The Arduino Yún rev. 2 is an Arduino board unlike any other. While programming it is very similar to the Arduino Leonardo and uses the same processor, the Atmel ATmega32U4, it also has an additional processor, an Atheros AR9331, running Linux and the OpenWrt wireless stack. Programming the 32U4 via USB is identical to the Arduino Leonardo. Once you've configured the Yún rev. 2 to connect to your WiFi network, you can program the 32U4 via WiFi as well.
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The Arduino Yún rev. 2 is programmed using the Arduino Software (IDE), our Integrated Development Environment common to all our boards. You should have already it installed on your PC, as explained in the home page of our Getting Started.
OSX
There's nothing to configure with the Yún Rev. 2.
Windows
Windows version of Arduino Software (IDE) already contains the proper drivers. When you installed it you let the operating system install them. Connect your Yún rev. 2 and the drivers will be installed automatically
Linux
There is no need to install drivers for Ubuntu 10.0.4 and later, but make sure port 5353 is not being blocked by a firewall.
Open the LED blink example sketch: File > Examples >01.Basics > Blink.
You'll need to select the entry in the Tools > Board menu that corresponds to your Arduino or Genuino board.
Select the serial device of the board from the Tools | Serial Port menu. This is likely to be COM3 or higher (COM1 and COM2 are usually reserved for hardware serial ports). To find out, you can disconnect your board and re-open the menu; the entry that disappears should be the Arduino or Genuino board. Reconnect the board and select that serial port. When your board is properly configured on WiFi, you will find it in the Port list, as in our screenshot.
Now, simply click the "Upload" button in the environment. Wait a few seconds - you should see the RX and TX leds on the board flashing. If the upload is successful, the message "Done uploading." will appear in the status bar.
A few seconds after the upload finishes, you should see the on-board LED start to blink. If it does, congratulations! You've gotten your Arduino Yún rev. 2 up-and-running. If you have problems, please see the troubleshooting suggestions.
Now that you have set up and programmed your Yún rev. 2 board, you may find inspiration in our Project Hub tutorial platform, or you can dig in deeper with the Bridge library and examples. You can also check out the Yún rev. 2 hardware page for additional technical information.
Differences from the Arduino Leonardo
In addition to the 32U4 chip, the Yún rev. 2 has an additional processor, an Atheros AR9331, which runs a distribution of Linux for embedded systems named OpenWrt-Yun, based on OpenWrt. A full install of Python 2.7 is included as well.
The Yún rev. 2 has a number of different physical characteristics and connectors than the Leonardo. There is an on-board SD slot, Ethernet jack, and a USB-A Host connector. There is no power barrel connector on the Yún; it can be powered from the micro-USB connector.
There is no built in 5V regulator. If you power your Yún rev. 2 with more than 5V, you will likely damage it. If you are not powering the Yún rev. 2 from the micro-USB connection, you can apply power to the VIN and 5V pins on the board. If using the VIN pin, you cannot provide more than 5V, it will damage your board. It is recommended to power the Yún rev. 2 from the USB connection whenever possible.
The SD, Ethernet, and USB-A connectors are not physically connected to the 32U4 processor, they are connected to the AR9331.
The Yún's 32U4 functions in the same way as the Leonardo, except you cannot use Serial1
. It is reserved for communication with the AR9331 processor.
The Yún rev. 2 also has a WiFi module built on board, allowing it to connect to a wireless router, or act as an access point.
The 32u4, WiFi, and AR9331 processors all have their own reset buttons.
There are several status LEDs on the Yún, indicating power, WLAN connection, WAN connection and USB. Additionally pin 13 is connected to one of the status lights.
The Yún rev. 2 runs a distribution of Linux called OpenWrt-Yun, based on OpenWrt. While it's possible to configure the system from the command line, there is a web page that allows you to configure many of the different options available. The interface (called LuCi) gives you access to most any setting you would need for maintaining the WiFi interface.
Accessing the web interface is described below.
To install additional software on OpenWrt-Yun, you need to use the the Linux package manager opkg. For more information on the manager and some common commands, see the Yún rev. 2 package manager page.
When interfacing with the OpenWrt-Yun system, you have to use a command line, either accessing it through the Arduino's Bridge library, or via SSH. If you are unfamiliar with the command line, you may want to read about some basics about it and some of the programs that are frequently used.
Due to continuous improvements and suggestions coming from both the OpenWrt community and the Arduino community, version of OpenWrt-Yun installed on your Yún rev. 2 may be out of date. Please check the upgrade tutorial and be sure you're running the latest version available.
An installation of Python 2.7 is included with OpenWrt-Yun, with which you can write applications or scripts. For more on Python, visit the Python 2.7 documentation pages.
If you're getting started with Python for the first time, there are a number of excellent resources on-line. "Learn Python the Hard Way" will cover everything you need to know to get up and running with your own scripts.
You're discouraged from using the Yún's built-in non-volatile memory, because it has a limited number of writes.
You can use external memory like a microSD card or thumb drive for saving data, or your own scripts, web pages, etc. For the Yún rev. 2 to access and store information on these drives through the 32U4, they need to have a directory named arduino
in the root of the volume.
If you plan to use a microSD memory card, you can expand the Yun Disk Space following this tutorial.
OpenWrt-Yun uses REST for clients and servers. REST is an acronym for "Representational State Transfer". It is a software architecture that exposes various parts of the Arduino hardware through URLs.
By default, the REST API access is password protected. It is possible to change this to access the services without a password. To change this setting, enter the Yún rev. 2 configuration panel. At the bottom of the page, you will see toggles for changing the access.
A nice introduction to the concepts behind REST can be found here.
The three REST end points recognized by the Yún rev. 2 are:
The "/arduino" directory doesn't have anything pre-configured. Anything added to the URL after the end point is passed from the webserver to the sketch on the 32U4. You can define your APIs inside the sketch. See the Bridge example to see how this is done to access the pins on the board.
"/data" is used to access to the internal key/value storage. The available calls are:
"mailbox" is used to add messages into a queue called Mailbox. The message queue is stored inside the Linux system and can be read by the Arduino microcontroller. The available REST call is:
To restart the AR9331, which reboots OpenWrt-Yun, press the "YÚN REV. 2 RST" reset button that is close to the analog inputs pins and the LEDs of the board.
To restart the the 32U4 and restart the currently installed Arduino sketch, tap the button next to the Ethernet port two times.
The reset button for WiFi is located next to the USB-A connector. It is labeled "WLAN RST". When you press the button, the WLAN LED will flash.
If you move to a different network and can no longer wirelessly access the Yún rev. 2 through its web interface, you can reset the Yún's network configuration by pressing the WiFi reset button (WLAN RST) for longer longer than 5 seconds, but less than 30, the AR9331 processor will reboot. The WiFi configuration will be reset and the Yún rev. 2 will start its own wiFi network Arduino Yún-XXXXXXXXXXXX. Any other modification/configuration will be retained.
To reset the OpenWrt-Yun distribution to its default state, press the WiFi reset button (WLAN RST) for at least 30 seconds. The board reverts to the original settings: like just taken out of the box or to the latest update of the OpenWRT image you have reflashed before. Among other things, this removes all installed files and network settings.
The webpanel password can be reset and changed. Connect the Arduino Yún rev. 2 to your computer with an USB cable and upload the YunSerialTerminal sketch. It can be found in the Bridge examples in the Arduino Software (IDE). When the Yún rev. 2 boot is complete, open the serial monitor, select New Line character in the dropdown menu and press Enter. Something like this should appear in your serial monitor:
Now you have to execute the passwd command to change the password. Type passwd into the serial monitor input and press enter. You will be asked to type the new password, and re-type it to confirm. If you want, you can ignore the weak password error. If both passwords you typed match, the system password will be changed and you will be able to access to the webpanel with the new password.
Since the Yún rev. 2 does not have a dedicated chip to handle serial communication, it means that the serial port is virtual -- it's a software routine, both on your operating system, and on the board itself. Just as your computer creates an instance of the serial port driver when you plug in any Arduino, the 32u4 creates a serial instance whenever it runs its bootloader. The board is an instance of USB's Connected Device Class (CDC) driver.
This means that every time you reset the 32U4 processor, the USB serial connection will be broken and re-established. The board will disappear from the list of serial ports, and the list will re-enumerate. Any program that has an open serial connection to the Yún rev. 2 will lose its connection. This is in contrast to the Arduino Uno, with which you can reset the main processor (the ATmega328P) without closing the USB connection (which is maintained by the secondary ATmega8U2 or ATmega16U2 processor). This difference has implications for driver installation, uploading, and communication.
The Yún rev. 2 won't restart your sketch when you open a serial port on the computer. That means you won't see serial data that's already been sent to the computer by the board, including, for example, most data sent in setup().
This also applies to the Console, described below.
This means that if you're using any Serial or Console print(), println() or write() statements in setup(), they won't show up when you open the serial monitor or Console connection. To work around this, you can check to see if the port is open like so:
or
To simplify the configuration of the Yún rev. 2 board we have prepared a sketch that will allow to input all the relevant information through the Arduino Software (IDE) Serial Monitor. This is an easy and quick solution that also is ideal for multiple boards set ups like workshops and classrooms.
The sketch is available already in your Arduino Software (IDE) installation under Examples > Bridge > YunFirstConfig.
As soon as the sketch is uploaded, open your Serial Monitor window and follow the instructions.
The Yún rev. 2 has the ability to act as an Access Point, but it can also connect to an existing network. These instructions walk you through connecting your Yún rev. 2 to a wireless network. The Yún rev. 2 can connect to unencrypted networks, as well as networks that support WEP, WPA, and WPA2 encryption.
When you first power on the Yún, it will create a WiFi network called ArduinoYun-XXXXXXXXXXXX. Connect your computer to this network.
Once you've obtained an IP address, open a web browser, and enter
http://arduino.local
or 192.168.240.1 in the address bar. After a few moments, a web page will appear asking for a password. Enter "arduino
" and click the Log In button.
You will find a page with some diagnostic information about the current network connections. The first is your WiFi interface, the second is your ethernet connection. Press the Configuration button to proceed.
On the new page, you will configure your Yún, giving it a unique name and identifying what network you want to connect to.
In the Yún rev. 2 NAME field, give your Arduino a unique name. You'll use this to refer to it in the future.
Choose a password of 8 or more characters for your Arduino. If you leave this field blank, the system retains the default password of arduino
If you wish, you can set the timezone and country. It is recommended to set these options as it may help connecting to local WiFi networks. Setting the local timezone also selects the country's regulatory domain.
Enter the name of the wiFi network you wish to connect to.
Select the security type, and enter the password.
When you press the Configure & Restart button, the Arduino will reset itself and join the specified network. The Arduino network will shut down after a few moments.
You can now join the network you assigned to the Yún.
When your Yún rev. 2 is on the same network as your computer, you can connect to it wirelessly to program it.
After configuring your Yún, connect to the network you specified in the configuration settings. Open the Arduino IDE.
Under the Tools > Port menu, you should see an entry that lists your Yún's name and its IP address. Under the Board menu, select Arduino Yún.
Open the Blink example (File > Examples > 01Basics > Blink) and upload the sketch to the board. You will be prompted for the administrator password. Use the one you entered in the configuration screen.
Once the program is uploaded, the 32U4 processor will restart. You should see the LED connected to pin 13 blinking.
When you connect the Yun to a wired network with an ethernet cable, it will try to connect automatically via DHCP. The board will show up on the ports menu just as it would over WiFi.
If you want to connect the Yun directly to your computer, either configure the computer's interfaces to have a static IP address, or act as a DHCP server.
NB: the ethernet interface is eth1, not eth0
The Bridge library enables communication between Arduino and OpenWrt-Yun. There are several different utility classes that facilitate different kinds of communication between the two, described below, and more in depth on the Bridge library reference pages.
The WiFi and Ethernet interfaces, USB host, and SD card are all connected to the AR9331. The Bridge library allows you to work with these devices, as well as run scripts and communicate with web services.
The Console, based on Bridge, enables you to send information from the Yún rev. 2 to a computer just as you would with the serial monitor, but wirelessly. It creates a secure connection between the Yún rev. 2 and your computer via SSH.
Load the following onto your Yún rev. 2 :
To see the Console, select your Yún's name and IP address in the Port menu. The Yún rev. 2 will only show up in the Ports menu if your computer is on the same LAN as the Yún. If your board is on a different network, you won't see it in the Ports menu. Open the Port Monitor. You'll be prompted for the Yún's password.
You can also see the Console by opening a terminal window and typing ssh root@yourYunsName.local 'telnet localhost 6571'
then pressing enter.
NB: If you are using Windows, you must install a terminal emulator. PuTTY is a reasonable choice, but you will have to enter the two commands above separately.
Type 'H' to turn the LED on pin 13 on and type 'L' to turn it off.
The Process commands allow you to run Linux processes on OpenWrt-Yun through the Arduino.
In the following example, The OpenWrt-Yun will connect to a server with curl
, and download some ASCII text. It prints the text a serial connection.
Bridge allows you to pass information between the two processors using a key/value pairing.
This example shows how to use the Bridge library to access the digital and analog pins on the board through REST calls. It demonstrates how you can create your own API when using REST style calls through the browser.
When running this example, make sure your computer is on the same network as the Yun.
When you have have programmed the board, you can request the value on a pin, write a value to a pin, and configure a pin as an input or output.
When the REST password is turned off, you can use a browser with the following URL structure :
You can use the curl command from the command line instead of a browser if you prefer.
You need to include the Bridge, YunServer, and YunClient libraries :
Instantiate a server enabling the the Yun to listen for connected clients.
YunServer server;
In setup()
, start serial communication for debugging purposes, and turn the built-in LED on pin 13 high while Bridge begins. Bridge.begin()
is blocking, and should take about 2 seconds to complete. Once Bridge starts up, turn the LED off.
In the second part of setup()
, tell the instance of YunServer to listen for incoming connections only coming from localhost. Connections made to OpenWrt-Yun will be passed to the 32U4 processor for parsing and controlling the pins. This happens on port 5555. Start the server with server.begin()
.
In loop()
, you'll create an instance of the YunClient for managing the connection. If the client connects, process the requests in a custom function (described below) and close the connection when finished.
Putting a delay at the end of loop()
will be helpful in keeping the processor from doing too much work.
Create a function named process
that accepts the YunClient as its argument. Read the command by creating a string to hold the incoming information. Parse the REST commands by their functionality (digital, analog, and mode) and pass the information to the appropriately named function.
Create a function to deal with digital commands. Accept the client as the argument. Create some local variables to hold the pin and value of the command.
Parse the client's request for the pin to work with using client.parseInt()
.
If the character after the pin is a "/", it means the URL is going to have a value of 1 or 0 following. This value will assign a value to the pin, turning it HIGH or LOW. If there is no trailing "/", read the value from the specified pin.
Print the value to the client and update the datastore key with the current pin value.
By wrapping the value to the client in F()
, you'll be printing form the flash memory. This helps conserve space in SRAM, which is useful when dealing with long strings like URLs.
The key will be the pin, and type. For example D2 will be saved for for digital pin 2. The value will be whatever value the pin is currently set to, or was read from the pin.
Set up a function to handle analog calls in the same fashion, except setting the key to A instead of D when working with the analog input pins :
Create one more function to handle pin mode changes. Accept the YunClient as the argument, and create a local variable to hold the pin number. Read the pin value just as you did in the digital and analog functions.
Check to make sure the URL is valid
If it's a valid URL, store the URL as a string. If the mode is an input
or output
, configure the pin and report it to client. If the string doesn't match those values, return an error.
You can find more details on this example on the Bridge Example page.
The Yún rev. 2 comes with several pieces of software pre-installed on OpenWrt-Yun, including "curl" and "python". You may want to install other software on the Yún. On Linux systems, additional software can be installed using a tool called the "package management system". For more information, refer to the package manager tutorial.
Last revision 2018/05/28 by SM
The text of the Arduino getting started guide is licensed under a
Creative Commons Attribution-ShareAlike 3.0 License. Code samples in the guide are released into the public domain.