HSC2011/Building your own EduBuzzer

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Version vom 1. Mai 2011, 22:00 Uhr von Chrysn (Diskussion | Beiträge) (building instructions part 1)
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< HSC2011

Requirements

In order to build an EduBuzzer, you'll need

Hardware

The main board

If your hardware-fu is stong, the board will assemble iself

For etching the main board, you'll find all required files in the `hardware/gerber` subdirectory of the repository, or you can directly use the Eagle files in `hardware`. For building an ergonomic buzzer, use the `buzzer` files.

The arduino shield -- comparison between the prototyping and our custom shield

As an alternative (to try it out with less effort), use the `arduino_schield` files -- with them, you need fewer components, and get an arduino shield you can plug onto an Arduino compatible device. If you are good at soldering and want to get going with what is present in a typical hackerspace (at least, in the metalab), you can produce the same circuit even on a prototyping shield.

Solder in all the components as described in the part list, starting with the big parts. We recommend to use sockets for both the ATMega328 and the RFM12B module, as they are prone to overheating from inexperienced soldering, and as there is no programming header exposed for the ATMega. (Updates can be flashed using a serial bootloader, but if you break something, things get tricky.) Other parts to take care of:

  • R10 -- don't install it, it's for adjusting the compatibility behavior with respect to Arduino's DTR handling, and
  • SW5 -- connect using about 5cm of cable, as the switch is installed in a dedicated slot in the case.

Checkpoint: You can try out the hardware immediately by flashing `firmware/ioexample.hex` onto an ATMega328 (works even with the ATMega328 built in in an Arduino -- just flash it as normal, take out the chip put it into the buzzer's socket). The device will:

  • when the first button is pressed, blink through all LEDs,
  • when the second button is pressed, make sounds while toggling through the LEDs,
  • when the third button is pressed, fade the RGB LED around all colors,
  • when the last button is pressed, send commands over radio,
  • when an iButton is inserted, show a hash of its ID on the LEDs, and buzz six times.

When the IO-example is flashed on two devices, the second should respond to the radio commands and cycle through its own LEDs.