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64K Byte self-programming Flash Program Memory, 4K Byte Boot Code section, 4K Byte SRAM, and 2K Bytes EEPROM. 4-channel DMA controller, 8-channel Event System, and Up to 32 MIPS throughput at 32 MHz.
12-bit ADC, 12-bit DAC and analog comparators. AES and DES crypto engines, 16-bit Timer Counters, USART, SPI, and TWI.
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ATxmega64A1/128A1/192A1/256A1/384A1 Preliminary
(99 pages, revision I, updated 4/09)
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AVR XMEGA A Manual Preliminary
(445 pages, revision G, updated 4/09)
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AVR042: AVR Hardware Design Considerations
(14 pages, revision F, updated 4/08)
This Application Note covers the most common problems encountered when switching to a new microcontroller architecture like the AVR. Solutions and considerations for the most common design challenges are covered.
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AVR1000: Getting Started Writing C-code for XMEGA
(15 pages, revision A, updated 2/08)
Short development times and high quality requirements on electronic products has made high-level programming languages a requirement. The choice of programming language alone does not ensure high readability and reusability; good coding style does. Therefore the XMEGA peripherals, header files and drivers are designed with this in mind.
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AVR1001: Getting Started With the XMEGA Event System
(8 pages, revision A, updated 2/08)
The XMEGA™ event system is a set of features that allows peripherals to interact without intervention from the CPU. Several peripheral modules can generate events, often on the same conditions as interrupt requests.
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AVR1003: Using the XMEGA Clock System
(10 pages, revision E, updated 11/09)
The XMEGA™ Clock System is a set of highly flexible modules that provides a large portfolio of internal and external clock sources. An internal high-frequency PLL and a flexible prescaler block provide a vast amount of possible clock source configurations, both for the CPU and peripherals.
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AVR1005: Getting started with XMEGA
(11 pages, revision B, updated 11/09)
The AVR® product portfolio has been expanded with the XMEGA™ family. Many ask if this is a new architecture and are uncertain how their experience with megaAVR® transfers to AVR XMEGA. This document briefly introduces the similarities and differences between the two AVR families, and provides an overview of the available tool chain.
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AVR1010: Minimizing the power consumption of XMEGA devices
(13 pages, revision B, updated 11/09)
This application note describes what must be done to achieve the lowest possible power consumption for XMEGA devices. Example code is also supplied, which compiles with both GCC and IAR Embedded Workbench®.
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 Other Related Application Notes |
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AVR JTAGICE mkII |
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AVR ONE! |
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See more FAQs |
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AVR and AVR32 - Quick Reference Guide
(Overview, 68 pages, revision I, updated 5/09)
Introduction of the product range of AVR and AVR32 microcontrollers and application processors:
- Device family description
- Key features
- Device selection guides
- Application oriented device families
- Tools offer
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AVR Instruction Set
(User Guide, 155 pages, revision H, updated 7/09)
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AVR XMEGA
(Flyer, 12 pages, revision C, updated 10/08)
8/16-bit High Performance Low Power Flash Microcontrollers |
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Introducing a New Breed of Microcontrollers for 8/16-bit Applications
(White Paper, 15 pages, revision A, updated 02/08)
This whitepaper discusses the key challenges that 8/16-bit embedded developers
meet and how the new XMEGA AVR family from Atmel brings 8/16-bit microcontrollers up to a new
level of system performance. |
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