Table of contents
Overview
Zynq PS Design with Linux Example.
Refer to http://trenz.org/te0726-info for the current online version of this manual and other available documentation.
Key Features
- VIDEO/AUDIO
- HDMI
- PetaLinux
- SD
- ETH
- USB
- I2C
- Special FSBL for QSPI programming
Revision History
| Date | Vivado | Project Built | Authors | Description |
|---|---|---|---|---|
| 2018-10-31 | 2018.2 | Oleksandr Kiyenko |
|
Design Revision History
Release Notes and Know Issues
| Issues | Description | Workaround | To be fixed version |
|---|---|---|---|
| No known issues | --- | --- | --- |
Known Issues
Requirements
Software
| Software | Version | Note |
|---|---|---|
| Vivado | 2018.2 | needed |
| SDK | 2018.2 | needed |
| PetaLinux | 2018.2 | needed |
Software
Hardware
Basic description of TE Board Part Files is available on TE Board Part Files.
Complete List is available on <design name>/board_files/*_board_files.csv
Design supports following modules:
| Module Model | Board Part Short Name | PCB Revision Support | DDR | QSPI Flash | Others | Notes |
|---|---|---|---|---|---|---|
| 01 | REV01 | 64MB LPDDR2 | 16MB | not included, user modifications are needed | ||
| r | REV02, REV03 | 128MB DDR3L | 16MB | not included, user modifications are needed | ||
| te0726-03m | m | REV02, REV03 | 512MB DDR3L | 16MB | ||
| te0726-03-07s-1c | 7s | REV03 | 512MB DDR3L | 16MB |
Hardware Modules
Design supports following carriers:
| Carrier Model | Notes |
|---|---|
| --- |
Hardware Carrier
Additional HW Requirements:
| Additional Hardware | Notes |
|---|---|
| USB Power | Use USB2.0 or higher for power supply via USB |
| USB Cable | Connect to USB2 or better USB3 Hub for proper power supply over USB |
| headphones |
Additional Hardware
Content
For general structure and of the reference design, see Project Delivery
Design Sources
| Type | Location | Notes |
|---|---|---|
| Vivado | <design name>/block_design <design name>/constraints <design name>/ip_lib | Vivado Project will be generated by TE Scripts |
| SDK/HSI | <design name>/sw_lib | Additional Software Template for SDK/HSI and apps_list.csv with settings for HSI |
| PetaLinux | <design name>/os/petalinux | PetaLinux template with current configuration |
| SDSoC | <design name>/../SDSoC_PFM | SDSoC Platform will be generated by TE Scripts or as separate download |
Design sources
Additional Sources
| Type | Location | Notes |
|---|---|---|
| init.sh | <design name>/misc/init_script | Additional Initialization Script for Linux |
Additional design sources
Prebuilt
File | File-Extension | Description |
|---|---|---|
| BIF-File | *.bif | File with description to generate Bin-File |
| BIN-File | *.bin | Flash Configuration File with Boot-Image (Zynq-FPGAs) |
| BIT-File | *.bit | FPGA (PL Part) Configuration File |
| DebugProbes-File | *.ltx | Definition File for Vivado/Vivado Labtools Debugging Interface |
| Diverse Reports | --- | Report files in different formats |
| Hardware-Platform-Specification-Files | *.hdf | Exported Vivado Hardware Specification for SDK/HSI and PetaLinux |
| LabTools Project-File | *.lpr | Vivado Labtools Project File |
| OS-Image | *.ub | Image with Linux Kernel (On Petalinux optional with Devicetree and RAM-Disk) |
| Software-Application-File | *.elf | Software Application for Zynq or MicroBlaze Processor Systems |
Prebuilt files (only on ZIP with prebult content)
Download
Reference Design is only usable with the specified Vivado/SDK/PetaLinux/SDx version. Do never use different Versions of Xilinx Software for the same Project.
Reference Design is available on:
Design Flow
Reference Design is available with and without prebuilt files. It's recommended to use TE prebuilt files for first lunch.
Trenz Electronic provides a tcl based built environment based on Xilinx Design Flow.
See also:
The Trenz Electronic FPGA Reference Designs are TCL-script based project. Command files for execution will be generated with "_create_win_setup.cmd" on Windows OS and "_create_linux_setup.sh" on Linux OS.
TE Scripts are only needed to generate the vivado project, all other additional steps are optional and can also be executed by Xilinx Vivado/SDK GUI. For currently Scripts limitations on Win and Linux OS see: Project Delivery Currently limitations of functionality
- _create_win_setup.cmd/_create_linux_setup.sh and follow instructions on shell:
- Press 0 and enter for minimum setup
- (optional Win OS) Generate Virtual Drive or use short directory for the reference design (for example x:\<design name>)
- Create Project
- Select correct device and Xilinx install path on "design_basic_settings.cmd" and create Vivado project with "vivado_create_project_guimode.cmd"
Note: Select correct one, see TE Board Part Files
- Select correct device and Xilinx install path on "design_basic_settings.cmd" and create Vivado project with "vivado_create_project_guimode.cmd"
- Create HDF and export to prebuilt folder
- Run on Vivado TCL: TE::hw_build_design -export_prebuilt
Note: Script generate design and export files into \prebuilt\hardware\<short dir>. Use GUI is the same, except file export to prebuilt folder
- Run on Vivado TCL: TE::hw_build_design -export_prebuilt
- Create Linux (uboot.elf and image.ub) with exported HDF
- HDF is exported to "prebuilt\hardware\<short name>"
Note: HW Export from Vivado GUI create another path as default workspace. - Create Linux images on VM, see PetaLinux KICKstart
- Use TE Template from /os/petalinux
- For 128MB and 64MB only:Netboot Offset must be reduced manually, see Config
- HDF is exported to "prebuilt\hardware\<short name>"
- Add Linux files (uboot.elf and image.ub) to prebuilt folder
- "prebuilt\os\petalinux\default" or "prebuilt\os\petalinux\<short name>"
Notes: Scripts select "prebuilt\os\petalinux\<short name>", if exist, otherwise "prebuilt\os\petalinux\default"
- "prebuilt\os\petalinux\default" or "prebuilt\os\petalinux\<short name>"
- Generate Programming Files with HSI/SDK
- Run on Vivado TCL: TE::sw_run_hsi
Note: Scripts generate applications and bootable files, which are defined in "sw_lib\apps_list.csv" - (alternative) Start SDK with Vivado GUI or start with TE Scripts on Vivado TCL: TE::sw_run_sdk
Note: See SDK Projects
- Run on Vivado TCL: TE::sw_run_hsi
Launch
Programming
Check Module and Carrier TRMs for proper HW configuration before you try any design.
Xilinx documentation for programming and debugging: Vivado/SDK/SDSoC-Xilinx Software Programming and Debugging
QSPI
- Connect JTAG and power on the carrier with module
- Open Vivado Project with "vivado_open_existing_project_guimode.cmd" or if not created, create with "vivado_create_project_guimode.cmd"
- Type on Vivado TCL Console: TE::pr_program_flash_binfile -swapp u-boot
Note: To program with SDK/Vivado GUI, use special FSBL (zynqmp_fsbl_flash) on setup
optional "TE::pr_program_flash_binfile -swapp hello_te0726" possible - Copy image.ub on SD-Card
- For correct prebuilt file location, see <design_name>/prebuilt/readme_file_location.txt
- Copy ffmpeg compatible video or aplay compatible audio file on SD
- Insert SD-Card
SD
Xilinx Zynq devices in CLG225 package do not support SD Card boot directly from ROM bootloader. Use QSPI for primary boot and SD for secondary boot (u-boot)
JTAG
Not used on this Example.
Usage
- Prepare HW like described in section Programming
- Connect UART USB (most cases same as JTAG)
- Insert SD Card with image.ub
- Power On PCB
Note: 1. Zynq Boot ROM loads FSBL from QSPI into OCM, 2. FSBL loads U-boot from QSPI into DDR, 3. U-boot load Linux from SD into DDR
Linux
- Open Serial Console (e.g. putty)
- Speed: 115200
- COM Port: Win OS, see device manager, Linux OS see dmesg |grep tty (UART is *USB1)
- Linux Console:
Note: Wait until Linux boot finished For Linux Login use:- User Name: root
- Password: root
- You can use a Linux shell now.
- I2C 1 Bus type: i2cdetect -y -r 5
Bus 0...5 possible - ETH0 works with udhcpc
- USB: insert USB device
- I2C 1 Bus type: i2cdetect -y -r 5
- Start Video with "play <video file>
- "play" is alias to ffmpeg with some parameters for video and audio, type "alias" to see configuration
- for videos with higher resolution, disable audio on ffmpeg configuration
- Start Audio with "aplay <audio files>
- Take image from camera (must be enabled with init.sh scripts):
- write image to webserver: fbgrab -d /dev/fb1 /srv/www/camera.png
- Display image on host PC: http://<ZynqBerry IP>/camera.png
System Design - Vivado
Block Design
Block Design
PS Interfaces
Activated interfaces:
| Type | Note |
|---|---|
| DDR | --- |
| QSPI | MIO |
| USB0 | MIO, ETH over USB |
| SD1 | MIO |
| UART1 | MIO |
| I2C0 | EMIO |
| I2C1 | MIO |
| GPIO | MIO / EMIO |
| USB RST | MIO |
| TTC0..1 | MIO |
| WDT | MIO |
| AXI HP0..1 | |
| DMA0..1 |
PS Interfaces
Constraints
Basic module constraints
_i_bitgen_common.xdc
# # Common BITGEN related settings for TE0726 # set_property BITSTREAM.GENERAL.COMPRESS TRUE [current_design] set_property CONFIG_VOLTAGE 3.3 [current_design] set_property CFGBVS VCCO [current_design] set_property BITSTREAM.CONFIG.UNUSEDPIN PULLUP [current_design]
Design specific constraint
_i_common.xdc
# # # set_property BITSTREAM.CONFIG.UNUSEDPIN PULLUP [current_design]
_i_te0726.xdc
#set_property IOSTANDARD LVCMOS33 [get_ports spdif_tx_o]
#set_property PACKAGE_PIN K15 [get_ports spdif_tx_o]
set_property IOSTANDARD LVCMOS33 [get_ports {GPIO_1_tri_io[*]}]
# GPIO Pins
# GPIO2
set_property PACKAGE_PIN K15 [get_ports {GPIO_1_tri_io[0]}]
# GPIO3
set_property PACKAGE_PIN J14 [get_ports {GPIO_1_tri_io[1]}]
# GPIO4
set_property PACKAGE_PIN H12 [get_ports {GPIO_1_tri_io[2]}]
# GPIO5
set_property PACKAGE_PIN N14 [get_ports {GPIO_1_tri_io[3]}]
# GPIO6
set_property PACKAGE_PIN R15 [get_ports {GPIO_1_tri_io[4]}]
# GPIO7
set_property PACKAGE_PIN L14 [get_ports {GPIO_1_tri_io[5]}]
# GPIO8
set_property PACKAGE_PIN L15 [get_ports {GPIO_1_tri_io[6]}]
# GPIO9
set_property PACKAGE_PIN J13 [get_ports {GPIO_1_tri_io[7]}]
# GPIO10
set_property PACKAGE_PIN H14 [get_ports {GPIO_1_tri_io[8]}]
# GPIO11
set_property PACKAGE_PIN J15 [get_ports {GPIO_1_tri_io[9]}]
# GPIO12
set_property PACKAGE_PIN M15 [get_ports {GPIO_1_tri_io[10]}]
# GPIO13
set_property PACKAGE_PIN R13 [get_ports {GPIO_1_tri_io[11]}]
# GPIO16
set_property PACKAGE_PIN L13 [get_ports {GPIO_1_tri_io[12]}]
# GPIO17
set_property PACKAGE_PIN G11 [get_ports {GPIO_1_tri_io[13]}]
# GPIO18
set_property PACKAGE_PIN H11 [get_ports {GPIO_1_tri_io[14]}]
# GPIO19
set_property PACKAGE_PIN R12 [get_ports {GPIO_1_tri_io[15]}]
# GPIO20
set_property PACKAGE_PIN M14 [get_ports {GPIO_1_tri_io[16]}]
# GPIO21
set_property PACKAGE_PIN P15 [get_ports {GPIO_1_tri_io[17]}]
# GPIO22
set_property PACKAGE_PIN H13 [get_ports {GPIO_1_tri_io[18]}]
# GPIO23
set_property PACKAGE_PIN J11 [get_ports {GPIO_1_tri_io[19]}]
# GPIO24
set_property PACKAGE_PIN K11 [get_ports {GPIO_1_tri_io[20]}]
# GPIO25
set_property PACKAGE_PIN K13 [get_ports {GPIO_1_tri_io[21]}]
# GPIO26
set_property PACKAGE_PIN L12 [get_ports {GPIO_1_tri_io[22]}]
# GPIO27
set_property PACKAGE_PIN G12 [get_ports {GPIO_1_tri_io[23]}]
## DSI_D0_N
#set_property PACKAGE_PIN F13 [get_ports {GPIO_1_tri_io[24]}]
## DSI_D0_P
#set_property PACKAGE_PIN F14 [get_ports {GPIO_1_tri_io[25]}]
## DSI_D1_N
#set_property PACKAGE_PIN F12 [get_ports {GPIO_1_tri_io[26]}]
## DSI_D1_P
#set_property PACKAGE_PIN E13 [get_ports {GPIO_1_tri_io[27]}]
## DSI_C_N
#set_property PACKAGE_PIN E11 [get_ports {GPIO_1_tri_io[28]}]
## DSI_C_P
#set_property PACKAGE_PIN E12 [get_ports {GPIO_1_tri_io[29]}]
## CSI_D0_N
#set_property PACKAGE_PIN M11 [get_ports {GPIO_1_tri_io[30]}]
## CSI_D0_P
#set_property PACKAGE_PIN M10 [get_ports {GPIO_1_tri_io[31]}]
## CSI_D1_N
#set_property PACKAGE_PIN P14 [get_ports {GPIO_1_tri_io[32]}]
## CSI_D2_P
#set_property PACKAGE_PIN P13 [get_ports {GPIO_1_tri_io[33]}]
## CSI_C_N
#set_property PACKAGE_PIN N12 [get_ports {GPIO_1_tri_io[34]}]
## CSI_C_P
#set_property PACKAGE_PIN N11 [get_ports {GPIO_1_tri_io[35]}]
## PWM_R
##set_property PACKAGE_PIN N8 [get_ports {GPIO_1_tri_io[36]}]
## PWM_L
##set_property PACKAGE_PIN N7 [get_ports {GPIO_1_tri_io[37]}]
# PWM_R
set_property PACKAGE_PIN N8 [get_ports PWM_R]
# PWM_L
set_property PACKAGE_PIN N7 [get_ports PWM_L]
set_property IOSTANDARD LVCMOS33 [get_ports PWM_*]
_i_hdmi.xdc
set_property IOSTANDARD TMDS_33 [get_ports hdmi_clk_p]
set_property PACKAGE_PIN R7 [get_ports hdmi_clk_p]
set_property IOSTANDARD TMDS_33 [get_ports {hdmi_data_p[*]}]
set_property PACKAGE_PIN P8 [get_ports {hdmi_data_p[0]}]
set_property PACKAGE_PIN P10 [get_ports {hdmi_data_p[1]}]
set_property PACKAGE_PIN P11 [get_ports {hdmi_data_p[2]}]
_i_csi.xdc
set_property PACKAGE_PIN N11 [get_ports csi_c_clk_p]
set_property IOSTANDARD LVDS_25 [get_ports csi_c_clk_p]
set_property PACKAGE_PIN M9 [get_ports {csi_d_lp_n[0]}]
set_property IOSTANDARD HSUL_12 [get_ports {csi_d_lp_n[0]}]
set_property PACKAGE_PIN N9 [get_ports {csi_d_lp_p[0]}]
set_property IOSTANDARD HSUL_12 [get_ports {csi_d_lp_p[0]}]
set_property PACKAGE_PIN M10 [get_ports {csi_d_p[0]}]
set_property IOSTANDARD LVDS_25 [get_ports {csi_d_p[0]}]
set_property PACKAGE_PIN P13 [get_ports {csi_d_p[1]}]
set_property IOSTANDARD LVDS_25 [get_ports {csi_d_p[1]}]
set_property INTERNAL_VREF 0.6 [get_iobanks 34]
set_property PULLDOWN true [get_ports {csi_d_lp_p[0]}]
set_property PULLDOWN true [get_ports {csi_d_lp_n[0]}]
# RPI Camera 1
create_clock -period 6.250 -name csi_clk -add [get_ports csi_c_clk_p]
# RPI Camera 2.1
#create_clock -period 1.875 -name csi_clk -add [get_ports csi_c_clk_p]
_i_timing.xdc
set_property ASYNC_REG true [get_cells {zsys_i/audio/axi_i2s_adi_0/U0/ctrl/tx_sync/out_data_reg[4]}]
set_property ASYNC_REG true [get_cells {zsys_i/audio/axi_i2s_adi_0/U0/ctrl/SDATA_O_reg[0]}]
set_false_path -from [get_clocks clk_fpga_0] -to [get_clocks clk_fpga_3]
set_false_path -from [get_clocks clk_fpga_3] -to [get_clocks clk_fpga_0]
set_false_path -from [get_pins {zsys_i/axi_reg32_0/U0/axi_reg32_v1_0_S_AXI_inst/slv_reg16_reg[1]/C}] -to [get_pins zsys_i/video_in/axis_raw_demosaic_0/U0/colors_mode_i_reg/D]
set_false_path -from [get_pins zsys_i/video_in/csi_to_axis_0/U0/lane_align_inst/err_req_reg/C] -to [get_pins zsys_i/video_in/csi2_d_phy_rx_0/U0/clock_upd_req_reg/D]
set_false_path -from [get_pins {zsys_i/video_in/axi_vdma_0/U0/I_PRMRY_DATAMOVER/GEN_S2MM_FULL.I_S2MM_FULL_WRAPPER/GEN_INCLUDE_REALIGNER.I_S2MM_REALIGNER/GEN_INCLUDE_SCATTER.I_S2MM_SCATTER/sig_max_first_increment_reg[2]/C}] -to [get_pins zsys_i/video_in/axi_vdma_0/U0/I_PRMRY_DATAMOVER/GEN_S2MM_FULL.I_S2MM_FULL_WRAPPER/GEN_INCLUDE_REALIGNER.I_S2MM_REALIGNER/GEN_INCLUDE_SCATTER.I_S2MM_SCATTER/sig_btt_eq_0_reg/D]
set_false_path -from [get_pins {zsys_i/video_in/axi_vdma_0/U0/I_PRMRY_DATAMOVER/GEN_S2MM_FULL.I_S2MM_FULL_WRAPPER/GEN_INCLUDE_REALIGNER.I_S2MM_REALIGNER/GEN_INCLUDE_SCATTER.I_S2MM_SCATTER/sig_btt_cntr_dup_reg[1]/C}] -to [get_pins zsys_i/video_in/axi_vdma_0/U0/I_PRMRY_DATAMOVER/GEN_S2MM_FULL.I_S2MM_FULL_WRAPPER/GEN_INCLUDE_REALIGNER.I_S2MM_REALIGNER/GEN_INCLUDE_SCATTER.I_S2MM_SCATTER/sig_btt_eq_0_reg/D]
Software Design - SDK/HSI
For SDK project creation, follow instructions from:
Application
SDK template in ./sw_lib/sw_apps/ available.
zynq_fsbl
TE modified 2018.2 FSBL
- Changes:
- enable VTC and VDMA cores (fsbl_hooks.c)
zynq_fsbl_flash
TE modified 2018.2 FSBL
Changes:
- Set FSBL Boot Mode to JTAG
- Disable Memory initialization
u-boot
U-Boot.elf is generated with PetaLinux. SDK/HSI is used to generate Boot.bin.
hello_te0726
Hello TE0726 is a Xilinx Hello World example as an endless loop instead of one console output and TE FSBL screen on HDMI Monitor.
Software Design - PetaLinux
For PetaLinux installation and project creation, follow instructions from:
Config
For 64MB variant only:
- CONFIG_SUBSYSTEM_NETBOOT_OFFSET = 0x2000000
For 128MB variant only:
- CONFIG_SUBSYSTEM_NETBOOT_OFFSET = 0x4000000
U-Boot
No changes.
Device Tree
/include/ "system-conf.dtsi"
/ {
};
/ {
#address-cells = <1>;
#size-cells = <1>;
reserved-memory {
#address-cells = <1>;
#size-cells = <1>;
ranges;
hdmi_fb_reserved_region@1FC00000 {
compatible = "removed-dma-pool";
no-map;
// 512M (M modules)
reg = <0x1FC00000 0x400000>;
// 128M (R modules)
//reg = <0x7C00000 0x400000>;
};
camera_fb_reserved_region@1F800000 {
compatible = "removed-dma-pool";
no-map;
// 512M (M modules)
reg = <0x1F800000 0x400000>;
// 128M (R modules)
//reg = <0x7800000 0x400000>;
};
};
hdmi_fb: framebuffer@0x1FC00000 { // HDMI out
compatible = "simple-framebuffer";
// 512M (M modules)
reg = <0x1FC00000 (1280 * 720 * 4)>; // 720p
// 128M (R modules)
//reg = <0x7C00000 (1280 * 720 * 4)>; // 720p
width = <1280>; // 720p
height = <720>; // 720p
stride = <(1280 * 4)>; // 720p
format = "a8b8g8r8";
status = "okay";
};
camera_fb: framebuffer@0x1F800000 { // CAMERA in
compatible = "simple-framebuffer";
// 512M (M modules)
reg = <0x1F800000 (1280 * 720 * 4)>; // 720p
// 128M (R modules)
//reg = <0x7800000 (1280 * 720 * 4)>; // 720p
width = <1280>; // 720p
height = <720>; // 720p
stride = <(1280 * 4)>; // 720p
format = "a8b8g8r8";
};
vcc_3V3: fixedregulator@0 {
compatible = "regulator-fixed";
regulator-name = "vccaux-supply";
regulator-min-microvolt = <3300000>;
regulator-max-microvolt = <3300000>;
regulator-always-on;
};
};
&qspi {
#address-cells = <1>;
#size-cells = <0>;
status = "okay";
flash0: flash@0 {
compatible = "jedec,spi-nor";
reg = <0x0>;
#address-cells = <1>;
#size-cells = <1>;
spi-max-frequency = <50000000>;
partition@0x00000000 {
label = "boot";
reg = <0x00000000 0x00500000>;
};
partition@0x00500000 {
label = "bootenv";
reg = <0x00500000 0x00020000>;
};
partition@0x00520000 {
label = "kernel";
reg = <0x00520000 0x00a80000>;
};
partition@0x00fa0000 {
label = "spare";
reg = <0x00fa0000 0x00000000>;
};
};
};
/*
* We need to disable Linux VDMA driver as VDMA
* already configured in FSBL
*/
&video_in_axi_vdma_0 {
status = "disabled";
};
&video_out_axi_vdma_0 {
status = "disabled";
};
&video_out_v_tc_0 {
//xilinx-vtc: probe of 43c20000.v_tc failed with error -2
status = "disabled";
};
&gpio0 {
interrupt-controller;
#interrupt-cells = <2>;
};
&i2c1 {
#address-cells = <1>;
#size-cells = <0>;
i2cmux0: i2cmux@70 {
compatible = "nxp,pca9544";
#address-cells = <1>;
#size-cells = <0>;
reg = <0x70>;
i2c1@0 {
#address-cells = <1>;
#size-cells = <0>;
reg = <0>;
id_eeprom@50 {
compatible = "atmel,24c32";
reg = <0x50>;
};
};
i2c1@1 { // Display Interface Connector
#address-cells = <1>;
#size-cells = <0>;
reg = <1>;
};
i2c1@2 { // HDMI Interface Connector
#address-cells = <1>;
#size-cells = <0>;
reg = <2>;
};
i2c1@3 { // Camera Interface Connector
#address-cells = <1>;
#size-cells = <0>;
reg = <3>;
};
};
};
/{
usb_phy0: usb_phy@0 {
compatible = "ulpi-phy";
#phy-cells = <0>;
reg = <0xe0002000 0x1000>;
view-port = <0x0170>;
drv-vbus;
};
};
&usb0 {
usb-phy = <&usb_phy0>;
} ;
/*
* Sound configuration
*/
/{
// Custom driver based on spdif-transmitter
te_audio: dummy_codec_te {
compatible = "te,te-audio";
#sound-dai-cells = <0>;
};
// Simple Audio Card from AXI_I2S and custom XADC audio input and
// PWM audio output cores
sound {
compatible = "simple-audio-card";
simple-audio-card,name = "TE0726-PWM-Audio";
simple-audio-card,format = "i2s";
simple-audio-card,widgets =
"Microphone", "In Jack",
"Line", "Line In Jack",
"Line", "Line Out Jack",
"Headphone", "Out Jack";
simple-audio-card,routing =
"Out Jack", "te-out",
"te-in", "In Jack";
simple-audio-card,cpu {
sound-dai = <&audio_axi_i2s_adi_0>;
};
simple-audio-card,codec {
sound-dai = <&te_audio>;
};
};
};
&audio_axi_i2s_adi_0 {
compatible = "adi,axi-i2s-1.00.a";
reg = <0x43c00000 0x1000>;
clocks = <&clkc 15>, <&clkc 18>; // FCLK_CLK0, FCLK_CLK3
clock-names = "axi", "ref";
dmas = <&dmac_s 0 &dmac_s 1>;
dma-names = "tx", "rx";
#sound-dai-cells = <0>;
};
/*
* We need to disable Linux XADC driver to use XADC for audio recording
*/
&adc {
status = "disabled";
};
Kernel
Activate:
- CONFIG_XILINX_GMII2RGMII
- CONFIG_USB_USBNET
- CONFIG_USB_NET_SMSC95XX
- CONFIG_USBIP_CORE
- CONFIG_FB_SIMPLE
- CONFIG_SND_SIMPLE_CARD
- CONFIG_SND_SOC_ADI_AXI_I2S
Deactivate:
- FRAMEBUFFER_CONSOLE
Rootfs
Activate:
i2c-tools
alsa-plugins
alsa-lib-dev
libasound
alsa-conf-base
alsa-conf
alsa-utils
alsa-utils-aplay
busybox-httpd
Applications
startup
Script App to load init.sh from SD Card if available.
See: \os\petalinux\project-spec\meta-user\recipes-apps\startup\files
Add on new project:
- petalinux-create -t apps -n startup --enable
- copy/create startup app files
rpicam
Application used to enable and configure Raspbery Pi camera module
See: \os\petalinux\project-spec\meta-user\recipes-apps\rpicam\files
Add on new project:
- petalinux-create -t apps -n rpicam --enable
- copy/create rpicam app files
fbgrab
Application used to take screenshot from camera
See: \os\petalinux\project-spec\meta-user\recipes-apps\fgrab
Add on new project:
- petalinux-create -t apps -n rpicam --enable
- copy/create fbgrab app files
Kernel Modules
te-audio-codec
Simple module stab to use audio interface.
See: \os\petalinux\project-spec\meta-user\recipes-modules\te-audio-codec\files
Add on new project:
- petalinux-create -t modules -n te-audio-codec --enable
- copy/create te-audio-codec module files
Core base files
profile
Simple profile for alias
See: \project-spec\meta-user\recipes-core\base-files\files\profile
Add on new project:
- copy/create profile file
Additional Software
No additional software is needed.
Appx. A: Change History and Legal Notices
Document Change History
To get content of older revision got to "Change History" of this page and select older document revision number.
| Date | Document Revision | Authors | Description |
|---|---|---|---|
| |||
| -- | all | -- |
Document change history.
Legal Notices
Data Privacy
Please also note our data protection declaration at https://www.trenz-electronic.de/en/Data-protection-Privacy
Document Warranty
The material contained in this document is provided “as is” and is subject to being changed at any time without notice. Trenz Electronic does not warrant the accuracy and completeness of the materials in this document. Further, to the maximum extent permitted by applicable law, Trenz Electronic disclaims all warranties, either express or implied, with regard to this document and any information contained herein, including but not limited to the implied warranties of merchantability, fitness for a particular purpose or non infringement of intellectual property. Trenz Electronic shall not be liable for errors or for incidental or consequential damages in connection with the furnishing, use, or performance of this document or of any information contained herein.
Limitation of Liability
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Copyright Notice
No part of this manual may be reproduced in any form or by any means (including electronic storage and retrieval or translation into a foreign language) without prior agreement and written consent from Trenz Electronic.
Technology Licenses
The hardware / firmware / software described in this document are furnished under a license and may be used /modified / copied only in accordance with the terms of such license.
Environmental Protection
To confront directly with the responsibility toward the environment, the global community and eventually also oneself. Such a resolution should be integral part not only of everybody's life. Also enterprises shall be conscious of their social responsibility and contribute to the preservation of our common living space. That is why Trenz Electronic invests in the protection of our Environment.
REACH, RoHS and WEEE
REACH
Trenz Electronic is a manufacturer and a distributor of electronic products. It is therefore a so called downstream user in the sense of REACH. The products we supply to you are solely non-chemical products (goods). Moreover and under normal and reasonably foreseeable circumstances of application, the goods supplied to you shall not release any substance. For that, Trenz Electronic is obliged to neither register nor to provide safety data sheet. According to present knowledge and to best of our knowledge, no SVHC (Substances of Very High Concern) on the Candidate List are contained in our products. Furthermore, we will immediately and unsolicited inform our customers in compliance with REACH - Article 33 if any substance present in our goods (above a concentration of 0,1 % weight by weight) will be classified as SVHC by the European Chemicals Agency (ECHA).
RoHS
Trenz Electronic GmbH herewith declares that all its products are developed, manufactured and distributed RoHS compliant.
WEEE
Information for users within the European Union in accordance with Directive 2002/96/EC of the European Parliament and of the Council of 27 January 2003 on waste electrical and electronic equipment (WEEE).
Users of electrical and electronic equipment in private households are required not to dispose of waste electrical and electronic equipment as unsorted municipal waste and to collect such waste electrical and electronic equipment separately. By the 13 August 2005, Member States shall have ensured that systems are set up allowing final holders and distributors to return waste electrical and electronic equipment at least free of charge. Member States shall ensure the availability and accessibility of the necessary collection facilities. Separate collection is the precondition to ensure specific treatment and recycling of waste electrical and electronic equipment and is necessary to achieve the chosen level of protection of human health and the environment in the European Union. Consumers have to actively contribute to the success of such collection and the return of waste electrical and electronic equipment. Presence of hazardous substances in electrical and electronic equipment results in potential effects on the environment and human health. The symbol consisting of the crossed-out wheeled bin indicates separate collection for waste electrical and electronic equipment.
Trenz Electronic is registered under WEEE-Reg.-Nr. DE97922676.
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