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c19f811c4d
also known as POGO-V4-A3-02 or POGO-V4-A3-01 SoC: Marvell 88F6192 800Mhz SDRAM memory: 128MB Gigabit ethernet: 1 Marvell 88E1310 Flash memory: 128MB 2 status LEDs (one green one red) 1 "Eject" button on the back (used as "Reset" button) 1 USB 2.0 port (on upper side) 1 sata slot (power + data) for 2.5'' drives (upper side) 2 USB 3.0 ports from a controller on PCIe x1 of the SoC 1 full-size SDcard slot (fits a whole SD card into it) This device supports the (linux-only) kwboot tool to send a new uboot over serial console, so it is easy to unbrick in case the uboot is erased and the device won't boot. ----- Install instructions: ----- Since it's not possible to get ssh access to these devices, the only way to take control is to solder pins to get TTL serial access. Case can be opened by removing screws beneath two rubber feet at back of device, then lifting while prying the sides of the upper part out to unhook a latch on each side about 2/3rds of the way toward the front. Serial connection pins are those labeled "J11", left of SD as you face SD opening. Pins are (from left to right, i.e. the first in the list is the nearest to the SD slot) GND, Rx, Tx. Do not connect +V pin if you use a USB (self-powered) TTL-to-USB dongle. Any USB TTL-to-USB converter will work. Baud rate is 115200, parity "none", databits "8", flow control "none". Stock uboot is unable to read ubi partitions (nor usb) so we will replace it first with our uboot. Start a TFTP server at IP address 169.254.254.254, and place the uboot.kwb file in the folder of the server. Start the serial session and then power up the device. As soon as you see text on the serial start pressing random letter keys to stop the boot process. If you see something like the following line you can proceed: CE>> Otherwise if text is still scrolling by you missed the opportunity, pull the plug and try again. write printenv ethaddr The uboot will write something like this: ethaddr=00:50:43:00:02:02 This is the device's MAC address, also present in the sticker under the device. Write this down as we will need to add it in the new uboot configuration. Use the following commands to load the new uboot: tftp 0x20000 u-boot.kwb If the uboot confirms that the transfer was successful, then you can write it to flash with the following commands: nand erase 0 0x200000 nand write 0x20000 0 0x1c0000 if after the last command the uboot wrote "xxxx bytes written: OK" then it was written correctly and we can proceed. If it did not go well, try again or ask assistence in forums. Shutting down or rebooting at this time will brick the device, to unbrick it you will need to use the kwboot tool from a Linux PC or Virtual Machine. Now write: reset and press enter, the device will reboot and you should see again text scrolling by. Press a random key to stop it, and now you should see pogoplugv4> We now add the MAC address back, write: setenv ethaddr '00:50:43:00:02:02' Confirm that the uboot has understood by writing printenv ethaddr If all looks ok, save the setting with saveenv At this point the uboot is configured, and we only need to load the firmware in the flash memory. Follow the steps below in "Firmware recovery procedure". ---- Firmware recovery procedure ---- The new uboot allows easy recovery from a bad firmware upgrade where you can't access the device anymore over ssh or luci. Take a USB flash drive formatted as FAT32, and copy the initramfs image file in it (it will have "initramfs" in the file name), then rename it as "initramfs.bin". Insert the USB drive in the USB 2.0 port of the pogoplug (the port at the top). Power up the device, and wait for it to finish booting. The uboot should find and load the "initramfs.bin" from usb and if you are connected with serial you should see the linux kernel boot log (text scrolling by). Once it is done, press Enter and you will be greeted by the OpenWRT banner. If you were not connected with serial just wait a bit and, you will be able to access it with ssh or luci web interface (once you find its IP). The recovery "initramfs" images are run from RAM, so you will have to do a normal sysupgrade (firmware upgrade) to write a firmware image to flash memory. Signed-off-by: Alberto Bursi <alberto.bursi@outlook.it> |
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| config | ||
| include | ||
| package | ||
| scripts | ||
| target | ||
| toolchain | ||
| tools | ||
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| .gitignore | ||
| BSDmakefile | ||
| Config.in | ||
| feeds.conf.default | ||
| LICENSE | ||
| Makefile | ||
| README | ||
| rules.mk | ||
This is the buildsystem for the OpenWrt Linux distribution. Please use "make menuconfig" to choose your preferred configuration for the toolchain and firmware. You need to have installed gcc, binutils, bzip2, flex, python, perl, make, find, grep, diff, unzip, gawk, getopt, subversion, libz-dev and libc headers. Run "./scripts/feeds update -a" to get all the latest package definitions defined in feeds.conf / feeds.conf.default respectively and "./scripts/feeds install -a" to install symlinks of all of them into package/feeds/. Use "make menuconfig" to configure your image. Simply running "make" will build your firmware. It will download all sources, build the cross-compile toolchain, the kernel and all choosen applications. To build your own firmware you need to have access to a Linux, BSD or MacOSX system (case-sensitive filesystem required). Cygwin will not be supported because of the lack of case sensitiveness in the file system. Sunshine! Your OpenWrt Community http://www.openwrt.org