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Xilink Vivado » History » Revision 69

Revision 68 (Frédéric Blanc, 2023-09-07 10:43) → Revision 69/94 (Frédéric Blanc, 2023-10-23 14:56)

h1. Xilink Vivado 

 h2. installation Ubuntu 20.04 

 sur le site de xilinx telecharger: 
 https://www.xilinx.com/support/download.html 
 Xilinx Unified Installer 2020.1: Linux Self Extracting Web Installer 


 *en root* 

 <pre><code class="shell"> 
 sudo bash 
 export XILINXD_LICENSE_FILE=2100@flexalter.laas.fr 
 chmod +x Xilinx_Unified_2020.1_0602_1208_Lin64.bin 
 sudo ./Xilinx_Unified_2020.1_0602_1208_Lin64.bin 
 </code></pre> 
 echo $XILINXD_LICENSE_FILE 
 2100@flexalter.laas.fr 


 https://danielmangum.com/posts/vivado-2020-x-ubuntu-20-04/ 

 h2. installation Windows 


 h3. Vivado 2022.2 

 Windows 64-bit: Run the settings64.bat from the Vivado/<version> directory 

 On Windows, click Start > All Programs > Xilinx Design Tools > Vivado 2022.2 > Vivado 2022.2 Tcl Shell to launch the Vivado Design Suite Tcl shell. 

 <pre><code class="shell"> 
 dir D:\Public\RedPitaya-FPGA 
 vivado -source red_pitaya_vivado_project_Z10.tcl -tclargs v0.94 
 </code></pre> 

 !clipboard-202304201305-exdsl.png! 

 We recommend Vivado 2020.1 

 h3. Vivado 2020.1 

 h2. Création d'un nouveau projet 

 Create a new project with Vivado. 
 !clipboard-202306070934-1ikrj.png! 

 *Select the device xc7z010clg400-1* 

 Add the constraint redpitaya.xdc . 

 Create a new Block Design  
 !clipboard-202306070939-6delu.png! 

 *ERROR: Could not find a top module* 

 solution Create an HDL Wrapper. 
 !clipboard-202306201313-n0s0q.png! 

 

 h3. source  

 soource: https://github.com/lvillasen/RedPitaya-Hello-World 

 Clone the repositiry 

 Create a new project with Vivado. 
 !clipboard-202306070934-1ikrj.png! 

 *Select the device xc7z010clg400-1* 

 Add the constraint redpitaya.xdc . 

 Create a new Block Design  
 !clipboard-202306070939-6delu.png! 

 Add the IP called ZYNQ7 Processing System from the menu and Run Block Automation with default options. 

 Add Module counter.v from the menu. 

 clic doit  
 !clipboard-202304261446-zpxnx.png! 

 Add a Binary Counter from thr Add IP menu. 

 Add a port called led_o with components from 7 down to 0. 

 !clipboard-202304261452-qlhno.png! 

 connect 

 !clipboard-202304261515-hhbvn.png! 

 From the menu click on Validate Design 

 In 'Sources' go to 'IP Sources' right-click on 'project1' and select 'Create HDL Wraper' 

 !clipboard-202304261503-3iuu2.png! 

 Proceed to run Synthesis, Implementation and Bitstream Generation 

 Find the bitstream file (you may use the command 'find . -name *bit') 

 Transfer the bitstream file (*.bit) to the Red Pitaya (you may use *sftp root@rp-ip and put *.bit) 

 clic doit  
 !clipboard-202304261446-zpxnx.png! 

 Tcl Console 

 <pre><code class="shell"> 
 cd d:/Public/RedPitaya-FPGA/prj/Examples/Led_blink 
 source D:/Public/RedPitaya-FPGA/prj/Examples/Led_blink/make_project.tcl 
 </code></pre> 

 !clipboard-202304251008-te1ah.png! 
 pour éviter cette erreur copier le dossier core dans ../tmp/ 

 attachment:cores.zip 

 h4. Bitstream 

 le Bitstream ce trouve dans le dossier /.../RedPitaya/fpga/<project...>/<project...>.runs/impl_1 

 !clipboard-202304251107-19zhk.png! 


 le fichier bitstream doit être remplacer le fichier /dev/xdevcfg 


 *rp-ip 140.93.64.197* 

 Transfer the bitstream file (*.bit) to the Red Pitaya (you may use *sftp root@rp-ip and put *.bit) 

 Connect to the RedPitaya (ssh root@rp-ip) 

 Program the FPGA with the command cat file_name.bit > /dev/xdevcfg 

 h2. GPIO 


 h3. Console TCL 

 utilisation des exemples  

 https://github.com/RedPitaya/RedPitaya-FPGA 

 !clipboard-202306021352-vc13m.png! 

 utiliser les commandes suivante dans vivado console TCL 

 <pre><code class="shell"> 
 cd /tools/redpitaya/RedPitaya-FPGA-master/prj/Examples 
 source make_project.tcl 
 </code></pre> 
 cela va ouvrir le projet complet de Led_Blink 

 h3. GPIO 

 !clipboard-202306071537-n2vfw.png! 
 connecteur E1 
 exp_n_tri_io      (OUT) 
 exp_p_tri_io      (IN) 

 exp_n_tri_io[1.1] correspond a DIO1_N 
 !clipboard-202306081407-xqky7.png! 
 !clipboard-202306081409-vulz6.png! 
 exemple de slice pour extraire du vecteur exp_p_tri_io[7.0] le scalaire exp_p_tri_io[3.3] qui correspond au GPIO DIO3_P du connecteur E1 
 Slice pour démultiplexer le vecteur 
 Concat pour multiplexer 

 h3. FIFO 

 !clipboard-202306221115-rthjy.png! 
 IP FIFO generator 
 *IN* 
 !clipboard-202306151112-equbx.png! 
 *OUT* 
 !clipboard-202306151112-gvamj.png! 

 h3. Shift Register 

 !clipboard-202307041436-0ex9q.png! 

 h3. Block Memory Generator 

 !clipboard-202307041437-3fhkj.png! 

 h3. test clock 

 !clipboard-202309071030-znwjj.png! 
 clk_463157890Hz 

 h3. tuto Web 

 https://github.com/lvillasen/RedPitaya-Hello-World 

 https://redpitaya.readthedocs.io/en/latest/developerGuide/software/build/fpga/fpga.html 

 https://antonpotocnik.com/?p=487360 

 https://easytp.cnam.fr/alexandre/index_fichiers/support/zynq_cours_tp_vivado_zc702.pdf 

 http://jmfriedt.free.fr/redpitaya.pdf 

 http://staff.ltam.lu/feljc/electronics/redpitaya/RedPitayaScriptingSummary_1.pdf 

 RAM 

 https://community.element14.com/technologies/fpga-group/b/blog/posts/learning-xilinx-zynq-use-ram-design-for-altera-cyclone-on-vivado-and-pynq 

 https://elinux.org/Connect_a_ARM_Microcontroller_to_a_FPGA_using_its_Extended_Memory_Interface_%28EMI%29 

 http://islab.soe.uoguelph.ca/sareibi/TEACHING_dr/XILINX_VIVADO_dr/HwSw_dr/VivadoEmbeddedZyncTutorial.pdf