DLW5BSN191SQ2L
IDT
IDT72V283L7-5PF
Fairchild
74VHC541M
National
Semiconductor
Fairchild
Motorola
ON Semiconductor
Motorola
Fairchild
DS90LV048A
24LC00P
SN74LVC2G74DCTR,
D-type flip-flop,
DCT_8PIN_0.65MM
74LVQ04SC, low
voltage hex inverter
74LCX574WM-ND,
74LCX574 octal D-type
flip-flop
High accuracy,
ADP3339AKC-3.3, 3.3 V
Oscillator, 24 MHz
0.1” jumpers
Microchip
Texas Instruments
CY7C68013-128AXC
or
CY7C68014A-128AXC
24LC00P
SN74LVC2G74DCTR
Fairchild
74LVQ04SC
Fairchild
74LCX574WM-ND
Analog Devices
ADP3339AKC-3.3
Ecliptek
Samtec
EC-12-24.000M
SNT-100-BK-G-H
7/8” height, standoffs
Richco
CBSB-14-01A-RT
These header inserts
for J104, Pin 81, and
Pin 120 are located
on the edges of the
top row
Samtec
TSW-104-07-T-S
Only U201 is populated for the single-channel version (HSC-ADC-EVALB-SC).
Rev. 0 | Page 24 of 28
Cypress
74VCX86
MC100EPT22D
MC100EP29DT
MC100EPT23D
NC7SZ32M5
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
ORDERING INFORMATION
ORDERING GUIDE
Model
HSC-ADC-EVALB-SC
HSC-ADC-EVALB-DC
HSC-ADC-FPGA-4/-8
HSC-ADC-FPGA-9289
AD922XFFA 1
AD9283FFA1
AD9059FFA1
AD9051FFA1
LG-0204A1
1
Description
Single FIFO Version of USB Evaluation Kit
Dual FIFO Version of USB Evaluation Kit
Quad/Octal Serial LVDS to Dual Parallel CMOS Interface; supports all Quad/Octal ADCs in this family except
the AD9289 (not Included in Evaluation Kit)
Quad Serial LVDS to Dual Parallel CMOS Interface for the AD9289 Only (Not Included in Evaluation Kit)
Adapter for AD922x Family (Not Included in Evaluation Kit)
Adapter for the AD9283 and AD9057 (Not Included in Evaluation Kit)
Adapter for the AD9059 (Not Included in Evaluation Kit)
Adapter for the AD9051 (Not Included in Evaluation Kit)
Adapter for the AD10xxx and AD13xxx Families (Not Included in Evaluation Kit)
If an adapter is needed, send an email to highspeed.converters@analog.com.
ESD CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on
the human body and test equipment and can discharge without detection. Although this product features
proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy
electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance
degradation or loss of functionality.
Rev. 0 | Page 25 of 28
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
NOTES
Rev. 0 | Page 26 of 28
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
NOTES
Rev. 0 | Page 27 of 28
HSC-ADC-EVALB-SC/HSC-ADC-EVALB-DC
NOTES
©2006 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
EB05870-0-2/06(0)
Rev. 0 | Page 28 of 28