A very simple and fully functional Raspberry Pi-based IP-KVM that you can make with your own hands. This device helps to manage servers or workstations remotely, regardless of the health of the operating system or whether one is installed. You can fix any problem, configure the BIOS, or even reinstall the OS using the included CD-ROM or Flash Drive emulation.
A ready-to-use OS that can be created just by running `make build` and installed to an SD-card using `make install`. The hardware can be made in half an hour and without soldering.
There are many ways to build a Pi-KVM. Video capture devices can be attached using the CSI-2 or USB interfaces. Raspberry Pi models 2, 3, 4, or ZeroW may be used. Any combination of hardware is supported, and Pi-KVM implements the maximum possible set of features.
With a very simple circuit that can be assembled on a breadboard, the power button of the attached server can be controlled using the ATX button headers on the motherboard.
Pi-KVM can be opened to the Internet and no one will get access without the password. SSL encryption is used to protect traffic from being intercepted by third parties.
The Pi-KVM OS is based on [Arch Linux ARM](https://archlinuxarm.org) and can be customized for any needs. Thousands of pre-built binary packages are at your service and can be updated with a single command!
Multiple Pi-KVMs can be configured to use a [common authorization service](https://github.com/pikvm/kvmd-auth-server). PAM and its rich authorization mechanisms can also be used to integrate Pi-KVM into your existing authentication infrastructure.
If repetitive actions must be perfromed on the attached server (or on several different servers), a macro can be recorded with keyboard & mouse actions and can be played back mutiple times.
We created [our very own MJPG video server](https://github.com/pikvm/ustreamer) written in C with multi-threading support and GPU video encoding - the fastest streaming solution available to provide the best video quality for Pi-KVM. We also tested a lot of hardware configurations so that you can be sure devices you assemble will work reliably.
This project is developed on a non-commercial basis by Open Source enthusiasts. If you find Pi-KVM useful or it has saved you a long trip to check on an unresponsive server, you can support the lead developer by donating a few dollars via [Patreon](https://www.patreon.com/pikvm) or [PayPal](https://www.paypal.me/mdevaev). With this money, he will be able to buy new hardware (Raspberry Pi boards and other components) to test and maintain various configurations of Pi-KVM, and generally devote significantly more time to the project. At the bottom of this page are the names of all the people who have helped this project develop with their donations. Our gratitude knows no bounds!
If you wish to use Pi-KVM in production, we accept orders to modify it for your needs or implement custom features you require. Contact us via live chat or email the lead developer at: mdevaev@gmail.com
**A:** Although this page is rarely updated, the project is actively maintained and developed. You can verify this by checking the activity in our other repositories.
**A:** Yes, and Pi-KVM works great with it. **However, it should be noted that the USB dongle has several disadvantages compared to the HDMI-CSI bridge:** USB gives a lot of latency (200ms vs 100ms for the bridge) and it doesn't support stream compression control (you won't be able to use Pi-KVM in a place with a poor internet connection). It also cannot automatically detect screen resolution. All this is caused by the hardware limitations of the dongle itself. **It may be used, but the loss of these features is probably not worth the ten dollars saved.**
**A:** Yes, but it will require additional work to set up. Pi-KVM can be connected to a multi-port HDMI/USB switch and the switch's buttons can be connected via optocouplers to the Pi's GPIO pins to switch channels. If your KVM switches channels using keyboard shortcuts, there is a chance that it will not be able to work with OTG (v2 platform, see bellow), since it does not fully implement the USB stack. In this case, you will have to use an Arduino board to emulate the keyboard & mouse. (Pi-KVM supports this configuration)
Pi-KVM supports several different hardware configurations, referred to as **platforms**. At the moment, there are two main ones: **v0** and **v2**.
* **v0** was designed to work with Raspberry Pi boards that do not have OTG (**Raspberry Pi 2** and **3**) and requires a few more components for a basic implementation. It also does not support the Mass Storage Drive feature.
* **v2** is the most modern implementation supporting all of the features of Pi-KVM. It was designed to work with the **Raspberry Pi 4** and **ZeroW**.
* HDMI to CSI-2 bridge board: [Lusya or any other based on the Toshiba TC358743](https://aliexpress.com/item/4000102166176.html) (**recommended**: compression control, lowest video latency for ~100ms, can determine the source resolution; see the FAQ above for the explanation)
* HDMI to USB dongle (RPi4 only): [AliExpress](https://aliexpress.ru/item/4001043540669.html) (high video latency for ~200ms, no compression control, can't detect the source resolution)
* If you want to capture VGA from your server instead of HDMI, buy the [VGA-to-HDMI converter](https://aliexpress.ru/item/4000553298530.html).
* Pi-KVM can be powered using PoE, but it is not recommend to use the official PoE HAT: it is unreliable and [not compatible with the HDMI bridge](https://github.com/pikvm/pikvm/issues/6). Use any other PoE hat without an I2C fan controller.
* **Don't use random relay modules or random optocouplers!** Some relays or optocouplers may not be sensitive enough for the Raspberry Pi, some others may be low-level controlled. Either use relays that are activated by a high logic level, or follow the design provided and buy an OMRON. See details [here](https://github.com/pikvm/pikvm/issues/13).
Sounds interesting? Subscribe to https://discord.gg/bpmXfz5 and you will be the first to know about the release. Prototypes will be ready in Q4 2020, and pre-orders will be available sooner. Or just email to mdevaev@gmail.com. We will let you know when you can purchase this board.
Here is a diagram shows that how to connect all of the pieces (click to full size). Build everything as shown in the diagram and insert the flexible cable of the HDMI bridge into the narrow white connector on the Raspberry Pi (the closest one to the USB).
Insert the flexible cable of the HDMI bridge into the narrow white connector on the Raspberry Pi (the closest one to the USB). Use only the cable that was included with the device package, or make sure that the third-party cable has the correct pinout.
**For HDMI-USB dongle**
Connect USB dongle to exactly this port. It is bound in the software so the OS does not confuse the video device with something else.
**Raspberry Pi 4 note**: since one USB-C female connector is used to receive power and perform keyboard/mouse/drive emulation a special Y-cable must be made that splits the DATA and POWER lines of USB-C (see [reasons](https://github.com/pikvm/docs/issues/11)). It can be made from two suitable connecting cables, or soldered together from scratch. Be sure to check the circuit diagram below, otherwise you may damage your devices. The appropriate USB pinout(s) can easily be found on Google. Please note that if you make a Y-cable from two no-name cables, the colors of the wires may not match those shown. Use a multimeter to make sure the connections are correct.
Insert the flexible cable of the HDMI bridge into the narrow white connector on the Raspberry Pi (the closest one to the USB). Use only the cable that was included with the device package, or make sure that the third-party cable has the correct pinout.
The Pi-KVM OS is based on Arch Linux ARM and contains all the required packages and configs for it to work. To build the OS you will need any Linux machine with a recent version of Docker (>= 1:19) with privileged mode enabled. (used for fdisk and some other commands, have a look through our Makefiles if you don't trust us :) )
0. When starting with a clean OS (Like Ubuntu 18) you need to install and configure docker (after adding your user to the docker group you must log out and log back in), as well as git and make.
2. Determine the target hardware configuration (platform). Choose the board (`BOARD=rpi4` for Raspberry Pi 4 or `BOARD=zerow`, `BOARD=rpi2`, `BOARD=rpi3` for other options). Next, choose the platform: `PLATFORM=v2-hdmi` for RPi4 or ZeroW with HDMI-CSI bridge; `PLATFORM=v2-hdmiusb` for RPi4 with HDMI-USB dongle; `PLATFORM=v0-hdmi` for RPi 2 or 3 with HDMI-CSI bridge. Other options are for legacy or specialized Pi-KVM boards (WIP).
3. Create the config file `config.mk` for the target system. You must specify the path to the SD card on your local computer (this will be used to format and install the system) and the version of your Raspberry Pi and platform. You can change other parameters as you wish. Please note: if your password contains the # character, you must escape it using a backslash like `ROOT_PASSWD = pass\#word`.
6. After installation remove the SD card and insert it into your RPi. Turn on the power. The RPi will try to get an IP address using DHCP on your LAN. It will then be available via SSH.
8.**Only for v0**. Now you need to flash the Arduino. This can be done using your RPi. **Before starting this operation, disconnect the RESET wire from the Arduino board, otherwise the firmware will not be uploaded. Connect the Arduino and RPi with a suitable USB cable.** Log in to the RPi and upload the firmware. Then reconnect the RESET wire, disconnect the USB cable, and reboot the RPi.
9. Congratulations! Your Pi-KVM will be available via SSH (`ssh root@<addr>`) and HTTPS (try to open it in a browser at `https://<IP addr>`). For HTTPS a self-signed certificate is used by default.
* The Pi-KVM file system is always mounted in read-only mode. This prevents it from being damaged by a sudden power outage. To change the configuration you must first switch the filesystem to write mode using the command `rw` from root. After the changes, be sure to run the command `ro` to switch it back to read-only.
* NEVER edit `/etc/kvmd/main.yaml`. Use `/etc/kvmd/override.yaml` to redefine the system parameters. All other files that are also not recommended for editing have read-only permissions. If you edit any of these files, you will need to manually make changes to them when you upgrade your system. You can view the current configuration and all available KVMD parameters using the command `kvmd -m`.
* Almost all KVMD (the main daemon controlling Pi-KVM) configuration files use [YAML](https://docs.ansible.com/ansible/latest/reference_appendices/YAMLSyntax.html) syntax. Information on the format's syntax can be found at the link provided.
* To use Wake-on-LAN with your server you must define some options such as the server's MAC address and (optionaly) IP address. Use `/etc/kvmd/override.yaml`. The format is:
Replace `ff:ff:ff:ff:ff:ff` with the MAC of your server. By default, a packet is sent via a broadcast request to the entire IPv4 network (`255.255.255.255`, port `9`), but you can address it to a specific static address:
* To use IPMI BMC you need to set up an appropriate account and run the `kvmd-ipmi` daemon (`systemctl start kvmd-ipmi` and `systemctl enable kvmd-ipmi`). Although Pi-KVM supports the IPMI protocol, we strongly recommend that you do not use it outside of trusted networks due to the protocol's [insecurity](https://github.com/NitescuLucian/nliplace.com.blog.drafts). Refer to the file `/etc/kvmd/ipmipasswd` to configure IPMI account.
By default username and password authentication is used. This is not supported by all clients (we recommend [TigerVNC](https://tigervnc.org)). To enable passphrase authentication, you need to edit the file `/etc/kvmd/vncpasswd` to set passphrases and enable this feature in `/etc/kvmd/override.yaml`:
After that you can enable the `kvmd-vnc` daemon (`systemctl start kvmd-vnc` and `systemctl enable kvmd-vnc`). VNC will be available on port 5900 by default.
It is reccomended to disable the automatic quality adjust setting if there is one in your client (this is called "Auto-Select"in TigerVNC).
Please note: **we strongly discourage the use of VNC on untrusted networks.** The current implementation does not use encryption, and your passwords are transmitted over the network in a plain text. The existing anonymous TLS mode is also not secure enough.
/root/.platformio/packages/tool-avrdude/avrdude: error while loading shared libraries: libtinfo.so.5: cannot open shared object file: No such file or directory
If problems occur when uploading even a small disk image it may be due to unstable network operation or antivirus software. It is well known that Kaspersky antivirus cuts off Pi-KVM connections during uploading, so you should add the Pi-KVM website to Kaspersky's list of exceptions or not filter web requests with the antivirus. Antivirus programs can also affect the performance of certain interface elements, for example the quality slider.
For Kaspersky, the steps to add the network address of Pi-KVM's website to the exclusion list is: **Protection -> Private browsing -> Categories and exclusions -> Exclusions**
If you can't or don't want to enable the CSM, you can try connecting a DisplayPort monitor, or a [dummy plug](http://amazon.com/s?k=displayport+dummy+plug). If you remove the DP cable/adapter the bug will reappear.
If none of this works, try connecting the DP cable first, boot into the BIOS, disable the CSM and shutdown (do not restart) your PC. Then, boot into the BIOS and enable the CSM before shutting down your PC. Then connect the HDMI and turn your PC on again.
These kind people donated money to the Pi-KVM project and supported work on it. We are very grateful for their help, and commemorating their names is the least we can do in return.
