Run the Demonstration Standalone (AD463x)
The DataStorm DAQ development kit can be run as a standalone desktop computer. This hardware configuration requires a keyboard, mouse, and HDMI monitor
The AD463x demonstration uses AD4630-24® Evaluation Platform in this configuration which is comprised of the following components:
- Analog Devices EVAL-AD4630-24 (also known as EVAL-AD4630-24FMCZ) data converter board
- DataStorm DAQ (Trenz Intel® Cyclone® V SoC TEI0022 Development Board) (includes 12VDC power supply)
- Digilent® Analog Discovery 2 Signal Generator with dual outputs
- Digilent Discovery BNC adapter board
- Two (2) BNC Male to SMA Male Cable
- Monitor with HDMI input
- HDMI cable
- Keyboard and Mouse with USB connectors
- Separate Windows PC running Digilent WaveForms App
Select the SD card as the boot source for the processor.
The FMC_VADJ power rails provide power to the EVAL-AD4630-24FMCZ via the FMC interface. This is an adjustable voltage. It must be set to 3.3V. Modify the VID_SW DIP switch settings to select 3.3V.
Follow the steps in the order shown below.
- Insert the Micro SD card into the SD card slot
- Insert the EVAL-AD4630-24FMCZ FMC connector into the FMC mating connector on the DataStorm DAQ board
- Attach the monitor to the DataStorm DAQ using an HDMI cable
- Attach the keyboard and mouse to the DataStorm DAQ using any of the 4 USB ports
- Connect the Signal Generator to the EVAL-AD4630-24FMCZ SMA connectors
- Ensure that Jumper JP1 is at EN position as shown below
- Connect the power supply to the DataStorm DAQ
- Plug the AC-DC adapter into an AC outlet
The AD463x requires a differential signal from a signal source. The EVAL-AD4630-24FMCZ, in its default configuration, requires the input signal to be centered around VCM=2.5V (as in yellow tag #5 below). Connect the Differential signal source to IN0+/IN1+ and IN0-/IN1- inputs of EVAL-AD4630-24FMCZ.
The Analog Discovery 2 is used as a signal generator to drive the AD463x input.
Install (if not already done) the Digilent WaveForms App.
Open the WaveForms App and Click on Wavegen in the left margin which opens a waveform window
Click on Channels and select 1
Select Type as Sine
Select Frequency or Period
Set Amplitude to 1V
Set Offset to 2.5V
For Channel 2, Match the Channel 1 settings
Select the Phase to 180 degrees for Inverse signal
Click on No synchronization and select Synchronized
Click Run All
The HDL design supports the following interface and clock mode configurations:
| 1 Lane per channel | 2 Lane per channel | 4 Lane per channel | |
|---|---|---|---|
| SPI Mode | SDR | SDR | SDR |
| Echo Clock Mode | SDR & DDR | SDR & DDR | SDR & DDR |
| Master Clock Mode | SDR | SDR | SDR |
Power up the unit and wait approximately 60 seconds for the unit to be fully functional.
IIO Oscilloscope automatically launches during the Linux boot process. No further configuration is required, however the application also has a desktop icon in case the user needs to launch the application on demand.
Select a Plot Channel to be displayed in IIO Oscilloscope. Click on the check box in the Plot Channel window adjacent to voltage0. Right click on ad4630 in the Plot Channels window. Select voltage0 and rising edge as the trigger parameters.
Select an appropriate number of Time Domain samples in the Plot Type window. Press the Capture / Stop button to begin the capture process.
Change the capture mode to Frequency Domain. Select an FFT Size and Average. Press the Capture / Stop button to begin the capture process.
Right click in the IIO Oscilloscope plot area. Select Single Tone markers. Press the Capture / Stop button to begin the capture process with markers.
Note the information in the Marker window. This capture shows a signal source of 50 kHz with harmonic components.
NOTE: This demo has AD463x configured by default to receive 24-bit differential and 8-bit common mode data over 4-Lane on SPI Mode.
The LibIIO library API enables access to the converter data from C code, Python code, or MATLAB. A small sample of C and Python codes are provided for the reader and can be run natively on the DataStorm DAQ.
-
Open the Terminal. Double click on the 'Terminal Emulator' icon on the Desktop
$ cd examples/python-examples $ thunar
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Review the Python source code
- Double click on the file ad4630.py to review in the text editor - Select your preferred channel to obtain readings from that specific channel
NOTE: This demo has AD463x configured by default to receive 24-bit differential and 8-bit common mode data over 4-Lane on SPI Mode.
-
Run the Python source code
$ python3 ad4630.py
This capture shows a signal source of 50 kHz with its harmonic components.
NOTE: The following image shows the output data from Channel 0 of the 2 available channels in AD463x. The outputs from other channels can be obtained in a similar method by defining the relevant channel number in the given source code.
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Open the Terminal. Double click on the 'Terminal Emulator' icon on the Desktop
$ cd examples/c-examples $ thunar
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Review the C source code
- Double click on the file ad4630-iiostream.c to review in the text editor - Select your preferred channel in the CHANNEL_NUMBER constant to obtain readings from that specific channel
NOTE: This demo has AD463x configured by default to receive 24-bit differential and 8-bit common mode data over 4-Lane on SPI Mode.
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Compile the C source code (Use -liio flag to dynamically link the LibIIO libraries)
$ gcc ad4630-iiostream.c -o ad4630-iiostream -liio
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Run the C executable using sudo permissions. The password is analog.
$ sudo ./ad4630-iiostream
NOTE: The following image shows the output data from Channel 0 of the 2 available channels in AD463x. The outputs from other channels can be obtained in a similar method by defining the relevant channel number in the given source code.
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Power down the target. Launch a Root Terminal by double clicking on the root terminal icon. Type the following
$ poweroff -
Wait 30 seconds and then you can safely power down the DataStorm DAQ
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