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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
Pololu A-Star 32U4 Micro User's
Guide
http://www.pololu.com/docs/0J61/all Page 1 of 24
Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
1. Overview
The Pololu A-Star 32U4 Micro is a general-purpose programmable module based on Atmel’s ATmega32U4 AVR microcontroller, which has 32 KB of flash program memory, 2.5 KB of RAM, and built-in USB functionality. Onboard features of the A-Star
(abbreviated A*) include a 16 MHz resonator, a USB Micro-B connector, an in-system programming (ISP) header, and a pair of indicator LEDs. A voltage regulator and power selection circuit allow the board to be powered from either USB or an external 5.5 V to 15 V source, while a resettable PTC fuse on the USB VBUS supply and reverse protection on VIN help protect it from accidental damage.
The A-Star 32U4 Micro breaks out 15 general-purpose I/O lines along two rows of pins, including 7 usable as PWM outputs and 8
A-Star 32U4 Micro, bottom view with U.S.
quarter for size reference.
usable as analog inputs. It fits all this into a 20-pin dual in-line package (DIP) measuring only 1″ × 0.6″, and its 0.1″ pin spacing makes the A* easy to use with solderless breadboards [http://www.pololu.com/category/28/solderlessbreadboards] , perfboards, and 0.1″-pitch connectors [http://www.pololu.com/category/19/connectors] .
This product requires a USB A to Micro-B cable [http://www.pololu.com/product/1938] (not included) to connect to a computer.
Arduino compatibility
The A-Star 32U4 ships with a preloaded Arduino-compatible bootloader (which uses 4 KB of flash memory, leaving
28 KB available for the user program). We provide a software add-on that enables the board to be easily programmed from the Arduino environment.
The A-Star 32U4 uses the same microcontroller as the Arduino Leonardo [http://www.pololu.com/product/2192] and
Arduino Micro [http://www.pololu.com/product/2188] and runs at the same frequency, making it just as powerful.
Although the larger boards offer a few more I/O pins, the A-Star 32U4 Micro fits in an area half that of the Arduino
Micro, and it takes up only 11% as much area as a standard full-size Arduino!
1. Overview Page 2 of 24
Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
Pololu A-Star 32U4 Micro, Arduino Micro, and Arduino Leonardo.
1. Overview Page 3 of 24
Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
Features
• Dimensions: 1″ × 0.6″ (1.05″ × 0.6″ including USB Micro-B connector)
• Programmable 16 MHz Atmel ATmega32U4 AVR microcontroller
◦ 32 KB flash (4 KB used by bootloader, leaving 28 KB available for user program by default)
◦ 2.5 KB SRAM
◦ 1 KB EEPROM
◦ Native full-speed USB (12 Mbps)
• Preloaded with Arduino-compatible bootloader
• Many I/O lines in a small package
◦ 15 general-purpose I/O pins available along the sides of the board
◦ 3 additional I/O pins available on ISP header
◦ 7 pins can be configured as hardware PWM outputs
◦ 8 pins can be configured as analog inputs
• 2 user-controllable LEDs
• Can be powered from USB or external 5.5 V to 15 V source on VIN
• PTC fuse on VBUS supply
• Reverse-voltage protection on VIN supply
• 6-pin ISP header for use with an external programmer [http://www.pololu.com/product/1300]
1.1. Supported Operating Systems
The A-Star can be programmed using any operating system that supports the Arduino environment. We have tested the A-Star, our Arduino software add-on, and the Arduino IDE on Microsoft Windows 8.1, 8, 7, Vista, XP (with
Service Pack 3), Linux, and Mac OS X.
1. Overview Page 4 of 24
Pololu A-Star 32U4 Micro User's Guide
2. Contacting Pololu
We would be delighted to hear from you about any of your projects and about your experience with the Pololu A-Star. You can contact us
[http://www.pololu.com/contact] directly or post on our forum
[http://forum.pololu.com/] . Tell us what we did well, what we could improve, what you would like to see in the future, or anything else you would like to say!
© 2001–2014 Pololu Corporation
2. Contacting Pololu Page 5 of 24
Pololu A-Star 32U4 Micro User's Guide
3. Pinout and Components
Pinout
© 2001–2014 Pololu Corporation
The diagram above identifies the I/O and power pins on the A-Star 32U4 Micro; yellow labels represent digital I/O pins and green labels represent analog input channels. Light text on a dark background indicates Arduino digital and analog pin numbering, which can be used to refer to the pins when writing code in the Arduino environment. Dark text on a light background indicates a name or function of the pin as defined in the ATmega32U4 datasheet. For more information about the ATmega32U4 microcontroller on this board, see Atmel’s ATmega32U4 documentation
[http://www.atmel.com/devices/atmega32u4.aspx] .
Printed on the A-Star are indicators that you can use to quickly identify each pin’s capabilities: a triangle next to the pin means it can be used as an analog input, and a square wave symbol under the pin number means it can be used as a PWM output.
LEDs
The A-Star 32U4 Micro has two indicator LEDs.
The yellow LED is connected to Arduino pin 13, or PC7. You can drive this pin high in a user program to turn this
LED on. The A-Star 32U4 Bootloader [http://www.pololu.com/docs/0J61/7] fades this LED on and off while it is waiting for a sketch to be loaded.
The green LED is connected to PD5 and lights when the pin is driven low. While the board is running the A-Star
32U4 Bootloader or a program compiled in the Arduino environment, it will flash this LED when it is transmitting data via the USB connection.
Connectors
The A-Star 32U4 includes a USB Micro-B connector that can be used to connect to a computer’s USB port via a USB
A to Micro-B cable [http://www.pololu.com/product/1938] (not included). The USB connection can be used to transmit
3. Pinout and Components Page 6 of 24
Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation and receive data from the computer, and a preloaded USB bootloader makes it possible to program the board over
USB. The USB connection can also provide power to the A-Star.
The board also has a 6-pin ISP header that allows it to be programmed with an external programmer, such as our USB
AVR programmer [http://www.pololu.com/product/1300] . Pin 1 of the header is indicated with a small white dot and has an octagonal shape.
Power
The A-Star 32U4 Micro can either be powered directly from the USB 5 V supply or from a separate source on the
VIN pin. The board features a power selection circuit that allows both USB and VIN to be connected at the same time; if this is done, the A-Star will draw power from USB.
USB power input: The A-Star can be powered from the USB 5 V bus voltage (VBUS) if it is connected to a USB cable. A resettable PTC fuse on VBUS makes it less likely for the A-Star (and the connected computer or other device) to be damaged if too much current is drawn from the USB connection.
VIN power input: The A-Star can be powered from VIN if you connect a 5.5 V to 15 V power supply (such as a battery or wall power adapter) to the VIN and GND pins, with the positive terminal connected to VIN. It will draw power from VIN only if USB is disconnected.
When powering the A-Star 32U4 Micro from VIN, a minimum voltage of 5.5 V is required to ensure that the board’s 5 V supply is stable. Even if power is being provided to the A-Star via USB, connecting a voltage higher than 0 V but lower than 5.5 V to VIN is not recommended, as this can interfere with the power selection circuit and cause the 5 V line to drop (potentially triggering a brown-out reset).
5V power output: This pin provides access to the board’s 5 V supply, which comes from either the USB 5 V bus voltage or a low-dropout (LDO) regulator on VIN, depending on which power source is connected. The regulator can supply up to 100 mA, although some of this is used by the board itself (typically about 25 mA) or used to provide current for the GPIO pins or 3.3 V power output (see below).
3V3 power output: This pin gives access to the output of the internal 3.3 V regulator inside the ATmega32U4.
The microcontroller uses this regulated voltage for USB signaling, but up to about 50 mA is available for powering external circuits or devices.
When the A-Star 32U4 Micro is being powered through VIN, the sum of the 5V output current, 3V3 output current,
GPIO output current, and current used by the board itself should not exceed the 100 mA that the regulator can provide.
3. Pinout and Components Page 7 of 24
Pololu A-Star 32U4 Micro User's Guide
4. Schematic Diagram
© 2001–2014 Pololu Corporation
Pololu A-Star 32U4 Micro schematic diagram.
This schematic is also available as a printable PDF [http://www.pololu.com/file/download/pololu-astar-32U4-micro-schematic-diagram.pdf?file_id=0J742] (253k pdf).
4. Schematic Diagram Page 8 of 24
Pololu A-Star 32U4 Micro User's Guide
5. Getting Started
5.1. Installing Windows Drivers
© 2001–2014 Pololu Corporation
If you use Windows XP, you will need to have either Service Pack 3 [http://www.microsoft.com/downloads/ details.aspx?FamilyId=68C48DAD-BC34-40BE-8D85-6BB4F56F5110] or Hotfix KB918365 installed before installing the drivers for the A-Star. Some users who installed the hotfix have reported problems which were solved by upgrading to Service Pack 3, so we recommend Service Pack 3 over the hotfix.
Before you connect your Pololu A-Star 32U4 Micro to a computer running Microsoft Windows, you must install its drivers:
1. Download the A-Star Software and Drivers [http://www.pololu.com/file/download/a-star-1.0.1.zip?file_id=0J743]
(98k zip) and extract the ZIP file to a temporary folder on your computer. These files are also available from the
A-Star repository on GitHub [https://github.com/pololu/a-star] .
2. Open the “drivers” folder. Right-click on “a-star.inf” and select “Install”.
3. Windows will ask you whether you want to install the drivers. Click “Install” (Windows 8, 7, and Vista) or
“Contiue Anyway” (Windows XP).
4. Windows will not tell you when the installation is complete, but it should be done after a few seconds.
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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
Windows 8, Windows 7, and Windows Vista users: After installing the drivers, your computer should automatically recognize the A-Star when you connect it via USB. No further action from you is required. However, the first time you connect an A-Star to your computer, Windows will take several seconds to recognize the device and configure itself properly. The first time you program the A-Star, Windows will again take several seconds to recognize the A-
Star’s USB bootloader, and this could cause the programming operation to fail the first time. Also, Windows will need to re-recognize the A-Star and the bootloader if you connect the board to another USB port that it has not been connected to before.
Windows XP users: After installing the drivers, you will need to follow steps 5–9 for each new A-Star you connect to your computer. You will also need to follow these steps the first time you attempt to program the A-Star in order to make Windows recognize the bootloader, and when you connect the A-Star to a different USB port that it has not been connected to before.
5. Connect the A-Star to your computer’s USB port.
6. When the “Found New Hardware Wizard” is displayed, select “No, not this time” and click “Next”.
7. On the second screen of the “Found New Hardware Wizard”, select “Install the software automatically” and click “Next”.
8. Windows XP will warn you again that the driver has not been tested by Microsoft and recommend that you stop the installation. Click “Continue Anyway”.
9. When you have finished the “Found New Hardware Wizard”, click “Finish”.
5.2. Programming using the Arduino IDE
The Pololu A-Star can be programmed from the popular Arduino integrated development environment (IDE). The Arduino IDE is a cross-platform, open source application that integrates a C++ code editor, the GNU C++ compiler, and a program upload utility. To get started programming the A-Star with the Arduino IDE, follow these steps:
1. Download the Arduino IDE from the Arduino Download page [http://arduino.cc/en/Main/Software] and install it. You can download either the 1.0.x version or the 1.5.x version; the A-Star supports both.
2. If you have not done so already, download the A-Star
Software and Drivers [http://www.pololu.com/file/download/astar-1.0.1.zip?file_id=0J743] (98k zip). These files are also available from the A-Star repository on GitHub [https://github.com/pololu/astar] . Copy the “pololu” folder from the downloaded “add-on” folder into the [sketchbook location]/hardware folder. You can see the sketchbook location in the Arduino IDE Preferences dialog, which is available from the File menu. For a typical user, the sketchbook location will be a folder named Arduino inside the
Programming the A-Star 32U4 from the
Arduino IDE.
Documents folder. For a typical Windows user running a recent version of Windows, the “pololu” folder should be installed in this location:
C:\Users\<username>\Documents\Arduino\hardware\pololu
If the “Arduino” or “hardware” directories do not exist yet, you will need to create them.
3. Close the Arduino IDE if it is open, and then restart it.
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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
4. In the Tools > Board menu, select the “Pololu A-Star 32U4” entry. If you do not see the A-Star listed in the Board menu, then the add-on is probably not installed correctly. Try doing step 2 again and restarting the
Arduino IDE.
Selecting the Pololu A-Star 32U4 in the Boards menu.
5. In the Tools > Port menu, select the port for the A-Star. On Windows you can determine what COM port the
A-Star is assigned to by looking at the “Ports (COM & LPT)” section of the Device Manager. On Linux, the port name will begin with “/dev/ttyACM”. On Mac OS X, the port name will begin with “/dev/tty.usbmodem”.
Windows 8 device manager showing the A-Star’s virtual COM port.
6. Open up the “Blink” Arduino example, which can be found under File > Examples > 01.Basics > Blink.
The code in this example will make the A-Star blink its yellow LED. When you select the Blink example, a new
Arduino IDE window will open up. It is OK to close the first window.
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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
Selecting the Blink example in the Arduino IDE.
7. Press the “Upload” button to compile the sketch and upload it to the A-Star. If everything goes correctly, you will see the message “Done uploading” appear near the bottom of the window. If you are using Windows and you have not previously programmed an A-Star on this USB port, then Windows might take several seconds to recognize the A-Star bootloader. The bootloader times out after 8 seconds and goes back to running the sketch, so the upload might fail if Windows does not recognize it quickly enough. If this happens, try again. If you are using Windows XP and have not programmed an A-Star on this USB port, you will have to go through the Found
New Hardware Wizard again as described in
, but the second time you try to upload it should work. If the Arduino IDE has trouble connecting to the port or using it, try unplugging the A-Star, closing any programs that might be using the serial port, restarting the Arduino IDE, and then plugging the A-Star back in.
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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
Uploading a sketch to the A-Star using the Arduino IDE.
8. If you uploaded the Blink sketch, then the A-Star’s yellow LED should be blinking once every two seconds.
However, we ship the A-Star with that same example already programmed onto it, so you might not be convinced that anything has changed. Try changing the delay values in the sketch to something else and uploading again to see if you can change the speed of the LED.
The A-Star is similar enough to the Arduino Leonardo that you do not actually have to install the addon. If you want to, you can just select the “Arduino Leonardo” board in the Arduino IDE. Note that if you upload a sketch to the A-Star this way, your computer will then recognize it as a Leonardo (for example, its entry in the Windows Device Manager will display “Arduino Leonardo”).
After you succeed in programming the A-Star from the Arduino IDE, there are many resources you can use to learn more:
• The Arduino IDE has many examples [http://arduino.cc/en/Tutorial/HomePage] that can run on the A-Star.
• The Arduino website has a Language Reference [http://arduino.cc/en/Reference/HomePage] , a wiki called the The
Arduino Playground [http://playground.arduino.cc/] , and other resources.
• The A-Star is very similar to the Arduino Leonardo [http://www.pololu.com/product/2192] and Arduino Micro
[http://www.pololu.com/product/2188] , so you can search the Internet for relevant projects that use one of those boards.
•
lists many more resources.
5.3. Programming using avr-gcc and AVRDUDE
This sections explains how to program the A-Star using the avr-gcc toolchain and AVRDUDE. This section is intended for advanced users who do not want to use the Arduino IDE as described in
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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
Getting the prerequisites
If you are using Windows, we recommend downloading WinAVR [http://winavr.sourceforge.net/] , which contains the avrgcc toolchain and a command-line utility called AVRDUDE [http://www.nongnu.org/avrdude/] that can be used to upload programs to the A-Star bootloader. If the version of GNU make that comes with WinAVR crashes on your computer, we recommend using the Pololu version of GNU make [https://github.com/pololu/make/releases] .
If you are using Mac OS X, we recommend downloading the CrossPack for AVR Development [http://www.obdev.at/ products/crosspack] .
If you are using Linux, you will need to install avr-gcc, avr-libc, and AVRDUDE. Ubuntu users can get the required software by running: sudo apt-get install gcc-avr avr-libc avrdude
After you have installed the prerequisites, open a command prompt and try running these commands to make sure all the required utilities are available: avr-gcc -v avr-objcopy -V make -v avrdude
If any of those commands fail, make sure the desired executable is installed on your computer and make sure that it is in a directory listed in your PATH environment variable.
Compiling an example program
Copy the following code to a file named “main.c”:
#define F_CPU 16000000
#include <avr/io.h>
#include <util/delay.h> int main()
{
DDRC |= (1 << DDC7); // Make pin 13 be an output.
while(1)
{
PORTC |= (1 << PORTC7); // Turn the LED on.
_delay_ms(500);
PORTC &= ~(1 << PORTC7); // Turn the LED off.
_delay_ms(500);
}
}
In the same folder, create a file named “Makefile” with the following contents:
PORT=\\\\.\\USBSER000
MCU=atmega32u4
CFLAGS=-g -Wall -mcall-prologues -mmcu=$(MCU) -Os
LDFLAGS=-Wl,-gc-sections -Wl,-relax
CC=avr-gcc
TARGET=main
OBJECT_FILES=main.o
all: $(TARGET).hex
clean: rm -f *.o *.hex *.obj *.hex
%.hex: %.obj
avr-objcopy -R .eeprom -O ihex $< $@
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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
%.obj: $(OBJECT_FILES)
$(CC) $(CFLAGS) $(OBJECT_FILES) $(LDFLAGS) -o $@ program: $(TARGET).hex
avrdude -p $(MCU) -c avr109 -P $(PORT) -U flash:w:$(TARGET).hex
Make sure that the PORT variable in the Makefile is set to the name of the A-Star’s virtual serial port. In Windows,
\\\\.\\USBSER000 should work if the A-Star is the only USB device connected that is using the usbser.sys driver, but you can change it to be the actual name of the COM port (e.g.
COM13 ).
In a command prompt, navigate to the directory with the Makefile and main.c. If you run the command make , the code should get compiled and produce a file named “main.hex”.
Programming
To program the A-Star, you will need to get it into bootloader mode first. One way to do this is to reset the AVR twice within 750 ms. A pushbutton can be connected between the GND and RST pins to serve as a reset button, or you can use a wire. Once the A-Star is in bootloader mode, quickly run the command make program to program the A-Star. If you wait longer than 8 seconds, the A-Star bootloader will exit and the AVR will go back to running the user program.
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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
6. The A-Star 32U4 USB Interface
The A-Star 32U4 Micro is based on a single AVR ATmega32U4 microcontroller that runs the user program and also handles the USB connection to the computer. The AVR has a full-speed USB transceiver built into it and can be programmed to present almost any type of USB device interface to the computer.
USB is an asymmetric system that consists of a single “host” connected to multiple “devices”. The host is typically a personal computer. The ATmega32U4 can only act as a USB device, so the A-Star cannot be connected to other USB devices; it can only be connected to a host such as your computer.
Programming the A-Star using the Arduino IDE as described in
will automatically configure it as a composite device with a single virtual serial port and a human interface device (HID) with a keyboard and mouse.
Since we preload an example Arduino sketch on each A-Star before it ships, this is the default USB configuration of the A-Star.
On a Windows computer, you can see the virtual serial port by going to your computer’s Device Manager and expanding the “Ports (COM & LPT)” list. You should see a COM port labeled “Pololu A-Star 32U4”. In parentheses after the name, you will see the name of the port (e.g. “COM3” or “COM4”). Windows will assign a different COM port number to the A-Star depending on what USB port you plug it into and whether it is in bootloader mode or not. If you need to change the COM port number assigned to the A-Star, you can do so using the Device Manager. Doubleclick on the COM port to open its properties dialog, and click the “Advanced…” button in the “Port Settings” tab.
From this dialog you can change the COM port assigned to the A-Star.
Windows 8 device manager showing the A-Star’s virtual COM port.
On a Windows computer, you can see the rest of the A-Star’s USB interface by going to the Device Manager, selecting
View > Devices by connection, and then expanding entries until you find the “Pololu A-Star 32U4” COM port. Near it, you should see the parent composite device and the human interface device.
6. The A-Star 32U4 USB Interface Page 16 of 24
Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
The Windows 8 Device Manager in “Devices by connection” mode, showing that the A-Star is a composite device.
On a Linux computer, you can see details about the A-Star’s USB interface by running lsusb -v -d 1ffb: in a
Terminal. The virtual serial port can be found by running ls /dev/ttyACM* in a Terminal.
On a Mac OS X computer, the virtual serial port can be found by running ls /dev/tty.usbmodem* in a Terminal.
You can send and receive bytes from the A-Star’s virtual serial port using any terminal program that supports serial ports. Some examples are the Serial Monitor in Arduino IDE, the Pololu Serial Transmitter Utility
[http://www.pololu.com/docs/0J23] , Br@y Terminal [http://sites.google.com/site/terminalbpp/] , PuTTY
[http://www.chiark.greenend.org.uk/~sgtatham/putty/] , TeraTerm [http://ttssh2.sourceforge.jp/] , Kermit [http://www.columbia.edu/ kermit/ck80.html] , and GNU Screen [http://www.gnu.org/software/screen/] . Many computer programming environments also support sending and receiving bytes from a serial port.
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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
7. The A-Star 32U4 Bootloader
The A-Star comes with a USB bootloader that can be used in conjunction with the Arduino IDE or AVRDUDE to load new programs onto the A-Star. This section documents some technical details of the bootloader for advanced users who want to better understand how it works. If you just want to get started using your A-Star, it is fine to skip this section.
The A-Star 32U4 Bootloader is based on the Caterina bootloader [https://github.com/arduino/Arduino/tree/master/ hardware/arduino/bootloaders/caterina] , which is the bootloader used on the Arduino Leonardo
[http://www.pololu.com/product/2192] , Arduino Micro [http://www.pololu.com/product/2188] and several other ATmega32U4 boards. The bootloader is open source and its source code [https://github.com/pololu/a-star/tree/master/bootloaders/caterina] is available on GitHub. The bootloader occupies the upper four kilobytes of the ATmega32U4’s program memory, leaving 28 KB for the user program. The bootloader’s USB interface consists of a single virtual serial port that accepts the programming commands defined in AVR109 [http://www.atmel.com/images/doc1644.pdf] . The bootloader always runs first immediately after the AVR is reset.
Startup logic
The main difference between the A-Star 32U4 Bootloader and Caterina is in the startup logic. This is the part of the bootloader that runs immediately after the AVR is reset, and it decides whether to run the user program or run the rest of the bootloader. The startup logic of the Caterina bootloader is designed so that when the RST line goes low, the bootloader will run. This means that if you want to restart your program using the RST line, it will take 8 seconds before the bootloader times out waiting for an upload and the sketch starts.
The A-Star 32U4 has different startup logic that allows you to use the RST line to reset the board with a smaller delay.
If the RST line goes low once, the user program will run after a 750 ms delay. If the RST line goes low twice within
750 ms, then the bootloader will run. (This behavior is the same as on boards like SparkFun’s Pro Micro.)
The start-up logic of the A-Star 32U4 bootloader is shown in the flowchart below:
7. The A-Star 32U4 Bootloader Page 18 of 24
Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
The startup logic for the A-Star 32U4 bootloader.
Brown-out detection
Unlike many other ATmega32U4 boards, the A-Star has brown-out detection enabled. The A-Star’s brown-out threshold is 4.3 V, and if the voltage on VCC goes below this then the AVR will reset. The A-Star bootloader was designed so that the user program can detect brown-out resets. To do so, check to see if the BORF bit in the MCUSR register is set, and then clear it later. Here is some example code you could put in your setup function for detecting brown-out resets:
7. The A-Star 32U4 Bootloader Page 19 of 24
Pololu A-Star 32U4 Micro User's Guide pinMode(13, OUTPUT); if (MCUSR & (1 << BORF))
{
// A brownout reset occurred. Blink the LED
// quickly for 2 seconds.
for(uint8_t i = 0; i < 10; i++)
{ digitalWrite(13, HIGH); delay(100); digitalWrite(13, LOW); delay(100);
}
}
MCUSR = 0;
© 2001–2014 Pololu Corporation
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Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
8. Reviving an unresponsive A-Star
In order to load a new program onto your A-Star, you will need to get it into bootloader mode and send programming commands to it over its virtual serial port using appropriate software. If you are programming the A-Star from the
Arduino IDE, the sketch loaded onto the A-Star will generally support a special USB command for putting the A-
Star mode in bootloader mode, and the Arduino IDE sends that command automatically when you press the Upload button. However, you might find yourself in a situation where the A-Star is unresponsive and that method will not work. This can happen for two reasons:
• You accidentally loaded a malfunctioning program onto the A-Star that is incapable of responding to the special USB command. For example, your program might be stuck in an infinite loop with interrupts disabled.
• You loaded a program which uses a non-standard type of USB interface or no USB interface.
The following sections provide different procedures you can use to revive your A-Star.
8.1. Reviving using the Arduino IDE
This section explains two special methods for programming an A-Star using the Arduino IDE in case your usual method of programming is not working. These instructions were developed for the Arduino IDE versions 1.0.5-r2 and
1.5.6-r2, and they might need to be modified for future versions.
Reset button
If you have not done so already, you should connect a momentary pushbutton [http://www.pololu.com/product/1400] between the GND and RST pins of the A-Star to serve as a reset button. Alternatively, you can use a wire to temporarily connect GND and RST together instead of using a reset button.
Resetting the board twice within 750 ms makes the board go into bootloader mode. The bootloader will exit after 8 seconds and try to run the sketch again if it has not started receiving programming commands. To revive the A-Star, you need to make sure you start sending it programming commands before the 8-second period is over.
In bootloader mode, the yellow LED (the one labeled L) fades in and out. It is useful to look at this LED so you can know what mode the microcontroller is in. Also, we recommend enabling verbose output during upload using the Arduino IDE’s “Preferences” dialog. Looking at the LED and looking at the verbose output during the following procedures will help you understand what is going on.
The uploading-before-bootloader method (Arduino 1.0.x only)
The goal of the uploading-before-bootloader method is to select a non-existent serial port in the Arduino IDE and then make sure the Arduino IDE enters the uploading phase before the microcontroller goes into bootloader mode.
This method does not work on the Arduino IDE 1.5.6-r2 and later because those versions of the IDE give a fatal error message if the selected serial port is not present at the beginning of the uploading phase (e.g. “Board at COM7 is not available.”).
1. Connect the A-Star to your computer via USB.
2. In the “Tools” menu, open the “Board” sub-menu, and select “Pololu A-Star 32U4”.
3. In the “Tools” menu, open the “Port” sub-menu, and check to see if any ports are selected. If the “Port” menu is grayed out or no ports in it are selected, that is good, and you can skip to step 6.
4. Reset the board twice to get the board into bootloader mode. While the board is in bootloader mode, quickly select the new serial port that corresponds to the bootloader in the “Port” menu.
5. After 8 seconds, the bootloader will exit and attempt to run the sketch again. Wait for the bootloader to exit.
Verify that either the “Port” menu is grayed out or no ports in it are selected.
8. Reviving an unresponsive A-Star Page 21 of 24
Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
6. Click the Upload button. The Arduino IDE will compile your sketch and start uploading it.
7. As soon as the large status bar near the bottom of the IDE says “Uploading…”, press reset the board twice to get into bootloader mode.
The Arduino IDE will stay in the uploading phase for 10 seconds, waiting for a new serial port to appear. Once the serial port of the bootloader appears, the Arduino IDE will connect to it and send programming commands.
The bootloader-before-uploading method
The goal of the bootloader-before-uploading method is to select the bootloader’s virtual serial port in the Arduino IDE and then make sure the board is in bootloader mode at the time when the Arduino IDE enters the uploading phase.
1. Connect the A-Star to your computer via USB.
2. In the “Tools” menu, open the “Board” sub-menu and check to see if the “Pololu A-Star 32U4 (bootloader port)” entry is visible. If this entry is visible, you can skip to step 6.
3. If you are using a 1.0.x version of the Arduino IDE, open the file [sketchbook location]/hardware/pololu/
boards.txt using a text editor. If you are using a 1.5.x version of the Arduino IDE, open the file [sketchbook
location]/hardware/pololu/avr/boards.txt using a text editor. You can see the sketchbook location in the
Arduino IDE preferences dialog. The file you are looking for is part of the A-Star add-on.
4. In the boards.txt file that you opened, find the lines at the bottom of the file that start with #a-star32U4bp .
Uncomment each of those lines by deleting the “#” character, and then save the file.
5. Close the Arduino IDE and restart it.
6. In the “Tools” menu, open the “Board” sub-menu and select “Pololu A-Star 32U4 (bootloader port)”. This entry is configured so that the Arduino IDE will send programming commands directly to selected serial port, instead of trying to send a special USB command to the port to get it into bootloader mode and then waiting for the new port to appear. By selecting this entry, the timing of the programming process below becomes easier, especially on Windows.
7. Prepare the computer to show you a list of its virtual serial ports. If you are using Windows, this means you should open the Device Manager. If you are on Linux or Mac OS X, this means you should open a Terminal and type the command ls /dev/tty* but do not press enter until the board is in bootloader mode in the next step.
8. Reset the board twice to get the board into bootloader mode. While it is in bootloader mode, quickly look at the list of serial ports provided by your operating system in order to determine what port the bootloader is assigned to.
9. Reset the board twice to get the board into bootloader mode again. While the board is in bootloader mode, quickly select the serial port of the bootloader in the Arduino IDE. The port can be selected in the “Port” submenu under “Tools”.
10. In the Arduino IDE, click the “Verify” button to compile your sketch. This could make the timing easier during the next step.
11. Press the reset button twice to get the board into bootloader mode again. As soon as you see the yellow
LED fading in and out, press the Upload button.
The Arduino IDE will compile your sketch and then upload it to the selected serial port.
If the compilation of the sketch takes longer than 8 seconds, then this procedure will fail because the bootloader will time out and start trying to run the malfunctioning sketch again. If that happens, try the procedure again using a simpler sketch such as the Blink example that can be found under File > Examples > 01.Basics > Blink.
8. Reviving an unresponsive A-Star Page 22 of 24
Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
8.2. Reviving using AVRDUDE
This section explains a special method for reviving an A-Star using the command-line utility AVRDUDE
[http://www.nongnu.org/avrdude/] in case your usual method of programming is not working. AVRDUDE stands for “AVR
Downloader/UploaDEr”, and it is compatible with the A-Star bootloader.
If you have not done so already, you should connect a momentary pushbutton [http://www.pololu.com/product/1400] between the GND and RST pins of the A-Star to serve as a reset button. Alternatively, you can use a wire to temporarily connect GND and RST together instead of using a reset button.
1. Connect the A-Star to your computer via USB.
2. Prepare the computer to show you a list of its virtual serial ports. If you are using Windows, this means you should open the Device Manager. If you are on Linux or Mac OS X, this means you should open a Terminal and type the command ls /dev/tty* but do not press enter until the board is in bootloader mode in the next step.
3. Press the reset button twice within 750 ms to make the AVR go into bootloader mode. You should see the yellow LED fading in and out when the AVR is in bootloader mode. While it is in bootloader mode, quickly look at the list of serial ports provided by your operating system in order to determine what port the bootloader is assigned to.
4. Type the following command in your terminal and replace COM4 with the name of the bootloader’s serial port, but do not press enter yet. This command will erase the malfunctioning program on the A-Star but preserve the bootloader.
avrdude -c avr109 -p atmega32U4 -P COM4 -e
5. Press the reset button twice within 750 ms to make the AVR go into bootloader mode.
6. Quickly run the command you typed previously. The command needs to be run within 8 seconds of starting the bootloader, or else the bootloader will exit and try to run the malfunctioning program again.
By following the instructions above, the malfunctioning program on the A-Star will be erased and the A-Star will stay in bootloader mode indefinitely. You can now load another program onto it using the Arduino IDE or AVRDUDE.
8. Reviving an unresponsive A-Star Page 23 of 24
Pololu A-Star 32U4 Micro User's Guide © 2001–2014 Pololu Corporation
9. Related Resources
To learn more about using the Pololu A-Star, see the following list of resources:
• The Arduino IDE has many examples [http://arduino.cc/en/Tutorial/HomePage] that can run on the A-Star.
• The Arduino website has a Language Reference [http://arduino.cc/en/Reference/HomePage] , a wiki called the The
Arduino Playground [http://playground.arduino.cc/] , and other resources.
• The A-Star is very similar to the Arduino Leonardo [http://www.pololu.com/product/2192] and Arduino Micro
[http://www.pololu.com/product/2188] , so you can search the Internet for relevant projects that use one of those boards.
• Atmel’s ATmega32U4 documentation [http://www.atmel.com/devices/atmega32u4.aspx] has the ATmega32U4 datasheet and many related documents.
• AVR Libc Home Page [http://www.nongnu.org/avr-libc/] : this page documents the standard library of functions that you can use with GNU C and C++ compilers for the AVR.
• LUFA – the Lightweight USB Framework for AVRs [http://www.fourwalledcubicle.com/LUFA.php]
• WinAVR [http://winavr.sourceforge.net/]
• Atmel Studio 6 [http://www.atmel.com/microsite/atmel_studio6/]
• AVRDUDE [http://www.nongnu.org/avrdude/]
• AVR Freaks [http://www.avrfreaks.net/]
Finally, we would like to hear your comments and questions on the A-Star section of the Pololu Robotics Forum
[http://forum.pololu.com/viewforum.php?f=10] !
9. Related Resources Page 24 of 24
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