Difference between revisions of "AVR"

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===PlanetCCRMA Linux on your own PC===
 
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Revision as of 15:12, 15 February 2007

AVR Microcontrollers

AVR 8-bit RISC microcontrollers by Atmel are currently at the heart of the embedded technology platform we use in Physical Interaction Design research and courses at CCRMA. These chips have a modern Harvard Architecture, executing most instruction cycles in a single clock cycle. An extremely efficient open source C compiler is available, and these devices are used and supported by a large community of developers. The AVR architecture and instruction set is available in a large family of 8-bit devices that come in a variety of packages. AVR-series chips come with as little as 1 Kbyte of Flash program memory, up to 256 Kbytes; 32 bytes to 8 Kbytes of RAM; and up to 20 MHz clock speeds. Specialized AVR devices exist for automotive, LCD and lighting control, USB and radio applications. Code is easily portable between devices.

AVR Hardware at CCRMA

ATMega32

We currently use the ATMega 32 (Product Page). It features:

  • 32 Kbyte self-programming Flash Program Memory
  • 2 Kbyte SRAM
  • 1 Kbyte EEPROM
  • 8-Channel 10-bit A/D-converter
  • Up to 16 Mhz clock
  • I2C, SPI interfaces
  • 1 USART, 2-channels PWM, 2 ext. interrupts

ATMega 32 Documentation:

AVRmini Development Board

The AVRmini development board, made by Pascal Stang, is a general purpose prototyping board that provides easy access to the AVR's I/O and programming interfaces, along with a number of useful peripheral devices. We are currently using the AVRmini v4.0. The AVRmini v4.0 provides:

  • Support for most 40-pin AVR processors
  • Ethernet, USB, SD/MMC, RS-232 I/O
  • I2C header
  • Character LCD header
  • 10-pin I/O headers
  • 4 buttons and 4 LEDs
  • 5-V regulator

AVRmini Documentation:

CCRMA's AVR Prototyping Kit

For our PID courses at CCRMA, we assemble a prototyping kit based on the AVRmini. We mount the AVRmini on a sheet of 1/8" acrylic, and add solderless breadboard strips, an LCD display and a small loudspeaker. Pins 9 and 10 of the AVRmini v4.0's "AUX" header (JP13) are connected to the ground and +5V power rails of the breadboard strips.

  • kit Photo

Spyglass User Interface Board

The LCD display on CCRMA's prototyping board is part of the Spyglass User interface Board, which communicates with the AVR via I2C. We purchased these on eBay, and from a few other places, but they are hard to come by these days. Pascal Stang has written a brief Spyglass User Guide. He has also developed a replacement I2C button module/LCD driver (no documentation available) to which we can connect an LCD display and use just like the Spyglass.

  • Spyglass photo
  • buttonmodule photo


AVR Software at CCRMA

AVRLib

avr-gcc

Setting up your Computer to do AVRLib / CCRMA-Style AVR Development

Linux Machines at CCRMA

PlanetCCRMA Linux on your own PC

Mac OS X

Windows

Communicating with Pd via OSC over USB

Linux Machines at CCRMA

PlanetCCRMA Linux on your own PC

Mac OS X

Windows

Communicating with Max/MSP via OSC over USB

Mac OS X

Windows

Communicating via OSC over udp