Difference between revisions of "Vayu Cape SW images and drivers"
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− | Vayu capes | + | Vayu capes are fully supported for Debian Wheezy ARMHF ([https://www.debian.org/ports/arm/ Official Page]). The kernel tree is based on Robert C Nelson git tree and all the commits are based on the latest kernel. |
Kindly follow his wiki for detailed steps on how to compile the kernel from scratch. [http://eewiki.net/display/linuxonarm/BeagleBone+Black BBB-RobertCNelson-Main Wiki]. | Kindly follow his wiki for detailed steps on how to compile the kernel from scratch. [http://eewiki.net/display/linuxonarm/BeagleBone+Black BBB-RobertCNelson-Main Wiki]. | ||
− | We have | + | We have compiled a bootable microSD card image for easy plug and play demonstration of the Vayu 2G and 3G capes. Additionally we have outlined detailed step by step compilation of this image based on [http://eewiki.net/display/linuxonarm/BeagleBone+Black BBB-RobertCNelson-Main Wiki]. |
+ | If you are using distribution other than debian, the kernel patches are listed, kindly recompile your kernel based on directed patches, enable PPS support (if your capes have GPS timing module) and you should be ready to go. | ||
We know in world of Linux, things get a bit complicated, we have FAQ's which may help you to unblock, kindly follow these. | We know in world of Linux, things get a bit complicated, we have FAQ's which may help you to unblock, kindly follow these. | ||
− | + | == Ready to use downloadable Debian Wheezy image == | |
− | + | * To get started quickly, download and extract image file from the links given below and flash to a 4GB SD CARD. | |
− | + | * This prebuilt SD card image (4GB size) or EMMC flasher image already has all the required drivers and extra functions and packages to be used by the Cape. | |
− | + | ||
− | + | ||
− | + | ||
− | * The above image file has: | + | === Download Files: === |
− | ** PPS drivers, required by NTP server | + | |
− | ** USB drivers , required by | + | * Download these files from the dropbox: |
− | ** NTP server | + | ** '''<big>MicroSD card Image</big>''' [https://www.dropbox.com/s/fo61fldqha5pjl1/VAYU_Debian_bone70_061215.img.xz?dl=0 VAYU_Debian_bone70_061215.img.xz] and Latest one : [https://www.dropbox.com/s/bh3d9q0k15kiti8/VAYU_4.4_debian_16052017.img.xz?dl=0 VAYU_4.4_debian_16052017.img.xz] |
+ | ** '''<big>eMMC Flasher Image</big>''' [https://www.dropbox.com/s/t03kd8egc4pwqyy/Vayu_emmc_flasher_4GB_3.8.13bone32.img.xz Vayu_emmc_flasher_4GB_3.8.13bone32.img.xz] | ||
+ | ** '''<big>Overlay</big>''' [https://www.dropbox.com/s/hlm31vvhrc30rfj/BBB_VAYU-00A0.dtbo BBB_VAYU-00A0.dtbo file] (if using another image, place in /lib/firmware) | ||
+ | ** '''<big>Overlay</big>''' [https://www.dropbox.com/s/1i4u6k05odx5cg4/BBB_VAYU.dts BBB_VAYU.dts file] (for reference only) | ||
+ | <i> '''Note:''' The dts source file is here for reference only in case you wish to compile the overlay yourself with the dtc compiler.</i> | ||
+ | |||
+ | * Extract the image file from the above xz file and then flash it to a 4GB(atleast) sd card. Follow steps mentioned [http://elinux.org/Beagleboard:Updating_The_Software#Image_For_Booting_From_microSD here] for flashing and using the images. | ||
+ | ** For linux : | ||
+ | <pre> | ||
+ | unxz VAYU_Debian_bone70_061215.img.xz | ||
+ | sudo dd if=./VAYU_Debian_bone70_061215.img of=/dev/sdX | ||
+ | </pre> | ||
+ | :* Beaglebone Black will boot by default from MicroSD card flashed with '''MicroSD card Image''' , if present in its slot at bootup. With this option, the microSD card is essential and the eMMC is left untouched. | ||
+ | :* Beaglebone Black will also boot by default from MicroSD card flashed with '''eMMC Flasher Image''' but it will then '''Flash the eMMC''', a process that takes around 15 minutes. After flashing is complete, all the 4 LEDs will glow. You can then power off the board, '''remove microSD card''' and power up Beaglebone Black again. Now it will boot up from eMMC with our prebuilt image. With this option, a microSD card is no longer needed. | ||
+ | :* For more detailed instructions, follow this link [http://elinux.org/Beagleboard:Updating_The_Software Updating the Software] | ||
+ | |||
+ | * '''The precompiled image file has''': | ||
+ | ** PPS GPIO support using the dtbo file for initializing the device tree overlay. | ||
+ | ** PPS drivers, required by NTP server. | ||
+ | ** USB drivers , required by 3G(UMTS/CDMA) modem. | ||
+ | ** NTP server preconfigured ( if using GPS module) with servers set for Asia/India | ||
** PPPd/Wvdial tool to establish 2G and 3G connection (only Service provider data has to be updated) with sample provider files. We have included AT&T and T-Mobile wvdial conf sample files for US users. | ** PPPd/Wvdial tool to establish 2G and 3G connection (only Service provider data has to be updated) with sample provider files. We have included AT&T and T-Mobile wvdial conf sample files for US users. | ||
− | ** Helpful | + | ** Helpful scripts for operating GPIOs (under /root/bin for activating/reading pins directly) and applying overlays and pin settings at bootup (as /root/boot_run.sh ). |
− | + | ||
− | * <big> | + | === Basic steps for Using 3G (GSM/WCDMA) Modem === |
− | ** | + | |
− | ** | + | * <big>Attach cape to beaglebone black and boot up .</big> |
− | ** | + | ** '''Keep USB cable unattached''' initially from the Beaglebone Black host port. |
− | ** After | + | ** Place a data-enabled GSM mini-SIM in the SIM card slot. In case of CDMA, the RUIM can be placed in the same SIM card slot. |
+ | ** In the pre-built image, all the required pin initialization and device tree overlays are applied by commands in the crontab after bootup(of user root). | ||
+ | ** After bootup is complete, [http://www.elinux.org/Beagleboard:BeagleBoneBlack#Connecting_to_the_BeagleBone_Black:_Serial_Connection.2C_SSH.2C_or_USB login] to Beaglebone Black. | ||
+ | |||
+ | * <big>After logging in, turn on the modem by one of these options:</big> | ||
+ | ** '''Using Pre-built Image''' | ||
*** Pressing switch S1 for 4 seconds and releasing, or | *** Pressing switch S1 for 4 seconds and releasing, or | ||
*** Issue the commands: | *** Issue the commands: | ||
− | < | + | <pre> |
− | + | echo "high" > /sys/class/gpio/gpio45/direction | |
− | + | sleep 4 | |
− | + | echo "low" > /sys/class/gpio/gpio45/direction | |
− | </ | + | sleep 4 |
− | ** After some time, LED D4 should | + | echo "high" > /sys/class/gpio/gpio45/direction |
− | * | + | </pre> |
− | + | :* '''Using Another Image''' (without prebuilt USB drivers for GSM/WCDMA modem) | |
− | + | <pre> | |
− | + | cd /sys/class/gpio/ | |
− | + | echo 45 > export | |
+ | cd gpio45 | ||
+ | echo "high" > direction | ||
+ | sleep 4 | ||
+ | echo "low" > direction | ||
+ | sleep 4 | ||
+ | echo "high" > direction | ||
+ | </pre> | ||
+ | ::* After some time, LED D4 should turn on and glow continuously which indicates modem has turned on. This LED, '''NETLIGHT LED''' is a new feature and is functional in latest versions of the cape. Earlier, LED D4 remained off all the time. | ||
+ | ::* '''Now, attach usb cable between mini USB port (#16) of cape and host port of Beaglebone Black.''' Alternatively, if the USB host port on cape is also populated,then the USB cable can be kept intact before Board was booted up. | ||
− | === Compiling the SD card image from | + | * <big>Check that modem is visible on the USB bus by:</big> |
− | This section describes how to compile the Debian image from | + | <pre> |
+ | lsusb | ||
+ | |||
+ | Bus 001 Device 002: ID 0424:2412 Standard Microsystems Corp. | ||
+ | Bus 001 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub | ||
+ | Bus 002 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub | ||
+ | Bus 001 Device 007: ID 21f5:2012 | ||
+ | </pre> | ||
+ | |||
+ | *<big> You can also check that ports have been assigned for the modem by :</big> | ||
+ | ** '''Using Pre-built Image''' | ||
+ | <pre> | ||
+ | ls /dev/ttyUSB* | ||
+ | |||
+ | /dev/ttyUSB0 /dev/ttyUSB1 /dev/ttyUSB2 | ||
+ | </pre> | ||
+ | :* '''Using Another Image''' | ||
+ | <pre> | ||
+ | modprobe usbserial vendor=0x21f5 product=0x2012 | ||
+ | lsusb | ||
+ | |||
+ | Bus 001 Device 002: ID 0424:2412 Standard Microsystems Corp. | ||
+ | Bus 001 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub | ||
+ | Bus 002 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub | ||
+ | Bus 001 Device 007: ID 21f5:2012 | ||
+ | </pre> | ||
+ | ::* System messages show what happened after applying ''modprobe usbserial'' | ||
+ | <pre> | ||
+ | dmesg | grep -i usb | ||
+ | |||
+ | usb 1-1.1: New USB device found, idVendor=21f5, idProduct=2012 | ||
+ | usb 1-1.1: New USB device strings: Mfr=3, Product=2, SerialNumber=4 | ||
+ | usb 1-1.1: Product: StrongRising Technologies | ||
+ | usb 1-1.1: Manufacturer: Modem | ||
+ | usb 1-1.1: SerialNumber: 000000000002 | ||
+ | usb 1-1.1: usb_probe_device | ||
+ | usb 1-1.1: configuration #1 chosen from 1 choice | ||
+ | usb 1-1.1: adding 1-1.1:1.0 (config #1, interface 0) | ||
+ | usbserial_generic 1-1.1:1.0: usb_probe_interface | ||
+ | usbserial_generic 1-1.1:1.0: usb_probe_interface - got id | ||
+ | usbserial_generic 1-1.1:1.0: The "generic" usb-serial driver is only for testing and one-off prototypes. | ||
+ | usbserial_generic 1-1.1:1.0: Tell linux-usb@vger.kernel.org to add your device to a proper driver. | ||
+ | usbserial_generic 1-1.1:1.0: generic converter detected | ||
+ | usb 1-1.1: generic converter now attached to ttyUSB0 | ||
+ | usb 1-1.1: adding 1-1.1:1.1 (config #1, interface 1) | ||
+ | usbserial_generic 1-1.1:1.1: usb_probe_interface | ||
+ | usbserial_generic 1-1.1:1.1: usb_probe_interface - got id | ||
+ | usbserial_generic 1-1.1:1.1: The "generic" usb-serial driver is only for testing and one-off prototypes. | ||
+ | usbserial_generic 1-1.1:1.1: Tell linux-usb@vger.kernel.org to add your device to a proper driver. | ||
+ | usbserial_generic 1-1.1:1.1: generic converter detected | ||
+ | usb 1-1.1: generic converter now attached to ttyUSB1 | ||
+ | usb 1-1.1: adding 1-1.1:1.2 (config #1, interface 2) | ||
+ | usbserial_generic 1-1.1:1.2: usb_probe_interface | ||
+ | usbserial_generic 1-1.1:1.2: usb_probe_interface - got id | ||
+ | usbserial_generic 1-1.1:1.2: The "generic" usb-serial driver is only for testing and one-off prototypes. | ||
+ | usbserial_generic 1-1.1:1.2: Tell linux-usb@vger.kernel.org to add your device to a proper driver. | ||
+ | usbserial_generic 1-1.1:1.2: generic converter detected | ||
+ | usb 1-1.1: generic converter now attached to ttyUSB2 | ||
+ | </pre> | ||
+ | ::* '''It is recommended to add a proper driver for the modem in kernel. The generic driver is not reliable.''' | ||
+ | |||
+ | *<big> The modem is now ready for use with pon/poff(PPPd), Wvdial or any other dialer program.</big> | ||
+ | |||
+ | === Basic Steps for Using GPS === | ||
+ | |||
+ | * '''Using pre-built image.''' | ||
+ | In the pre-built image, the GPS device is enabled (in crontab under root) by default at bootup on the /dev/ttyO4 port. To quickly test the GPS, issue the following commands: | ||
+ | <pre> | ||
+ | stty -F /dev/ttyO4 raw 19200 | ||
+ | cat /dev/ttyO4 | ||
+ | </pre> | ||
+ | This should produce the text NMEA messages as received from the GPS device. | ||
+ | <pre> | ||
+ | $GPRMC,140615.00,A,2834.25835,N,07720.54109,E,0.033,53.14,240214,0.00,E,D,V*70 | ||
+ | $GPVTG,53.14,T,0.00,M,0.033,N,0.061,K,D*12 | ||
+ | $GPGGA,140615.00,2834.25835,N,07720.54109,E,1,11,0.80,199.5,M,-36.0,M,,*70 | ||
+ | $GPGSA,A,3,07,08,28,09,19,03,27,10,23,13,11,,1.81,0.80,1.62,1*1A | ||
+ | $GPGSV,4,1,15,13,72,176,32,07,53,346,48,19,52,080,38,03,40,052,39,1*69 | ||
+ | $GPGSV,4,2,15,23,37,159,33,28,31,255,42,08,29,313,45,27,25,046,37,1*65 | ||
+ | $GPGSV,4,3,15,09,23,312,43,11,22,135,28,10,17,260,33,16,08,049,10,1*65 | ||
+ | $GPGSV,4,4,15,01,03,150,22,05,00,312,,40,,,38,1*6C | ||
+ | $GPGLL,2834.25835,N,07720.54109,E,140615.00,A,D*64 | ||
+ | $GPZDA,140615.00,24,02,2014,-00,00*4F | ||
+ | </pre> | ||
+ | |||
+ | * '''Using another image.''' | ||
+ | To ensure that the GPS device is enabled, check the reset signal,'''GPIO 50'''. It should always be '''high''' and in output mode. | ||
+ | <pre> | ||
+ | cd /sys/class/gpio/ | ||
+ | echo 50 > export | ||
+ | cd gpio50 | ||
+ | echo "high" > direction | ||
+ | </pre> | ||
+ | |||
+ | Since the GPS device is attached to the generic /dev/ttyO4 serial port(UART4) on Beaglebone black, it is possible to access it without any special drivers. So we need to enable the device tree overlay for /dev/ttyO4 (uart4) on beaglebone black: | ||
+ | <pre> | ||
+ | cd /lib/firmware | ||
+ | echo BB-UART4 > /sys/devices/bone_capemgr.9/slots | ||
+ | stty -F /dev/ttyO4 raw 19200 | ||
+ | cat /dev/ttyO4 | ||
+ | </pre> | ||
+ | |||
+ | For more details, see [http://www.yantrr.com/wiki/Configuring_for_GPS_Location_and_Time_Synchronization Configuring for GPS Location and Time Synchronization]. | ||
+ | |||
+ | === Basic Steps for Using PPS === | ||
+ | |||
+ | For PPS support, it is essential to have PPS drivers enabled in the kernel. For this reason, it is advisable to use the pre-built kernel image or use another image verified to have PPS support built in already. Once this is done, the following steps can be executed: | ||
+ | |||
+ | * Enable PPS pin as interrupt (already done if booting with pre-built image): | ||
+ | <pre> | ||
+ | cd /lib/firmware | ||
+ | echo BBB_VAYU > /sys/devices/bone_capemgr.9/slots | ||
+ | </pre> | ||
+ | |||
+ | * Verify pps signal is activated in the kernel | ||
+ | <pre> | ||
+ | /usr/src/pps-tools/ppstest /dev/pps1 | ||
+ | </pre> | ||
+ | |||
+ | For more details, see [http://www.yantrr.com/wiki/Configuring_for_GPS_Location_and_Time_Synchronization Configuring for GPS Location and Time Synchronization]. | ||
+ | |||
+ | == Compiling the SD card image from scratch == | ||
+ | This section describes how to compile the Debian image from scratch to enable | ||
* PPS drivers, required by NTP server | * PPS drivers, required by NTP server | ||
− | * USB drivers , required by | + | * USB drivers , required by 3G(UMTS/CDMA) modem |
* Custom wvdial conf file to enable connections | * Custom wvdial conf file to enable connections | ||
− | * Device tree overlays to enable | + | * Device tree overlays to enable PPS GPIO support |
* Helpful scripts | * Helpful scripts | ||
− | Kindly follow this page for the detailed outlined steps - [[Compiling Yantrr Vayu Drivers on Debian Wheezy]] | + | Kindly follow this page for the detailed outlined steps - <big>'''[[Compiling Yantrr Vayu Drivers on Debian Wheezy]]'''</big> |
== Modifying your existing kernel or other distribution == | == Modifying your existing kernel or other distribution == | ||
− | If you are having your own branch of kernel and | + | If you are having your own branch of kernel and following some other linux distribution like Ubuntu, Angstrom, you can use following wiki to recompile the kernel to support Vayu capes. We dont officially support it, but hopefully would make it easier. |
+ | |||
+ | '''Note : ''' | ||
+ | |||
* Vayu 2G cape - These are fully supported in all linux distribution with device tree and overlay support, you just need the Vayu cape overlay to configure UART's | * Vayu 2G cape - These are fully supported in all linux distribution with device tree and overlay support, you just need the Vayu cape overlay to configure UART's | ||
* Vayu 2G + GPS capes - These need PPS support for GPIO in kernel, you may need to rebuilt your kernel to enable these, the details are outlined here from make menuconfig. | * Vayu 2G + GPS capes - These need PPS support for GPIO in kernel, you may need to rebuilt your kernel to enable these, the details are outlined here from make menuconfig. | ||
Line 56: | Line 213: | ||
Following wiki would help you in enabling these if you have correct tools to compile your kernel. | Following wiki would help you in enabling these if you have correct tools to compile your kernel. | ||
+ | |||
+ | <span style="color: red"> Coming soon .... </span> | ||
== FAQ's== | == FAQ's== |
Latest revision as of 06:21, 17 May 2017
Vayu capes are fully supported for Debian Wheezy ARMHF (Official Page). The kernel tree is based on Robert C Nelson git tree and all the commits are based on the latest kernel. Kindly follow his wiki for detailed steps on how to compile the kernel from scratch. BBB-RobertCNelson-Main Wiki.
We have compiled a bootable microSD card image for easy plug and play demonstration of the Vayu 2G and 3G capes. Additionally we have outlined detailed step by step compilation of this image based on BBB-RobertCNelson-Main Wiki. If you are using distribution other than debian, the kernel patches are listed, kindly recompile your kernel based on directed patches, enable PPS support (if your capes have GPS timing module) and you should be ready to go.
We know in world of Linux, things get a bit complicated, we have FAQ's which may help you to unblock, kindly follow these.
Contents
Ready to use downloadable Debian Wheezy image
- To get started quickly, download and extract image file from the links given below and flash to a 4GB SD CARD.
- This prebuilt SD card image (4GB size) or EMMC flasher image already has all the required drivers and extra functions and packages to be used by the Cape.
Download Files:
- Download these files from the dropbox:
- MicroSD card Image VAYU_Debian_bone70_061215.img.xz and Latest one : VAYU_4.4_debian_16052017.img.xz
- eMMC Flasher Image Vayu_emmc_flasher_4GB_3.8.13bone32.img.xz
- Overlay BBB_VAYU-00A0.dtbo file (if using another image, place in /lib/firmware)
- Overlay BBB_VAYU.dts file (for reference only)
Note: The dts source file is here for reference only in case you wish to compile the overlay yourself with the dtc compiler.
- Extract the image file from the above xz file and then flash it to a 4GB(atleast) sd card. Follow steps mentioned here for flashing and using the images.
- For linux :
unxz VAYU_Debian_bone70_061215.img.xz sudo dd if=./VAYU_Debian_bone70_061215.img of=/dev/sdX
- Beaglebone Black will boot by default from MicroSD card flashed with MicroSD card Image , if present in its slot at bootup. With this option, the microSD card is essential and the eMMC is left untouched.
- Beaglebone Black will also boot by default from MicroSD card flashed with eMMC Flasher Image but it will then Flash the eMMC, a process that takes around 15 minutes. After flashing is complete, all the 4 LEDs will glow. You can then power off the board, remove microSD card and power up Beaglebone Black again. Now it will boot up from eMMC with our prebuilt image. With this option, a microSD card is no longer needed.
- For more detailed instructions, follow this link Updating the Software
- The precompiled image file has:
- PPS GPIO support using the dtbo file for initializing the device tree overlay.
- PPS drivers, required by NTP server.
- USB drivers , required by 3G(UMTS/CDMA) modem.
- NTP server preconfigured ( if using GPS module) with servers set for Asia/India
- PPPd/Wvdial tool to establish 2G and 3G connection (only Service provider data has to be updated) with sample provider files. We have included AT&T and T-Mobile wvdial conf sample files for US users.
- Helpful scripts for operating GPIOs (under /root/bin for activating/reading pins directly) and applying overlays and pin settings at bootup (as /root/boot_run.sh ).
Basic steps for Using 3G (GSM/WCDMA) Modem
- Attach cape to beaglebone black and boot up .
- Keep USB cable unattached initially from the Beaglebone Black host port.
- Place a data-enabled GSM mini-SIM in the SIM card slot. In case of CDMA, the RUIM can be placed in the same SIM card slot.
- In the pre-built image, all the required pin initialization and device tree overlays are applied by commands in the crontab after bootup(of user root).
- After bootup is complete, login to Beaglebone Black.
- After logging in, turn on the modem by one of these options:
- Using Pre-built Image
- Pressing switch S1 for 4 seconds and releasing, or
- Issue the commands:
- Using Pre-built Image
echo "high" > /sys/class/gpio/gpio45/direction sleep 4 echo "low" > /sys/class/gpio/gpio45/direction sleep 4 echo "high" > /sys/class/gpio/gpio45/direction
- Using Another Image (without prebuilt USB drivers for GSM/WCDMA modem)
cd /sys/class/gpio/ echo 45 > export cd gpio45 echo "high" > direction sleep 4 echo "low" > direction sleep 4 echo "high" > direction
- After some time, LED D4 should turn on and glow continuously which indicates modem has turned on. This LED, NETLIGHT LED is a new feature and is functional in latest versions of the cape. Earlier, LED D4 remained off all the time.
- Now, attach usb cable between mini USB port (#16) of cape and host port of Beaglebone Black. Alternatively, if the USB host port on cape is also populated,then the USB cable can be kept intact before Board was booted up.
- Check that modem is visible on the USB bus by:
lsusb Bus 001 Device 002: ID 0424:2412 Standard Microsystems Corp. Bus 001 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub Bus 002 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub Bus 001 Device 007: ID 21f5:2012
- You can also check that ports have been assigned for the modem by :
- Using Pre-built Image
ls /dev/ttyUSB* /dev/ttyUSB0 /dev/ttyUSB1 /dev/ttyUSB2
- Using Another Image
modprobe usbserial vendor=0x21f5 product=0x2012 lsusb Bus 001 Device 002: ID 0424:2412 Standard Microsystems Corp. Bus 001 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub Bus 002 Device 001: ID 1d6b:0002 Linux Foundation 2.0 root hub Bus 001 Device 007: ID 21f5:2012
- System messages show what happened after applying modprobe usbserial
dmesg | grep -i usb usb 1-1.1: New USB device found, idVendor=21f5, idProduct=2012 usb 1-1.1: New USB device strings: Mfr=3, Product=2, SerialNumber=4 usb 1-1.1: Product: StrongRising Technologies usb 1-1.1: Manufacturer: Modem usb 1-1.1: SerialNumber: 000000000002 usb 1-1.1: usb_probe_device usb 1-1.1: configuration #1 chosen from 1 choice usb 1-1.1: adding 1-1.1:1.0 (config #1, interface 0) usbserial_generic 1-1.1:1.0: usb_probe_interface usbserial_generic 1-1.1:1.0: usb_probe_interface - got id usbserial_generic 1-1.1:1.0: The "generic" usb-serial driver is only for testing and one-off prototypes. usbserial_generic 1-1.1:1.0: Tell linux-usb@vger.kernel.org to add your device to a proper driver. usbserial_generic 1-1.1:1.0: generic converter detected usb 1-1.1: generic converter now attached to ttyUSB0 usb 1-1.1: adding 1-1.1:1.1 (config #1, interface 1) usbserial_generic 1-1.1:1.1: usb_probe_interface usbserial_generic 1-1.1:1.1: usb_probe_interface - got id usbserial_generic 1-1.1:1.1: The "generic" usb-serial driver is only for testing and one-off prototypes. usbserial_generic 1-1.1:1.1: Tell linux-usb@vger.kernel.org to add your device to a proper driver. usbserial_generic 1-1.1:1.1: generic converter detected usb 1-1.1: generic converter now attached to ttyUSB1 usb 1-1.1: adding 1-1.1:1.2 (config #1, interface 2) usbserial_generic 1-1.1:1.2: usb_probe_interface usbserial_generic 1-1.1:1.2: usb_probe_interface - got id usbserial_generic 1-1.1:1.2: The "generic" usb-serial driver is only for testing and one-off prototypes. usbserial_generic 1-1.1:1.2: Tell linux-usb@vger.kernel.org to add your device to a proper driver. usbserial_generic 1-1.1:1.2: generic converter detected usb 1-1.1: generic converter now attached to ttyUSB2
- It is recommended to add a proper driver for the modem in kernel. The generic driver is not reliable.
- The modem is now ready for use with pon/poff(PPPd), Wvdial or any other dialer program.
Basic Steps for Using GPS
- Using pre-built image.
In the pre-built image, the GPS device is enabled (in crontab under root) by default at bootup on the /dev/ttyO4 port. To quickly test the GPS, issue the following commands:
stty -F /dev/ttyO4 raw 19200 cat /dev/ttyO4
This should produce the text NMEA messages as received from the GPS device.
$GPRMC,140615.00,A,2834.25835,N,07720.54109,E,0.033,53.14,240214,0.00,E,D,V*70 $GPVTG,53.14,T,0.00,M,0.033,N,0.061,K,D*12 $GPGGA,140615.00,2834.25835,N,07720.54109,E,1,11,0.80,199.5,M,-36.0,M,,*70 $GPGSA,A,3,07,08,28,09,19,03,27,10,23,13,11,,1.81,0.80,1.62,1*1A $GPGSV,4,1,15,13,72,176,32,07,53,346,48,19,52,080,38,03,40,052,39,1*69 $GPGSV,4,2,15,23,37,159,33,28,31,255,42,08,29,313,45,27,25,046,37,1*65 $GPGSV,4,3,15,09,23,312,43,11,22,135,28,10,17,260,33,16,08,049,10,1*65 $GPGSV,4,4,15,01,03,150,22,05,00,312,,40,,,38,1*6C $GPGLL,2834.25835,N,07720.54109,E,140615.00,A,D*64 $GPZDA,140615.00,24,02,2014,-00,00*4F
- Using another image.
To ensure that the GPS device is enabled, check the reset signal,GPIO 50. It should always be high and in output mode.
cd /sys/class/gpio/ echo 50 > export cd gpio50 echo "high" > direction
Since the GPS device is attached to the generic /dev/ttyO4 serial port(UART4) on Beaglebone black, it is possible to access it without any special drivers. So we need to enable the device tree overlay for /dev/ttyO4 (uart4) on beaglebone black:
cd /lib/firmware echo BB-UART4 > /sys/devices/bone_capemgr.9/slots stty -F /dev/ttyO4 raw 19200 cat /dev/ttyO4
For more details, see Configuring for GPS Location and Time Synchronization.
Basic Steps for Using PPS
For PPS support, it is essential to have PPS drivers enabled in the kernel. For this reason, it is advisable to use the pre-built kernel image or use another image verified to have PPS support built in already. Once this is done, the following steps can be executed:
- Enable PPS pin as interrupt (already done if booting with pre-built image):
cd /lib/firmware echo BBB_VAYU > /sys/devices/bone_capemgr.9/slots
- Verify pps signal is activated in the kernel
/usr/src/pps-tools/ppstest /dev/pps1
For more details, see Configuring for GPS Location and Time Synchronization.
Compiling the SD card image from scratch
This section describes how to compile the Debian image from scratch to enable
- PPS drivers, required by NTP server
- USB drivers , required by 3G(UMTS/CDMA) modem
- Custom wvdial conf file to enable connections
- Device tree overlays to enable PPS GPIO support
- Helpful scripts
Kindly follow this page for the detailed outlined steps - Compiling Yantrr Vayu Drivers on Debian Wheezy
Modifying your existing kernel or other distribution
If you are having your own branch of kernel and following some other linux distribution like Ubuntu, Angstrom, you can use following wiki to recompile the kernel to support Vayu capes. We dont officially support it, but hopefully would make it easier.
Note :
- Vayu 2G cape - These are fully supported in all linux distribution with device tree and overlay support, you just need the Vayu cape overlay to configure UART's
- Vayu 2G + GPS capes - These need PPS support for GPIO in kernel, you may need to rebuilt your kernel to enable these, the details are outlined here from make menuconfig.
- Vayu 3G & 3G + GPS capes - These may need USB driver support in addition to GPS PPS support.
Following wiki would help you in enabling these if you have correct tools to compile your kernel.
Coming soon ....