RPi Serial Connection
Back to RPi Advanced Setup.
The Serial Port is a low-level way to send data between the Raspberry Pi and another computer system. There are two main ways in which it can be used:
- Connecting to a PC to allow access to the Linux console. This can help to fix problems during boot, or to log in to the Pi if the video and network are not available.
- Connecting to a microcontroller or other peripheral which has a serial interface. This can be useful if you want the Pi to control another device.
- 1 Connections and signal levels
- 2 Connection to a PC
- 3 Connection to a microcontroller or other peripheral
Connections and signal levels
The Raspberry Pi serial port consists of two signals (a 'transmit' signal, TxD and a 'receive' signal RxD) made available on the GPIO header. To connect to another serial device, you connect the 'transmit' of one to the 'receive' of the other, and vice versa. You will also need to connect the Ground pins of the two devices together.
The Broadcom chip at the heart of the Pi uses 0 and 3.3V logic levels, not the +/-12V used by RS-232 serial ports found on some older PCs. If you wish to connect one of these, you need a board or adapter to convert the signal levels. See this tutorial for one example on how to build a 3.3V to RS-232 level converter with a breadboard, a MAX3232CPE IC and five 0.1 uF capacitors.
If you wish to connect your Pi to a PC with a USB port, the simplest option is to use a USB-to-serial cable which uses 3.3V logic levels (e.g. the Adafruit 954 or the FTDI TTL-232R-RPI cables). These can be simply plugged in directly to the GPIO header (see illustration).
If you wish to connect to a peripheral which has 0/5V signals, you should ideally have a circuit to convert between the voltage levels. See this tutorial for an example circuit. For prototyping work, provided the connections are kept short you may connect the GPIO TxD directly to the 5V RxD, and the 5V TxD can be connected via a voltage divider to the GPIO RxD. A 5V to 3V resistor divider can be built from a 2K2 (top) and a 3K3 (bottom) resistor.
Connection to a PC
You can connect the Pi to a PC using a USB-serial cable, or (if it has an RS232 port) a level-converter circuit - see above for details. When this is done, you will need to set up a terminal emulator program on your PC as described below.
Console serial parameters
The following parameters are needed to connect to the Pi console, and apply on both Linux and Windows.
- Speed (baud rate): 115200
- Bits: 8
- Parity: None
- Stop Bits: 1
- Flow Control: None
Linux terminal set up
If your PC is running Linux, you will need to know the port name of its serial port:
- Built-in (standard) Serial Port: the Linux standard is /dev/ttyS0, /dev/ttyS1, and so on
- USB Serial Port Adapter: /dev/ttyUSB0, /dev/ttyUSB1, and so on.
- Some types of USB serial adapter may appear as /dev/ttyACM0 ...
You will need to be a member of the dialout group to access this port (for later releases the required group is tty). You can check which is needed with:
ls -l /dev/ttyUSB0
and you will see something like "crw-rw----T 1 root dialout ...", c means character device, and root can 'read,write' and the group dialout can 'read,write' to the port and everyone else cannot access it.
To find out if you, the current user, is in the group dialout, use the command:
If you do not see dialout listed, add yourself with the command
sudo usermod -a -G dialout username
You then have a choice of terminal emulation programs:
- Super Easy Way Using GNU Screen
Enter the command below into a terminal window
screen port_name 115200
To exit GNU screen, type Control-A k.
- Super Easy Way Using Minicom
Run minicom with the following parameters:
minicom -b 115200 -o -D Port_Name
You can exit minicom with Control-A x
- Tedious Old-Fashioned Way Using Minicom
Another method to setup minicom is described in the Tincantools Minicom Tutorial
- GUI method with GtkTerm
Start GtkTerm, select Configuration->Port and enter the values above in the labeled fields.
- Network connection with the point-to-point protocol
The easiest way to set up a network connection between your Raspberry Pi and another computer is with an ethernet cable. If this is not possible, as is the case for the Raspberry Pi Model A, you can set up a connection over the serial cable. This uses the Point-to-point Protocol (PPP). A network connection running over a serial cable can be very useful for copying files onto the Raspberry Pi.
Step 1: login to the Raspberry Pi over the serial cable and run the Point-to-Point Protocol Daemon:
Some garbage will start appearing in the terminal. This is the cue to quit your terminal program and proceed to step two.
Step 2: on your local computer, start the Point-to-Point protocol. On a Linux or Mac computer you can do this by typing:
sudo pppd -detach noauth proxyarp /dev/tty.usbserial-FTGCC2MV 115200 10.0.0.1:10.0.0.2 passive local maxfail 0 nocrtscts xonxoff
replacing /dev/tty.usbserial-FTGCC2MV with the name of your serial port. In the above line, 115200 is the baud rate of the connection, 10.0.0.1 is the local internet protocol (IP) address, the address you want your computer to have. 10.0.0.2 is the remote IP address, it is the address that the Raspberry Pi will have.
Test the connection:
Windows terminal set-up
PuTTY users simply need to choose 'serial', select the correct COM port and set the speed, as shown in the dialog below.
If you are unsure of the COM port, run [Device Manager] and look under 'Ports'. USB-attached serial adapters should have the name of the adapter shown (the Adafruit cable comes up as 'Prolific USB-to_Serial Comm Port'.
If your connection is set up correctly, when the Pi is booted you should see many messages as the system comes up:
Uncompressing Linux... done, booting the kernel. [ 0.000000] Initializing cgroup subsys cpu [ 0.000000] Linux version 3.2.27+ (dc4@dc4-arm-01) (gcc version 4.7.2 20120731 (prerelease) (crosstool-NG linaro-1.13.1+bzr2458 - Linaro GCC 2012.08) ) #250 PREEMPT Thu Oct 18 19:03:02 BST 2012 [ 0.000000] CPU: ARMv6-compatible processor [410fb767] revision 7 (ARMv7), cr=00c5387d [ 0.000000] CPU: PIPT / VIPT nonaliasing data cache, VIPT nonaliasing instruction cache [ 0.000000] Machine: BCM2708 [ 0.000000] Memory policy: ECC disabled, Data cache writeback [ 0.000000] Built 1 zonelists in Zone order, mobility grouping on. Total pages: 113792 [ 0.000000] Kernel command line: dma.dmachans=0x7f35 bcm2708_fb.fbwidth=656 bcm2708_fb.fbheight=416 bcm2708.boardrev=0xf bcm2708.serial=0xcc5c4b6d smsc95xx.macaddr=B8:27:EB:5C:4B:6D sdhci-bcm2708.emmc_clock_freq=100000000 vc_mem.mem_base=0x1c000000 vc_mem.mem_size=0x20000000 dwc_otg.lpm_enable=0 console=ttyAMA0,115200 console=tty1 root=/dev/mmcblk0p2 rootfstype=ext4 elevator=deadline rootwait
and so on. Eventually, you should see a login prompt:
Debian GNU/Linux wheezy/sid raspi2 ttyAMA0 raspi2 login:
You can then log in as you would with a keyboard and screen.
Unwanted serial garbage input
Note that on older software by accident the internal pullups of the RxD GPIO pins were not enabled, this could lead to lots of serial garbage being picked up if the GPIO pin was touched, or even if a finger was nearby. In extreme case this could lead to kernel warnings and other problems.
Connection to a microcontroller or other peripheral
The TxD and RxD signals can also be connected directly to similar signals on a microcontroller board like the Arduino provided the signals are all at 3V3 levels. Some Arduino variants use 5V levels, and should have level conversion (see 'Connections and Signal levels' above). Even at 3V3 levels, it's still a good idea to put 2K2 series resistors in the lines to prevent damage when two outputs are connected together, which could also happen if a GPIO input pin is accidentally programmed as output.
If your microcontroller uses 5V logic levels, level conversion is usually necessary - see 'Connecting to a PC' for details.
Preventing Linux using the serial port
The Broadcom UART appears as
/dev/ttyAMA0 under Linux. There are several minor things in the way if you want to have dedicated control of the serial port on a Raspberry Pi.
- Firstly, the kernel will use the port as controlled by kernel command line contained in
/boot/cmdline.txt. The file will look something like this:
dwc_otg.lpm_enable=0 console=ttyAMA0,115200 kgdboc=ttyAMA0,115200 console=tty1 root=/dev/mmcblk0p2 rootfstype=ext4 elevator=deadline rootwait
The console keyword outputs messages during boot, and the kgdboc keyword enables kernel debugging. You will need to remove all references to ttyAMA0. So, for the example above
/boot/cmdline.txt, should contain:
dwc_otg.lpm_enable=0 console=tty1 root=/dev/mmcblk0p2 rootfstype=ext4 elevator=deadline rootwait
You must be root to edit this (e.g. use
sudo nano /boot/cmdline.txt). Be careful doing this, as a faulty command line can prevent the system booting.
- Secondly, after booting, a login prompt appears on the serial port. This is controlled by the following lines in
#Spawn a getty on Raspberry Pi serial line T0:23:respawn:/sbin/getty -L ttyAMA0 115200 vt100
You will need to edit this file to comment out the second line, i.e.
#T0:23:respawn:/sbin/getty -L ttyAMA0 115200 vt100
Finally you will need to reboot the Pi for the new settings to take effect. Once this is done, you can use
/dev/ttyAMA0 like any normal linux serial port, and you wont get any unwanted traffic confusing the attached devices.
The above instructions have been verified on Raspbian 'wheezy'; other distributions may be set up differently. To double-check, use
to show the current kernel command line, and
ps aux | grep ttyAMA0
to search for
getty processes using the serial port.
A tutorial on accessing the Pi's serial port from Python is available at Serial_port_programming.
You can have the RTS0 signal on GPIO 17 (P1-11) if you set it to ALT function 3. Likewise, the CTS0 is available on GPIO 30 (P5-05), if it is set to ALT function 3. You can control the settings of IOs with gpio_setfunc