Leaderboard


Popular Content

Showing content with the highest reputation since 12/13/18 in all areas

  1. 3 points
    Ciprian

    Digital Twin

    Hi @Kris Persyn, It depends on how you manage your resources, driving immersive visuals on a HDMI display can be done in multiple ways at different resolutions, some are PL taxing others are DDR taxing; you could generate entire frame buffers in PL or PS or you could find a optimal algorithm to change just the previous frame or you could allocate a high number of frame buffers and then run them in a loop. It also depends on how math lab synthesizes the IP you will need to add to your design. If you design your project properly and don't aim for a resolution higher more 720p( I'm being conservative, we managed to drive the HDMI at 1080p with processing filters without a problem) I think it should be enough for what you want to do, resource wise. My suggestion, download and install Vivado, download and install the board files, create and implement your project look at the resource consumption and then buy a board. - Ciprian
  2. 3 points
    In your constraint file, the ddc pins have lowercase "ddc_scl_io" and "ddc_sda_io". Your block design has the port in uppercase "DDC". The case must match. Try editing your constraint file to have "DDC_scl_io" and "DDC_sda_io".
  3. 3 points
    jpeyron

    pmod wifi

    Hi @harika, I believe the HTML web page error is related to the materials on the SD card. 1) Please attach a screen shot of the contents of the Sd card you are using. 2) Please follow the YouTube video here from about 6 minutes and 28 seconds on for how to set up the HTTP server project. Make sure to update the login an password for the router/modem you are using. thank you, Jon
  4. 2 points
    JColvin

    Read from MicroSD in HDL, Write on PC

    Hi @dcc, I'm not certain how you are verifying that the HDL is writing to and then reading back from the SD card in a normal formatting style, but in general FAT32 is a widely used format for SD cards that has existing material for it. I am uncertain why you are using a special tool to write to the SD card though; from what I can tell the tool is Windows compatible, so why not just use the Notepad program which comes with Windows and save a .txt file with the data you are interested in reading to the SD card or just using Windows Explorer (the file manager) to move the file of interest onto the SD card? If you do have a header in your file, you will need to take account for that, though I do not know what you mean by "random file" in this case. Thanks, JColvin
  5. 2 points
    SeanS

    Genesys 2 DDR Constraints

    Hi JColvin, I am definitely not using ISE. I think JPeyron had it correctly. I didn't have my board.Repopaths variable set and so the project wasn't finding the board files. Once I set this variable as suggested, the pin mapping and IO types were auto populated as expected. Kudos, Sean
  6. 2 points
    @jpeyron @D@n I fixed the bug in my SPI Flash controller design. Now I can read from Flash memory.
  7. 2 points
    Hi @Blake, I was struggling with the same problem. In Adam's project is mistake which result is an FMC-HDMI module is not recognizable by other devices. The reason for that is not sending EDID at all. The cause of this situation is wrong initialized EDID map. In Adams example EDID is initialized by: but the correct way is: the body of iic_write2 is from LK example: By the way, in LucasKandle example initialization is done in same way as in Adam's example so is the reason why it not worked in your case. I hope it will helps. If you want I will post my working code for a ZedBoard with FMC-HDMI when I clean it because at the moment is kind of messy.
  8. 2 points
    Hi, there's a lot of new information in your last post. You aren't just "trying" FPGA but have a professional interest in Zynq. Don't let anybody scare you it's "difficult" and go for it, possibly with the cheapest board, no tutorials and low expectations like, blinking LEDs for quite a while. Given the price tag of any industrial training coarse, an FPGA board for self-study is a no-brainer. Maybe save some money to buy your FPGA engineer a coffee once a week, with some questions in mind
  9. 2 points
    True. Zygot believes that making you work for knowledge is kinder than giving you solutions that can be used to mindlessly resolve your problem of the hour.... it's just a different philosophical bent...
  10. 2 points
    kwilber

    Pmod DA3 clocking

    It looks to me like DA3_WriteSpi() was adapted from code for a different device and has vestigial and incorrect code. Reviewing the AD5541A datasheet, several things stand out There is only a single register in the chip so there is no need for the u8 reg parameter. There is no need for a"config byte" to be sent before the data. The transfer is always 16 bits so there is no need to allow for arbitrary length data quoting from the datasheet "Input data is framed by the chip select input, CS. After a high-to-low transition on CS, data is shifted synchronously and latched into the serial input register on the rising edge of the serial clock, SCLK. After 16 data bits have been loaded into the serial input register, a low-to-high transition on CS transfers the contents of the shift register to the DAC register if LDAC is held low". Reviewing the PmodDA3 schematic, the ~LDAC signal is softly pulled to ground with a 10K resistor. So there is no need to explicitly toggle ~LDAC. What all this means is DA3_WriteSpi could be simplified to something like void DA3_WriteSpi(PmodDA3 *InstancePtr, u16 wData) { u8 bytearray[2]; bytearray[0] = ((wData & 0xFF00) >> 8); bytearray[1] = (wData & 0xFF); XSpi_Transfer(&InstancePtr->DA3Spi, bytearray, 0, sizeof(bytearray)); } You would then call it passing in just the instance pointer and the value you want to write to the DAC. u16 dacValue = 1234; DA3_WriteSpi(&myDevice, dacValue); I do not have a PmodDA3 on my bench so I cannot verify the function works, You can give it a try and let us know how it goes.
  11. 2 points
    JColvin

    Pin Mapping for JTAG-SMT3-NC

    Hi @RussGlover, I apologize for the delay; the details you are looking are as follows: TCK - ADBUS0 TDI - ADBUS1 TDO - ADBUS2 TMS - ADBUS3 OEJTAG - ADBUS7 OESRSTN - ACBUS4 Let me know if you have any more questions. Thanks, JColvin
  12. 2 points
    kwilber

    Pmod DA3 clocking

    It seems to me the AXI Quad SPI block is sending address + data. Looking at the .xci file again, I see C_SPI_MEM_ADDR_BITS set to 24 bits. So 24 bits of address and 16 bits of data would yield 40 bits.
  13. 2 points
    kwilber

    Pmod DA3 Pinout

    That is one of the conventions commonly used to indicate an Active Low signal. So in this case, you pull Chip Select low when you want to access the chip. After you have toggled in all the data bits on the DIN line, you pull LDAC low. The Pmod DA3 reference manual has a link to the D/A chip's datasheet. That is the best first place to look for information on the device's function. The required signal timings are on page 5 of the datasheet.
  14. 2 points
    @Ahmed Alfadhel If you installed Vivado then you also installed the Xilinx Document Navigator. If you are serious about developing with FPGA devices you need to know how to find and access the plethora of documents that your vendor provides in order to use their devices properly. Check the box for 7 Series devices to see the list of reference manuals, User's Guides, Datasheets etc. From there you can add all relevant documents to your search and keep up to date. Do the same for ISE or Vivado tools. This is where everyone needs to start their Xilinx FPGA journey. Xilinx makes it easier than other FPGA vendors to obtain knowledge.
  15. 2 points
    The hot plug detect should be on the rx side. The source will see that and will then initiate the DDC conversation.
  16. 2 points
    The answer is yes, that fixed it! Thank you so much! The odd thing is that I tried this in one of my attempts and put it back to QSPI as it didnt work. Regardless thank you so very much for walking me through this. all looks good now:
  17. 2 points
    So the picture that you post of a (relatively) gigantic scope probe clip resting on a fairly small FPGA device in a BGA package is a way of making a statement. It might also be viewed as a picture that might be making a statement to you. I routinely use an LED to verify that my design is at least being clocked properly. Make a 32-bit counter and connect bit 26 or so to an obuf driving one of the boards LEDs. You can get an approximation of a 1 blink/s LED rate with a little math depending on the clock rate and the chosen counter bit. For me the clock rate of interest isn't the external clock coming into the FPGA but some clock output of an MMCM or PLL that I'm using for my design. If the LED is blinking then I at least know that something is alive in my design. You've got to be careful with those large scope probe grabbers around fine pitch components. I prefer to bring out a few debug versions of particular signals of interest to a PMOD and connect that to a scope probe ( the PMOD has DGND pin(s) ). You still have to exercise some caution with the ground clip on your scope probe as it's easy to short an adjacent pin to ground and ruin your day. It would be very useful if Digilent provided GND test points, or at least holes for test points, in an area of their boards for scope probing. The safest thing might be to stick a pin into the GND receptacle of one PMOD connector and probe on signals in another. Insulation stripped off suitably sized wires can help as well to keep ground clips from accidents. It's really easy to have that ground clip pop off whatever it's connect to and bounce around on exposed parts of your board; nothing good will come of that. I limit scope probing to when it's necessary. There are usually safer ways to evaluate signals in your FPGA design. Lastly, you should understand that its very easy to get a false impression of what a signal looks like, especially with normal scope probe ground clips. Think Heisenberg.
  18. 2 points
    Ciprian

    Hdmi out from zybo

    Try adding this: &i2c0 { clock-frequency = <100000>; status = "okay"; }; Here: <petalinux_project>/project-spec/meta-user/recipes-bsp/device-tree/files/system-user.dtsi -Ciprian
  19. 2 points
    xc6lx45

    Cmod S6 - Multilayer?

    You might go to Texas Instruments' site (or AD or both) and find documentation for some $500 high frequency ADC or DAC eval board as example to study.. There's nothing wrong with copper planes, generally. Free-standing structures (such as non-connected filler polygons) can be bad, if they resonate. So are loops if the driving wire spans an area together with the GND return wire (for which the ground plane is an obvious solution). The worst resonators have high quality factor meaning loose coupling meaning it can be surprising how the energy managed to couple in. There's no such thing as too many ground vias... Note, your ground plane can do very interesting things in combination with the metal box it's in (resonant cavity) but that's a different story.
  20. 2 points
    The warning you pasted is benign and simply means there are no ILAs present in your design. The real issue could be your clock. You should review the datasheet for the dvi2rgb.Table 1 in section 5 specifies RefClk is supposed to be 200Mhz. Also, your constraint should follow the recommendation in section 6.1 for a 720p design. Finally, @elodg gives some great troubleshooting information in this thread.
  21. 2 points
    And.... I have this sense that if you keep describing what you did you will answer your own question. I don't have enough information yet to help. [I confess that I haven't bothered to read through your code] Verbalizing problems, if you go into enough detail, is often a fairly reliably way to resolve them. Sometimes it helps to have someone throw in a good question or two.
  22. 2 points
    zygot

    Cmod S6 - Multilayer?

    Consider that the FPGA on your module has 196 balls. The A7 versions have 236. You can answer your own question by thinking about how one gets all of those surface mount pads to ground, voltage and signal traces.
  23. 2 points
    You are not wrong - but for that device ID the tooling will not let you use all the LUTs present on the silicon die. It is a somewhat artificial restriction, and might have some implications for the power and thermal properties of the package (e.g. a smaller package may not be able to dissipate the heat).
  24. 2 points
    Hi, Abdul, Here are my notes/recommendations: 1. Open your block diagram in Vivado where you created BRAM configuration and then check the address editor. You should see whether the BRAM address was assigned. If you find assigned see axi_bram_ctrl_0 OffsetAdress and the Range then the BRAM was created and mapped to the memory. 2. Writing and reading from BRAM requires a clock signal. Check Xilinx templates for BRAM which you can access inside the Vivado. I am not sure that the code you've used to write into BRAM does anything. 3. You don't use an absolute address in your HDL when BRAM created in Vivado. Vivado maps the address 0x4000_0000 to 0. So you can start from the address 0 and it will be the lowest address of the BRAM. If your don't use Vivado then you will need to define your block in HDL and include addresses, and many other parameters. 4. The C-code in SDK should use BRAM address from the file parameters.h. You just need to use XPAR_AXI_BRAM_CTRL_0_S_AXI_BASEADDR as the begining of the BRAM address space. 5. You can treat BRAM as RAM meaning that all read/write operators are the same. For example you can copy BRAM content into the RAM: for(i = 0 ; i < BRAM_SIZE ; i++) *(destination + i) = *(source + i); where source = XPAR_AXI_BRAM_CTRL_0_S_AXI_BASEADDR Disclaimer: always read documentation, whatever you find on Internet might not be correct. Good luck!
  25. 2 points
    Hi @akhilahmed, In the mentioned video tutorial, the leds are controlled using "xgpio.h" library but the application is standalone. If you want to use a linux based application you have to use linux drivers for controlling. In the current Petalinux build, which is used in SDSoC platform, UIO driver is the best approach. Steps: 1. Vivado project generation: - Extract .dsa archive from /path_to_sdsoc_platform/zybo_z7_20/hw/zybo_z7_20.dsa - Launch Vivado - In Tcl Console: cd /path_to_extracted_dsa/prj - In Tcl Console: source rebuild.tcl - In this point you should have the vivado project which is the hardware component of SDSoC platform. Open Block Design. Change to Address Editor Tab. Here you will find the address for axi_gpio_led IP: 0x4122_0000 2. Petalinux UIO driver: - Launch SDx - Import zybo-z7-20 SDSoC platform - Create a new SDx linux based project using a sample application (e.g. array_zero_copy) - Build the project - Copy the files from /Dubug/sd_card to SD card - Plug the SD card in Zybo Z7. Make sure that the JP5 is set in SD position. Turn on the baord - Use your favorite serial terminal to interact with the board (115200, 8 data bits, 2 stop bits, none parity) - cd to /sys/class/uio - if you run ls you will get something like: uio0 uio1 uio2 uio3 uio4 uio5 - Now you have to iterate through all these directories and to search for the above mentioned axi_gpio_led address: 0x4122_0000 - For example: cat uio0/maps/map0/addr will output: 0x41220000, which means that the axi_gpio_led can be accessed using linux uio driver through uio0 device. - Code: #include <stdio.h> #include <stdlib.h> #include <sys/ioctl.h> #include <sys/mman.h> #include <stdint.h> #include <unistd.h> #include <fcntl.h> #define UIO_MEM_SIZE 65536 #define UIO_LED_PATH "/dev/uio0" void UioWrite32(uint8_t *uioMem, unsigned int offset, uint32_t data) { *((uint32_t*) (uioMem+offset)) = data; } uint32_t UioRead32(uint8_t *uioMem, unsigned int offset) { return *((uint32_t*) (uioMem+offset)); } void led_count_down(uint8_t *ledMem) { uint8_t count = 0xF; uint8_t index = 0; for (index = 0; index < 5; index++) { UioWrite32(ledMem, 0, count); count = count >> 1; sleep(1); } } int main() { // Set Leds as output int led_fd = open(UIO_LED_PATH, O_RDWR); uint8_t *ledMem = (uint8_t *) mmap( 0, UIO_MEM_SIZE, PROT_READ | PROT_WRITE, MAP_SHARED, led_fd, (off_t)0); UioWrite32(ledMem, 4, 0x0); // Set all leds as output while(1) { // Start led count-down led_count_down(ledMem); } return 0; } - Build the project and copy the content of Debug/sd_card on SD sd_card - Power on the board and connect to it using a serial terminal - run the following commands: mount mmcblk0p1 /mnt cd /mnt ./project_name.elf - Result: A countdown should be displayed on leds.
  26. 2 points
    Hi @Ben B, Regarding your question on using Zybo Z7-20 to capture HDMI signals. It is possible and using UIO is also an option, but because we are using the VDMA to get the Video signal it's better to use a DMA driver. Unfortunately Xilinx does not provide a complete DMA driver for any of their DMA IPs, therefore I have been using this DMA driver which includes the VDMA functionality as well. To make things as easy as possible, I generated a example project for you with the VDMA used to capture video streams and OpenCV functions to write a *.bmp file. What you need to do in order to get it working is: 1. load the HDMI2BMP.elf to /home/root on your rootfs portion of your board 2. after the board boots you need to load the axi_dma_driver root@Zybo-Z7-20:~# insmod /lib/modules/4.9.0-xilinx-v2017.4/extra/xilinx-axidma.ko 3. run the HDMI2BMP.elf This will generate a test.bmp in /home/root with the captured image. The source file for the app is in the SDK folder. Changes which I had to do to the original petalinux project are: - create a new module in petalinux petalinux-create -t modules -n xilinx-axidma --enable - copy the necessary file to Petalinux-Zybo-Z7-20/Zybo-Z7-20/project-spec/meta-user/recipes-modules/xilinx-axidma/files and update the MAKE file and the xilinx-axidma.bb - update the system-user.dtsi in /Petalinux-Zybo-Z7-20/Zybo-Z7-20/project-spec/meta-user/recipes-bsp/device-tree/files - write the demo program Hope this helps. -Ciprian Zybo-Z7-20-HDMI-RX_peta.zip
  27. 2 points
    >> having about 60uF of ceramic decoupling goodness Maybe it's even more a question of ESR than capacitance. Ceramic if money doesn't matter (e.g. Mouser: 22 µF: €4..6). The typical solution are staggered capacitors, with a quick look at the datasheet for the self resonance frequency in the impedance curve. I do this for RF (try to get a quality short at n GHz...) but if I had to make a blind guess, I'd use two orders of magnitude, e.g. 10 µ, 100n, 1n and with a nervous glance at my Voodoo doll, 10p. The CMOD A7 is reported quite frequently (possibly because it's one of the most attractive boards) but I can tell that I've run into the same issues with FTDI's reference module for the 2232H. The chip just shuts down if it doesn't like what it sees on VCC. It took a long Friday night in the lab to prove without doubt that our system is sensitive to USB cables. We changed the design and shipped with non-detachable cable. Zero issues so far.
  28. 2 points
    HI @yottabyte, I realize (based on the time stamps) that you figured out the answer to your question before you got a response, but do you mind posting your original question and what you found out so any future users with a similar question would be able to see the answer you (and xc6lx45) found out? Thanks, JColvin
  29. 2 points
    attila

    WaveForms beta download

    3.11.4 digilent.waveforms_beta_v3.11.4_64bit.exe Added: - Scope: - set/reset zero offset in each channel option - precision option for measurements Fixed: - Script: access to traces and channels from Instrument.Export - unit conversions V to Ṽ, A to à - I2S 32 bit data 3.11.3 digilent.waveforms_beta_v3.11.3_64bit.exe digilent.waveforms_beta_3.11.3_amd64.deb digilent.waveforms_beta_3.11.3.x86_64.rpm Fixes 3.11.2 digilent.waveforms_beta_v3.11.2_64bit.exe digilent.waveforms_beta_3.11.2_amd64.deb digilent.waveforms_beta_3.11.2.x86_64.rpm Added: - Spectrum, Network and Impedance Analyzer store time data when this view is open Fixed: - runscript argument - loading of docked views geometry 3.11.1 digilent.waveforms_beta_v3.11.1_64bit.exe digilent.waveforms_beta_3.11.1_amd64.deb digilent.waveforms_beta_3.11.1.x86_64.rpm Added: - Scope: out of range warning in measurements - Protocol/UART: - support up to 32bit/word - TX/RX format: text, binary, decimal, hex - Wheel Direction option - Logic Analyzer: option to swap previous/next events - Spectrum Analyzer: allowing higher number of BINs for CZT 3.10.7 digilent.waveforms_beta_v3.10.7_64bit.exe Added: - Spectrum: logarithmic magnitude scale for voltage units - Protocol: datetime stamp for SPI/I2C Spy Fixes 3.10.6 digilent.waveforms_beta_v3.10.6_64bit.exe Added: - Scope - access to digital channels from custom mathematic channels - digital measurements view Fixes 3.10.5 digilent.waveforms_beta_v3.10.5_64bit.exe digilent.waveforms_beta_3.10.5_amd64.deb digilent.waveforms_beta_3.10.5.x86_64.rpm Added: - Power Supplies for AD2: tracking, slider, min/max - Logic Analyzer: Measurements - Impedance Analyze: DC mode compensation - SDK VB wrapper, C# wrapper updated Fixed: - EExplorer Wavegen AM/FM index precision for sine 3.10.4 digilent.waveforms_beta_v3.10.4_64bit.exe Fixed: - decimal resolution in Export, Data and Event views 3.10.3 digilent.waveforms_beta_v3.10.3_64bit.exe digilent.waveforms_beta_v3.10.3.dmg digilent.waveforms_beta_3.10.3_amd64.deb digilent.waveforms_beta_3.10.3.x86_64.rpm Added: - UART format option (binary, decimal...) - SDK I2C without clock stretching - SDK examples: Digital_I2c_PmodAcl.py, Digital_I2c_PmodGyro.py - Spectrum Analyzer THDN measurement, THDp and THDNp in percentage units - Impedance Analyzer: - constant current, voltage, custom script for amplitude and resistance control - Option to disable mouse drag and wheel operations on plots - Impedance/Network Analyzer: averaging time - Wavegen: extended frequency option Changed: - special values (none, off) moved to end of the preset list 3.10.2 digilent.waveforms_beta_v3.10.2_64bit.exe digilent.waveforms_beta_v3.10.2_32bit.exe digilent.waveforms_beta_v3.10.2.dmg digilent.waveforms_beta_v3.10.2_mavericks.dmg digilent.waveforms_beta_3.10.2_amd64.deb digilent.waveforms_beta_3.10.2_i386.deb digilent.waveforms_beta_3.10.2.x86_64.rpm digilent.waveforms_beta_3.10.2.i686.rpm Added: - Impedance Analyzer - voltage, current and custom plots - edit Meter list - Resistance mode for Meter, Frequency DC option - step mode in Time view - Netowrk Analyzer - step mode in Time and FFT views - amplitude table and custom function Fixed: - Help minor fix - Protocol SPI and I2C Sensor rate improvement - StaticIO button lock 3.8.22 digilent.waveforms_beta_v3.8.22_64bit.exe digilent.waveforms_beta_v3.8.22_32bit.exe Added: - Impedance differential setup, W1-C1P-DUT-C1N-C2-R-GND 3.8.21 digilent.waveforms_beta_v3.8.21_64bit.exe digilent.waveforms_beta_v3.8.21_32bit.exe digilent.waveforms_beta_v3.8.21.dmg digilent.waveforms_beta_3.8.21_amd64.deb digilent.waveforms_beta_3.8.21_i386.deb digilent.waveforms_beta_3.8.21.x86_64.rpm digilent.waveforms_beta_3.8.21.i686.rpm Added: - data property for impedance/network channels. - Impedance.Resistor.reference property - instruments accessible without index in Script tool like Scope. Fixes... 3.8.20 digilent.waveforms_beta_v3.8.20_64bit.exe Added: - Logger function access to other channels value, average, min, max - Script access to Logger channel set data property, getting average, minimum, maximum Fixed: - Logger Show/Maximum - Script Protocol.I2C.Clear() function 3.8.18 digilent.waveforms_beta_v3.8.18_64bit.exe digilent.waveforms_beta_v3.8.18_32bit.exe digilent.waveforms_beta_v3.8.18.dmg Added: - Network Analyzer - logarithmic scale and percentage unit - spectrum measurements: Carrier, THD+N, THD, HD# - FFT view - Averaging option 3.8.17 digilent.waveforms_beta_v3.8.17_64bit.exe digilent.waveforms_beta_v3.8.17_32bit.exe digilent.waveforms_beta_v3.8.17.dmg digilent.waveforms_beta_3.8.17_amd64.deb digilent.waveforms_beta_3.8.17_i386.deb digilent.waveforms_beta_3.8.17.x86_64.rpm digilent.waveforms_beta_3.8.17.i686.rpm Added: - Scope - persistence support for smooth curve and min/max sampling - custom math - current value in custom math function, can be used for averaging - initialization code for integration purposes - examples - unit presets for: ohm, degree, VAC, AAC - Spectrum - Import/Export samples for Traces - trace information option - Range option to adjust all the scope input ranges - Network and Spectrum - Script support for set magnitude property - Step size and steps per decade settings - Network Analyzer - custom plots: THD, HD2, HD3 - Protocol - I2C/Spy glitch filter based on frequency setting - Device options - On Close: Run (keep running), Stop, Shutdown - USB Power: Always ON or Stop with AUX for AD2 - USB Limit: USB current limitation AD1,2 - Audio Output: AD1, 2 - WaveForms SDK FDwfParamSet/Get, FDwfDeviceParamSet/Get - DwfParamOnClose, DwfParamUsbPower, DwfParamLedBrightness, DwfParamAudioOut, DwfParamUsbLimit - Notes toolbar show/hide option - on/off icon for toggle buttons: supply enable, network analyzer reference... - show entire capture button Changed: - renewed mouse wheel, drag and key (left,right,up,down) operation on plots and axis Fixed: - EExplorer output glitch during first device connection - NI VI crash when initializing without device connected - Scope XY plot 3.8.11 digilent.waveforms_v3.8.11_64bit.exe digilent.waveforms_v3.8.11_32bit.exe digilent.waveforms_v3.8.11.dmg digilent.waveforms_3.8.11_amd64.deb digilent.waveforms_3.8.11_i386.deb digilent.waveforms_3.8.11.x86_64.rpm digilent.waveforms_3.8.11.i686.rpm Added: - Digital Discovery: - LED brightness option - Logic Analyzer - ASCII format for: Bus, SPI, I2C, I2S - Format option for I2C - Logic Analyzer and Patterns - Line Color option - Protocol - Format option for SPI and I2C: Hexadecimal, Decimal, Binary, ASCII - Plot Width option in application settings Changed: - drawing quality improvement for thicker lines - color dialog buttons renamed to Close and Reset 3.8.9 digilent.waveforms_v3.8.9_64bit.exe digilent.waveforms_v3.8.9_32bit.exe digilent.waveforms_v3.8.9.dmg digilent.waveforms_3.8.9_amd64.deb digilent.waveforms_3.8.9_i386.deb digilent.waveforms_3.8.9.x86_64.rpm digilent.waveforms_3.8.9.i686.rpm Added: - WF/Settings/Options: Locale with System or English US regional option, export and import options - SDK: FDwfParamSet/Get function - Scope: measurement resolution Fixed: - minor issues 3.8.8 digilent.waveforms_v3.8.8_64bit.exe digilent.waveforms_v3.8.8_32bit.exe digilent.waveforms_v3.8.8.dmg Added: - WF SDK: - examples updated to be Python v3 compatible - FDwfAnalogImpedance functions for impedance/network analysis - Protocol: CAN receiver filter by ID - Impedance: Export information about amplitude and offset Fixed: - WF SDK: FDwfDigitalSpi functions read MISO/RX 3.8.7 digilent.waveforms_v3.8.7_64bit.exe Fixed: - Scope: save/load of coefficients for custom Math channel filter 3.8.6 digilent.waveforms_v3.8.6_64bit.exe digilent.waveforms_3.8.6_amd64.deb Added: - Export: Wavegen and Supplies information added to Scope, Spectrum, Impedance, Network export comments Fixed: - Script Tool.exec timeout - CAN high polarity option in Protocol tool and WF SDK 3.8.5 digilent.waveforms_v3.8.5_64bit.exe Added - Script functions: getSaveFile, getOpenFile, getDirectory - Scope: multiple scales, zero offset - Notes view - Export options: notes, header as comment - Help tab: floating/undock option, find with highlight Fixed: - Impedance Analyzer frequency scale in export 3.7.22 digilent.waveforms_v3.7.22_64bit.exe digilent.waveforms_v3.7.22_32bit.exe digilent.waveforms_v3.7.22.dmg digilent.waveforms_3.7.22_amd64.deb digilent.waveforms_3.7.22_i386.deb digilent.waveforms_3.7.22.x86_64.rpm digilent.waveforms_3.7.22.i686.rpm Added - Scope/Logic View/Logging picture format - Script: - Export function for instruments - access to Protocol/UART/RX using Receiver, Receive and ReceiveArray functions, SendArray Fixed - Scope edge trigger position for all devices, when only one or two samples are above the threshold - other minor fixes 3.7.21 digilent.waveforms_v3.7.21_64bit.exe digilent.waveforms_v3.7.21_32bit.exe digilent.waveforms_3.7.21_amd64.deb digilent.waveforms_3.7.21_i386.deb digilent.waveforms_3.7.21.x86_64.rpm digilent.waveforms_3.7.21.i686.rpm Added - Wavegen dynamic configuration, adjustments without restarting the generator - SDK support for CAN bus TX, RX - more detail in Spectrum, Network and Impedance Analyzer export comments - import data orientation option Fixed - Network Analyzer Meter export and copy - Data Logger quick measurements - other fixes and optimizations 3.7.19 digilent.waveforms_v3.7.19-2_64bit.exe digilent.waveforms_v3.7.19-2_32bit.exe digilent.waveforms_v3.7.19.dmg digilent.waveforms_3.7.19-2_amd64.deb digilent.waveforms_3.7.19-2_i386.deb digilent.waveforms_3.7.19-2.x86_64.rpm digilent.waveforms_3.7.19-2.i686.rpm Added: - Logic I2S Show channel option - SDK functions for UART, SPI, I2C master and UART receiver Changed: - OS-X rollback to FTDI driver 1.2.2 Fixed: - Impedance Analyzer: save/load of views positions - other fixes and optimizations 3.7.15 digilent.waveforms_v3.7.15_64bit.exe digilent.waveforms_v3.7.15_32bit.exe Added: - Logic Analyzer: position (Nth word) option for SPI trigger on value - Impedance: Nyquist plot; settle time, minimum periods options - Wavegen, Network/Impedance Analyzer: external Amplification option - Tabbed/Docking window switching from main window Changed: - lower frequency limit for Scope, AWG, Network, Impedance Fixed: - 10ns delay in Logic Analyzer Sync and Protocol interface - Sound Card device CPU usage 3.7.14 digilent.waveforms_v3.7.14_64bit.exe digilent.waveforms_v3.7.14_32bit.exe Added: - Protocol I2C ACK/NAK last read byte option Changed: - Windows XP, Vista compatible FTDI driver in 32bit installer 3.7.13 digilent.waveforms_v3.7.13_64bit.exe digilent.waveforms_v3.7.13_32bit.exe digilent.waveforms_v3.7.13.dmg digilent.waveforms_3.7.13_amd64.deb digilent.waveforms_3.7.13_i386.deb digilent.waveforms_3.7.13.x86_64.rpm digilent.waveforms_3.7.13.i686.rpm Added: - Sound Card device of the computer can be used as Scope and Wavegen - Scope sampling clock for Electronics Explorer - Logic Analyzer data compression for recording, for Electronics Explorer - Scope and Wavegen support for 4th device configuration of Analog Discovery 1 & 2 - Scope Logging Repeat option - Scope Audio view: Stereo, Tempo options - MacOS option for application menu 3.7.12-2 digilent.waveforms_v3.7.12-2_64bit.exe Fixed: - Analog Discovery 2 configuration file descriptions 3.7.12 digilent.waveforms_v3.7.12_64bit.exe digilent.waveforms_v3.7.12_32bit.exe Added: - Scope sampling clock under time options, for Analog Discovery 1 & 2. The trigger IOs can be used as sample clock with delay and edge options. - Logic Analyzer data compression for recording, for Analog Discovery 1 & 2 Changed: - Windows installer: - embedded prerequisites: Windows Installer, Visual C++ Redistributable 9 32/64bit, 12 64bit - split installer for 32bit and 64bit WF applications, but the included WF runtime for custom applications support both architectures Fixed: - Logic Analyzer UART frame error threshold 3.7.10 digilent.waveforms_v3.7.10.exe Added: - Spectrum Analyzer Markers Fixed: - SDK Electronics Explorer enumeration - Scope Math channel unit presets 3.7.9 digilent.waveforms_v3.7.9.exe Fixing: - Logic Analyzer Event view double click for signals 3.7.8 digilent.waveforms_v3.7.8.exe Changed: - Impedance Analyzer: - view names - solid line for magnitude Fixed: - Impedance Analyzer admittance |Y| value 3.7.7 digilent.waveforms_v3.7.7.exe Added: - Scope and Logic trigger detector for trigger source Fixed: - warning message when connecting to EExplorer - Patterns trigger on Digital Discovery.
  30. 1 point
    If you want to set both pins at the same time, rather than in two separate statements, you could also do this: LATGSET = (1 << 15) | (1 << 6); // or 0b1000000001000000 These parts have registers that can do an atomic set/clear/invert, so that you don't have to do a read/modify/write of the register.
  31. 1 point
    CVu

    Nexys 2 - transistor part number

    Transistor has been replaced, board is back up and running. Thanks!
  32. 1 point
    kwilber

    Pmod DA3 clocking

    I included visualizations of the ~CS, SCLK and DIN lines in the logic analyzer trace I posted Tuesday at 2:51 AM. In the trace, MOSI is the DIN line, Enable is the ~CS line and Clock is the SCLK line. Did the Xilinx SDK report any errors while opening the workspace? Did you program the fpga from the SDK?
  33. 1 point
    >> But it will cost me a bomb and I need to be sure I am investing on the correct thing. My entry for the "shortest answer" competition: Get a CMOD A7 or similar. It's dirt cheap - consider it disposable and save the idea of buying something "more capable" for long term motivation. Starting with an expensive board, then being afraid to use it for fear of breaking it does not help with learning. Zynq is significantly more complex than Artix and the FPGA part is less accessible.
  34. 1 point
    kwilber

    Pmod DA3 clocking

    If you look in the PmodDA3_axi_quad_spi_0_0.xci you will see that it is using a sck_ratio of 16. In the AXI Quad SPI reference manual you will find and With your 50 Mhz clock, 50 Mhz / 16 = 3.125 Mhz.
  35. 1 point
    jpeyron

    Pmod DA3 clocking

    Hi @Ahmed Alfadhel, Here and here are good descriptions for the spi (Serial Peripheral Interface) and the spi modes. thank you, Jon
  36. 1 point
    attila

    dimensions of Digital Discovery 2

    Hi @FabianS DigitalDiscovery_revB_PCB.pdf USB Micro B DIP Type, 4 Pin, 2mm
  37. 1 point
    kwilber

    Simple HDMI pass through with NexysVideo

    Unfortunately, I do not have a NexysVideo board available. I have run the simple hdmi pass thru on both zybo and arty boards. Have you tried using a resolution of 720p yet? I find it useful to start with the lower frequencies first. Most sources and monitors have no trouble working with that.
  38. 1 point
    Hi @ebattaglia42, What operating system are you currently on? If you are Windows, can you attach a picture of what is shown in the Windows Device Manager and what you see in the WaveForms Device Manager (it should pop up when you initially connect the EE Board). The other thing I would suggest to try would be to use a different USB cable (make sure it's not just for charging only) and/or USB port on your computer as that is another source of error that is easy to check. Thank you, JColvin
  39. 1 point
    Hi @Danny Armstrong, 1) make sure you have added the vivado library to the ip repository by clicking into the project setting and selecting ip and adding the path to the vivado library on your PC in the IP Repository. 2) It is my understanding that you can add the pmod ip cores to the block design by clicking the add ip button and type pmod then select which pmod you would like to have added to the block design. thank you, Jon
  40. 1 point
    @askhunter, Are you asking how I created and named the hdmi_in and hdmi_out ports in the block design for my Zybo-Z7 project? If so, once I started a new project selecting the Zybo-Z7-20, I created an empty block design. I then selected the "Board" window. The Zybo-Z7-20 and its available components were listed. Under the HDMI branch, I double clicked on the "HDMI in" component and clicked on OK in the dialog that popped up. The DVI to RGB IP block was added to my block design along with the appropriate ports. I did the same thing for the "HDMI out" component. I did the same thing for the system clock component. Then I ran block automation to add the reset line then added connections between the blocks as necessary and ended up with this.
  41. 1 point
    laughing out loud ... Formula-1-performance is niche business, combine harvesters bring home the money, walking barefoot is the norm. And why not, I'm even discouraging people to touch it as long as a UART does the job. Same as with fast cars, speed is largely overrated. Those who know otherwise, you know who you are 🙂
  42. 1 point
    I'm having a hard time comprehending how this project has gotten only 200 or so looks and my demo project has 10X that. I suspect that views may not be a good metric for interest. No one's talking but I surmise that people (students) are getting some utility out of the terminal based UART user interface that I provide. I certainly do. Who knows? Will anyone take the time to provide feedback? Is there a Multiverse?
  43. 1 point
    Hi @Abdul Qayyum, Glad to hear you were able to resolve the issue. Thank you for sharing what you did to resolve the BRAM issue. thank you, Jon
  44. 1 point
    JColvin

    Chipkit WF32 Wifi Communication

    Hi @Shahab Ahmed, Unfortunately, I do not believe there are any ready demos that use the WF32 WiFi chip and MPLAB X, aside from some examples from this thread, though it sounds like you have some material already. Otherwise I would recommend checking out this thread that also has a link to an Instructable tutorial that should be helpful. Thanks, JColvin
  45. 1 point
    Hi @Abdul Qayyum, Glad to hear that you were able to move forward with your project! thank you, Jon
  46. 1 point
    jpeyron

    Source Code in SDK

    Hi @Ahmed Alfadhel, Looking through your previous post it appears that I gave you an incorrect generic IP core. The Pmod DA3 communicates through SPI as shown on the Pmod DA3 resource center here and not through GPIO. I have attached the correct generic SPI IP Core below. J6 is a SPI connector typically associated with the Arduino/Chipkit header and used with a shield like the MTDS. Most of the Digilent SPI Pmod IP Cores are designed to use SPI through the Pmod Ports instead of the J6 connector. thank you, Jon PmodDA3_v1_0.zip
  47. 1 point
    Hi All, Hereby two video's of my ZedBoard with an ad-fmcomms3-ebz daughter board from Analog Devices. Although the AD9361 is capable of much more and this is my first experiment with a SDR I'm exited to show you my progress with this simple demonstration of a FM broadcast modulator and demodulator, using a ZedBoard with Analog Devices ad-fmcomms3-ebz FMC daughter card. Greets, Iw@n
  48. 1 point
    shahbaz

    How to read from SD card on ZYBO

    Hi, I want to read a .txt file from a SD card and load it into a register vector. is this possible? because I've read somewhere that file handling can only be done at simulation time to load values/inputs from files. basically I want to display a 16-bit colored image on LCD using VGA on ZYBO. I've extracted the R, G, B values from each pixel using MATLAB and now I want to assign them to respective r, g, b vector of each pixel which can only be done using file handling, since MATLAB exports these values to .txt file
  49. 1 point
    shahbaz

    How to read from SD card on ZYBO

    hi @jpeyron, I followed the guide at GitHub under Readme in PMODSD. can you please guide me step wise on how to start from block design and than going to SDK and running the demo. I have added the pmodsd and zynq PS IPs, after auto connection and running the generate bitstream I get following error. I need your guidance at this
  50. 1 point
    @Ajay Ghodke, For being new, you've picked a pretty challenging project! Reading an image from an SD card requires several layers of processing. The first part is the physical layer. The specification outlines one of two means of communicating with a cards physical layer: using the SDIO protocol (a four-wire, bidirectional data/command channel), and using the SPI protocol. I have personally built a Verilog core that communicates over the SPI protocol, and you are welcome to use my core, while other's have done their work with SDIO and ... I haven't tried their cores so I cannot speak to it. Across this physical layer, and to get things up and running, a protocol handshake must take place between the card and the controller. This handshake is outlined in the physical specification above, and also in the instructions for the controller I just mentioned. For a given card, the handshake isn't all that difficult. Indeed, for a given class of cards it's probably not that bad. To process every possible SD card, finding appropriate examples to test with can be a challenge--just to prove that you can handle all the corner cases. Once you can handle communications at this level, you will then be able to read and write sectors from the SD card. The next level, beyond sectors, involves reading and understanding the partition table. This table will tell you where the file systems are on the SD card, and more specifically, what file systems are on the SD card. In general, most SD cards have only one file system on them so partition processing is pretty simple. That file system is a FAT filesystem--whether FAT16, FAT32, etc. I'm not certain. (I haven't gotten this far yet.) After the partition layer, you will need to process the file system. Assuming that your SD card has a FAT filesystem on it, there will be two types of files on the system: file containing directory entries, and other. These files may be found in any order on the SD card, as specified by the file allocation table. That table contains one entry per cluster on the file system, telling you that after you read the given cluster, where to find the next one. (Clusters are similar to sectors, but may be implemented as groups of sectors.) If the filesystem is in proper order, the last cluster will identify itself as the last cluster. So, the steps to processing this filesystem involve: Identifying which version of the FAT system you are working with Finding, from that information, the first cluster of the root directory Reading through the directory for the file you want. (Keep in mind, other clutsers to this directory may be out of order--you'll need to look up their locations in the table.) If your file is in a subdirectory, you'll have to find the subdirectory entry. Once you have the file (subdirectory) you want, you'll find a location on the disk where that file begins. (IIRC, it's the cluster number of the first sector of the file) You'll also find the length of the file (or subdirectory) you are interested in. If what you found was a subdirectory, and if it's the subdirectory your file is in (assuming it is in a subdirectory and not the main directory), you'll then need to repeat this process, reading the subdirectory "file" and looking for your file's entry. (Or perhaps looking for another subdirectory entry.) From the final entry, you will now know where to find the first cluster of your file, and the full length of the file in bytes. (It may be longer or shorter than the number of clusters allocated for it in the allocation table.) The file allocation table will tell you where to find subsequent clusters. If all you wish to do is to change the image in place, then you now know where to find all the pieces. At this point, you can change the file as it exists on the SD card at will. Creating new files on the SD card requires creating a directory entry that file, find empty clusters to hold the file, placing the number of the first cluster into the directory, adjusting the directory length, etc. It doesn't take long and this becomes an in-depth software task. I have seen some approaches where individuals have created their own partitions containing their own file system with their own format just to avoid all of this hassle, and to be successful doing this within a microcontroller. While doable, such solutions tend to be application specific. Hope this helps, Dan