This section explains why we need decentralized computing devices and the problems the Netrabrick resolves.
1980: Do we value design?
2000: Do we value open-source?
2020: Do we value decentralization?
Phase I: The atomization:
Phase II: Centralization
Phase III: Decentralization
This section describes the installation and configuration of the Netrabrick™.
A Netrabrick is a combination of the following technologies:
Small form-factor PC (NUC)
Out-of-band Management
Ubuntu base instance
IoT data collector
backup NAS
DappNode
VPN
home automation data
Other web3 services
Small form-factor PC (NUC)
This is the initial NUC configuration: https://simplynuc.com/product/cbm1r5rb/
It may be overblown for the Netrabrick requirements:
Internally, the NUC has two USB 2.0 Headers and one serial header.
For audio:
Up to 7.1 surround via HDMI
Front audio: mic in / line out
This document contains the technical specifications, including header diagrams for internal USB, serial, and reset jumpers.
Out-of-band management
The Netrabrick runs critical services. As such, insuring uptime is supreme. To enable remote monitoring and access to the Netrabrick, an additional NUC lid (Netrabrick lid) was designed to provide out-of-band management services.
Essentially, if the Netrabrick crashes, and nobody is physically near the device to reboot or repair, this out-of-band management facility allows us to access the netrabrick remotely, power-off and power-on, reinstall or reconfigure as if we were sitting at the keyboard in front of the Netrabrick.
This is accomplished by a combination of various technologies:
Raspberry Pi Zero 2W
A Raspberry Pi Zero 2W is hardwired to the Netrabrick device.
HDMI Adapter
Geekworm Raspberry Pi HDMI to CS1-2 C229 Adapter board.
PiKVM
PiKVM is the software that is installed on the Raspberry Pi.
PiSugar
The PiSugar 3 provides uninterrupted power (UPS) to the Netrabrick lid components. This way, even if the Netrabrick server loses power, or needs to be rebooted, the Netrabrick lid will remain online long enough to provide a power-outage notification.
Also, the PiSugar 3 functions as an external watchdog reset for the Raspberry Pi.
4G modem
If the Netrabrick lid loses communications with the internet, a 4G modem can be activated by the lid to notify about the communications failure.
Setup Steps
3D print the Netrabrick lid cover.
Attach the lid components
Connect the headers cables to the PiSugar and Raspberry Pi.
Flash the PiKVM image onto a the Raspberry Pi Zero W 2.
Install the SD card in the Raspberry Pi
Attach the lid, and connect the HDMI - CS1 adapter cable
Printing the Netrabrick lid cover
Attaching the Netrabrick lid components
Open the Netrabrick by removing the four bottom screws:
Be careful to not disconnect or break the SATA drive cable connection:
Connecting the header cables to the PiSugar and RaspberryPi
Flashing the PiKVM image
Download the latest DIY PiKVM image for the HDMI-CSI bridge for the RaspberryPi Zero 2W and sha hash.
Validate the download image:
PiKVM % shasum v2-hdmi-zero2w-latest.img.xz cdb1bb899a72351a2da924ceb0675130d01e46ed v2-hdmi-zero2w-latest.img.xz PiKVM % cat v2-hdmi-zero2w-latest.img.xz.sha1 cdb1bb899a72351a2da924ceb0675130d01e46ed%
Download the latest version of the DappNode ISO for Debian, attended, and note the sha1 hash.
Download and install the Raspberry Pi imager.
Run RPi Imager:
Press NO FILTERING then CHOOSE OS and select Use custom image at bottom of the list:
After clicking on this item, select the image file for PiKVM that you downloaded earlier then click CHOOSE STORAGE:
Insert the memory card into the card reader. Choose the card reader from this list. Be careful and choose the right device:
After choosing the memory card, press the WRITE button. Confirm the operation when you are asked about it:
Mount the PiKVM memory card, and edit the file
pikvm.txt
. If you haven't enabled PiKVM yet, this file will contain a single lineFIRST_BOOT=1
.
WIFI_ESSID='mynet' WIFI_PASSWD='p@s$$w0rd' WIFI_ADDR=192.168.0.86/24 WIFI_DNS=8.8.8.8 WIFI_GW=192.168.0.1 SSH_PORT=2001
Note that backslash in the password should be escaped: \
should be written as \\
.
If there was a string FIRST_BOOT=1
in the file, do not remove it. This is the trigger needed to initialize the OS at the first boot. On the contrary, if the file pikvm.txt does not exist, you should not add this line.
Unmount partition and insert the memory card on the Raspberry Pi Zero 2W. Power on the Netrabrick.
Connect via ssh
ssh -p 2001 root@192.168.0.86 root@192.168.0.86's password: _____ _ _ ____ ____ __ | __ (_)| |/ /\ \ / / \/ | | |__) | | ' / \ \ / /| \ / | | ___/ || < \ \/ / | |\/| | | | | || . \ \ / | | | | |_| |_||_|\_\ \/ |_| |_| Welcome to PiKVM - The Open Source KVM over IP on Raspberry Pi ____________________________________________________________________________ The root filesystem of PiKVM is mounted in the read-only mode by default. Use command "rw" to remount it in the RW-mode and "ro" to switch it back. If the filesystem is busy and doesn't switch to the RO-mode, use "reboot" to reboot the device, don't leave it in the RW-mode. Useful commands: * Preventing kernel messages in the console: dmesg -n 1 * Changing the Web UI password: kvmd-htpasswd set admin * Changing the root password: passwd Links: * Official website: https://pikvm.org * Documentation: https://docs.pikvm.org * Auth & 2FA: https://docs.pikvm.org/auth * Networking: https://wiki.archlinux.org/title/systemd-networkd
Change the root password and web admin password
[root@pikvm ~]# rw + mount -o remount,rw / + mount -o remount,rw /boot + set +x === PiKVM is in Read-Write mode === [root@pikvm ~]# passwd root New password: Retype new password: passwd: password updated successfully [root@pikvm ~]# kvmd-htpasswd set admin Password: Repeat: # Note: Users logged in with this username will stay logged in. # To invalidate their cookies you need to restart kvmd & kvmd-nginx: # systemctl restart kvmd kvmd-nginx # Be careful, this will break your connection to the PiKVM # and may affect the GPIO relays state. Also don't forget to edit # the files /etc/kvmd/{vncpasswd,ipmipasswd} and restart # the corresponding services kvmd-vnc & kvmd-ipmi if necessary.
Activate 2FA authentication with your favorite authenticator app:
[root@pikvm ~]# kvmd-totp init
Connect via browser to the PiKVM address: 192.168.0.86. (Accept the unsecured connection, as we have not yet added a SSL certificate) using password
Attaching the lid and connecting external cables
NUC - Netrabrick NUClid cabling
Identifier | Header |
---|---|
8 | COM Header |
9 | USB2 Header |
10 | Front Panel Header |
COM header
Use of this header is not really necessary, but it could be connected to the Raspberry Pi used by PiKVM to provide a serial terminal login access to the server.
Pin | RS232 signal | Connection |
---|---|---|
1 | DCD | Empty |
2 | RXD | RPi GPIO14 (UART TX) |
3 | TXD | RPi GPIO15 (UART RX) |
4 | DTR | Empty |
5 | GND | Rpi GND |
6 | DSR | Empty |
7 | RTS | Empty |
8 | CTS | Empty |
9 | RI# | Empty |
10 | Empty | Empty |
NUC USB2.0 header
The USB2.0 header is essential for providing keyboard and mouse HID access from the PiKVM instance on the Raspberry Pi to the server. Also, this header provides power to the SugarPi3, which in turn, powers the PiKVM Raspberry Pi.
Notice that VCC (5v) is NOT provided to the MicroUSB connection on the Raspberry Pi. This is the equivalent of blocking the VCC pin, as described here.
Pin | USB Signal | Connection |
---|---|---|
1 | VCC | Pin 8 (5v in) on SugarPi3 |
2 | VCC | Current connector to power fan? |
3 | USB0- | MicroUSB cable USB- (green) |
4 | USB1- | Empty |
5 | USB0+ | MicroUSB cable USB+ (white) |
6 | USB1+ | Empty |
7 | GND | Pin 1 on SugarPi 3 (next to Pin 8) AND USB ground (black) |
8 | GND | Current ground connector to fan? |
9 | No Connect | Empty |
10 | Empty | Empty |
NUC Front Panel header
Connecting the NUC Front Panel header to the Raspberry Pi is necessary if want ATX power control from PiKVM.
Pin | Header | Function | Connection |
---|---|---|---|
1 | HD_LED | HD_PWR | Connect to RPi, pin (red) |
3 | HD_Active | Connect to RPi, pin 22 (red) | |
2 | PWR_LED | PWR LED+ | Connect to Front Panel LED |
4 | PWR LED- | ||
5 | RESET | GND | Connect to RPi, pin (red) |
7 | RST BTN | Connect to RPi, pin 27 (red) | |
6 | PW_ON | PWR BTN | Connect to Front Panel Button |
8 | GND | ||
9 | No Connect | +5V | No connect |
10 | Empty | Empty | Empty |
This is how ATX wiring between the server and Raspberry Pi are instrumented:
As described here:
With this part, you will be able to remotely turn on, turn off and restart your computer!
x4 MOSFET relays OMRON G3VM-61A1 or OMRON G3VM-61AY1.
Don't use random relay modules or random optocouplers! Some of these 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.x4 390 Ohm resistors (see here for alternatives).
2x 4.7 kOhm resistors.
x10+ dupont wires male-male.
x1 a breadboard.
various wires for the breadboard.
Dappnode base instance
This section describes the steps involved for installing the Dappnode Linux base instance (bare metal install).
backup NAS
Time machine backup for MacOS devices
First we'll install samba
sudo apt install samba
Add a samba user
sudo smbpasswd -a mtb sudo usermod -g users mtb vi /etc/samba/smb.conf
Configure samba
[global] workgroup = openvino min protocol = SMB2 # security security = user passdb backend = tdbsam map to guest = Bad User # mac Support spotlight = yes vfs objects = acl_xattr catia fruit streams_xattr fruit:aapl = yes fruit:time machine = yes #NetShares [volumes] comment = Time Machine path = /timecapsule valid users = @users browsable = yes writable = yes read only = no create mask = 0644 directory mask = 0755
Adjust permissions
chmod 777 /timecapsule chown root:users /timecapsule/
Restart samba
service smbd restart
Connect to the samba server from MacOS finder
Go > Connect to server...
.
Configure Time Machine
FOAM.space anchor node
Dappnode
From the dappnode documentation:
DAppNode connects the decentralized internet by allowing a user to conveniently host P2P clients in a truly decentralized way, and eliminates the reliance on third parties vulnerable to centralization. It also adds an extra layer of incentivization that helps spread adoption of the blockchain ecosystem and solves the problem of infrastructure centralization.
The Problem
Most nodes for public blockchains nowadays have a degree of architectural or/and political centralization. The first refers to the number of machines a system is made of, and the second concerns the ownership of such machines, Vitalik Buterin, 2017.
A first very common case is to host a node in a Virtual Private Server (VPS). This puts your node in the hands of a highly centralized company like Digital Ocean or Amazon, which could block and censor your access. Moreover, they could be hosting different nodes in the same machine, architecturally reducing decentralization too.
Another common case in the Ethereum blockchain is to connect through a node owned by Infura. While Infura's work on providing infrastructure for the network is a necessity at this stage, we can see how the ownership of a majority of nodes by the same company is a centralizing factor.
Installation
Install dappnode
Download the image from DAppNodeISO or build it from source, and configure as a flexVDI Media Storage image file.