ATXMEGA256A3U-MHR - MICROCHIP TECHNOLOGY

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Features

zHigh-performance, low-power Atmel® AVR® XMEGA® 8/16-bit Microcontroller

zNonvolatile program and data memories

64K - 256KBytes of in-system self-programmable flash

4K - 8KBytes boot section

2K - 4KBytes EEPROM

4K - 16KBytes internal SRAM

zPeripheral features

Four-channel DMA controller

Eight-channel event system

Seven 16-bit timer/counters

zFour timer/counters with four output compare or input capture channels

zThree timer/counters with two output compare or input capture channels

zHigh resolution extension on all timer/counters

zAdvanced waveform extension (AWeX) on one timer/counter

One USB device interface

zUSB 2.0 full speed (12Mbps) and low speed (1.5Mbps) device compliant

z32 Endpoints with full configuration flexibility

Seven USARTs with IrDA support for one USART

Two two-wire interfaces with dual address match (I2C and SMBus compatible)

Three serial peripheral interfaces (SPIs)

AES and DES crypto engine

CRC-16 (CRC-CCITT) and CRC-32 (IEEE® 802.3) generator

16-bit real time counter (RTC) with separate oscillator

Two sixteen-channel, 12-bit, 2msps Analog to Digital Converters

One two-channel, 12-bit, 1msps Digital to Analog Converter

Four Analog Comparators with window compare function, and current

sources

External interrupts on all general purpose I/O pins

Programmable watchdog timer with separate on-chip ultra low power

oscillator

QTouch® library support

zCapacitive touch buttons, sliders and wheels

zSpecial microcontroller features

Power-on reset and programmable brown-out detection

Internal and external clock options with PLL and prescaler

Programmable multilevel interrupt controller

Five sleep modes

8/16-bit Atmel XMEGA A3U Microcontroller

ATxmega256A3U / ATxmega192A3U /

ATxmega128A3U / ATxmega64A3U

DATASHEET

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Programming and debug interfaces

zJTAG (IEEE 1149.1 compliant) interface, including boundary scan

zPDI (program and debug interface)

zI/O and packages

50 Programmable I/O pins

64-lead TQFP

64-pad QFN

zOperating voltage

1.6 – 3.6V

zOperating frequency

0 – 12MHz from 1.6V

0 – 32MHz from 2.7V

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

1. Ordering Information

Notes: 1. This device can also be supplied in wafer form. Please contact your local Atmel sales office for detailed ordering information.

2. Pb-free packaging, complies to the European Directive for Restriction of Hazardous Substances (RoHS directive). Also Halide free and fully Green.

Ordering code Flash (bytes)

EEPROM

(bytes)

SRAM

(bytes) Speed (MHz)

Power

supply

Package

(1)(2)(3) Temp.

ATxmega256A3U-AU 256K + 8K 4K 16K

32 1.6 - 3.6V

64A

-40°C - 85°C

ATxmega256A3U-AUR(4) 256K + 8K 4K 16K

ATxmega192A3U-AU 192K + 8K 2K 16K

ATxmega192A3U-AUR(4) 192K + 8K 2K 16K

ATxmega128A3U-AU 128K + 8K 2K 8K

ATxmega128A3U-AUR(4) 128K + 8K 2K 8K

ATxmega64A3U-AU 64K + 4K 2K 4K

ATxmega64A3U-AUR(4) 64K + 4K 2K 4K

ATxmega256A3U-MH 256K + 8K 4K 16K

64M2

ATxmega256A3U-MHR(4) 256K + 8K 4K 16K

ATxmega192A3U-MH 192K + 8K 2K 16K

ATxmega192A3U-MHR(4) 192K + 8K 2K 16K

ATxmega128A3U-MH 128K + 8K 2K 8K

ATxmega128A3U-MHR(4) 128K + 8K 2K 8K

ATxmega64A3U-MH 64K + 4K 2K 4K

ATxmega64A3U-MHR(4) 64K + 4K 2K 4K

ATxmega256A3U-AN 256K + 8K 4K 16K

32 1.6 - 3.6V

64A

-40°C - 105°C

ATxmega256A3U-ANR(4) 256K + 8K 4K 16K

ATxmega192A3U-AN 192K + 8K 2K 16K

ATxmega192A3U-ANR(4) 192K + 8K 2K 16K

ATxmega128A3U-AN 128K + 8K 2K 8K

ATxmega128A3U-ANR(4) 128K + 8K 2K 8K

ATxmega64A3U-AN 64K + 4K 2K 4K

ATxmega64A3U-ANR(4) 64K + 4K 2K 4K

ATxmega256A3U-MN 256K + 8K 4K 16K

64M2

ATxmega256A3U-MNR(4) 256K + 8K 4K 16K

ATxmega192A3U-MN 192K + 8K 2K 16K

ATxmega192A3U-MHR(4) 192K + 8K 2K 16K

ATxmega128A3U-MN 128K + 8K 2K 8K

ATxmega128A3U-MNR(4) 128K + 8K 2K 8K

ATxmega64A3U-MN 64K + 4K 2K 4K

ATxmega64A3U-MNR(4) 64K + 4K 2K 4K

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

3. For packaging information, see “Packaging information” on page 71.

4. Tape and Reel.

Typical Applications

Package Type

64A 64-lead, 14 x 14mm body size, 1.0mm body thickness, 0.8mm lead pitch, thin profile plastic quad flat package (TQFP)

64M2 64-pad, 9 x 9 x 1.0mm body, lead pitch 0.50mm, 7.65mm exposed pad, quad flat no-lead package (QFN)

Industrial control Climate control Low power battery applications

Factory automation RF and ZigBee®Power tools

Building control USB connectivity HVAC

Board control Sensor control Utility metering

White goods Optical Medical applications

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

2. Pinout/Block Diagram

Figure 2-1. Block diagram and pinout.

Note: 1. For full details on pinout and alternate pin functions refer to “Pinout and Pin Functions” on page 59.

VCC

GND

VCC

AVCC

GND

PB0

PB1

PB3

PB2

PB7

PB5

PB4

PB6

PA7

PA6

PA0

PA1

PA2

PA3

PA4

PA5

RESET/PDI

PDI

PR0

PR1

VCC

GND

PC0

PC1

PC2

PC3

PC4

PC5

PC6

PC7

PD0

PD1

PD2

PD3

PD4

PD5

PD6

PD7

VCC

GND

PE0

PE1

PE2

PE3

PE4

PE5

PE6

PE7

PF0

PF1

PF2

PF3

PF4

PF5

PF6

PF7

VCC

GND

Digital function

Analog function / Oscillators

Programming, debug, test

External clock / Crystal pins

General Purpose I /O

Ground

Power

Supervision

Port A

EVENT ROUTING NETWORK

DMA

Controller

BUS

matrix

SRAMFLASH

ADC

AC0:1

OCD

Port EPort D

Prog/Debug

Interface

EEPROM

Port C

TC0:1

Event System

Controller

Watchdog

Timer

Internal

oscillators

OSC/CLK

Control

Real Time

Counter

Interrupt

Controller

DATA BUS

Port R

USART0:1

TWI

SPI

TC0:1

USART0:1

SPI

TC0:1

USART0:1

TWI

Port B

ADC

DAC

AC0:1

AREF

JTAG

AREF

Sleep

Controller

Reset

Controller

Internal

references

IRCOM

USB

Port F

TC0:1

USART0

CPU

SPI

XOSC

TOSC

Crypto /

CRC

Watchdog

oscillator

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

3. Overview

The Atmel AVR XMEGA is a family of low power, high performance, and peripheral rich 8/16-bit microcontrollers

based on the AVR enhanced RISC architecture. By executing instructions in a single clock cycle, the AVR

XMEGA device achieves throughputs CPU approaching one million instructions per second (MIPS) per

megahertz, allowing the system designer to optimize power consumption versus processing speed.

The AVR CPU combines a rich instruction set with 32 general purpose working registers. All 32 registers are

directly connected to the arithmetic logic unit (ALU), allowing two independent registers to be accessed in a

single instruction, executed in one clock cycle. The resulting architecture is more code efficient while achieving

throughputs many times faster than conventional single-accumulator or CISC based microcontrollers.

The AVR XMEGA A3U devices provide the following features: in-system programmable flash with read-while-

write capabilities; internal EEPROM and SRAM; four-channel DMA controller, eight-channel event system and

programmable multilevel interrupt controller, 50 general purpose I/O lines, 16-bit real-time counter (RTC); seven

flexible, 16-bit timer/counters with compare and PWM channels; seven USARTs; two two-wire serial interfaces

(TWIs); one full speed USB 2.0 interface; three serial peripheral interfaces (SPIs); AES and DES cryptographic

engine; two 16-channel, 12-bit ADCs with programmable gain; one 2-channel 12-bit DAC; four analog

comparators (ACs) with window mode; programmable watchdog timer with separate internal oscillator; accurate

internal oscillators with PLL and prescaler; and programmable brown-out detection.

The program and debug interface (PDI), a fast, two-pin interface for programming and debugging, is available.

The devices also have an IEEE std. 1149.1 compliant JTAG interface, and this can also be used for boundary

scan, on-chip debug and programming.

The ATx devices have five software selectable power saving modes. The idle mode stops the CPU while

allowing the SRAM, DMA controller, event system, interrupt controller, and all peripherals to continue

functioning. The power-down mode saves the SRAM and register contents, but stops the oscillators, disabling

all other functions until the next TWI, USB resume, or pin-change interrupt, or reset. In power-save mode, the

asynchronous real-time counter continues to run, allowing the application to maintain a timer base while the rest

of the device is sleeping. In standby mode, the external crystal oscillator keeps running while the rest of the

device is sleeping. This allows very fast startup from the external crystal, combined with low power

consumption. In extended standby mode, both the main oscillator and the asynchronous timer continue to run.

To further reduce power consumption, the peripheral clock to each individual peripheral can optionally be

stopped in active mode and idle sleep mode.

Atmel offers a free QTouch library for embedding capacitive touch buttons, sliders and wheels functionality into

AVR microcontrollers.

The devices are manufactured using Atmel high-density, nonvolatile memory technology. The program flash

memory can be reprogrammed in-system through the PDI or JTAG interfaces. A boot loader running in the

device can use any interface to download the application program to the flash memory. The boot loader

software in the boot flash section will continue to run while the application flash section is updated, providing

true read-while-write operation. By combining an 8/16-bit RISC CPU with in-system, self-programmable flash,

the AVR XMEGA is a powerful microcontroller family that provides a highly flexible and cost effective solution for

many embedded applications.

All Atmel AVR XMEGA devices are supported with a full suite of program and system development tools,

including C compilers, macro assemblers, program debugger/simulators, programmers, and evaluation kits.

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

3.1 Block Diagram

Figure 3-1. XMEGA A3U block diagram.

Power

Supervision

POR/BOD &

RESET

PORT A (8)

PORT B (8)

DMA

Controller

SRAM

ADCA

ACA

DACB

ADCB

ACB

OCD

PDI

PA[0..7]

PB[0..7]/

JTAG

Watchdog

Timer

Watchdog

Oscillator

Interrupt

Controller

DATA BUS

Prog/Debug

Controller

VCC

GND

Oscillator

Circuits/

Clock

Generation

Oscillator

Control

Real Time

Counter

Event System

Controller

JTAG

AREFA

AREFB

PDI_DATA

RESET/

PDI_CLK

PORT B

Sleep

Controller

DES

CRC

PORT C (8)

PC[0..7]

TCC0:1

USARTC0:1

TWIC

SPIC

PD[0..7] PE[0..7]

PORT D (8)

TCD0:1

USARTD0:1

SPID

TCE0:1

USARTE0:1

TWIE

SPIE

PORT E (8)

AES

USB

PORT R (2)

XTAL1

XTAL2

PR[0..1]

DATA BUS

NVM Controller

MORPEEhsalF

IRCOM

BUS Matrix

CPU

TOSC1

TOSC2

TCF0

USARTF0

PF[0..7]

PORT F (8)

EVENT ROUTING NETWORK

To Clock

Generator

Int. Refs.

Tempref

Digital function

Analog function

Programming, debug, test

Oscillator/Crystal/Clock

General Purpose I/O

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

4. Resources

A comprehensive set of development tools, application notes and datasheets are available for download on

http://www.atmel.com/avr.

4.1 Recommended reading

zAtmel AVR XMEGA AU manual

zXMEGA application notes

This device data sheet only contains part specific information with a short description of each peripheral and

module. The XMEGA AU manual describes the modules and peripherals in depth. The XMEGA application

notes contain example code and show applied use of the modules and peripherals.

All documentations are available from www.atmel.com/avr.

5. Capacitive touch sensing

The Atmel QTouch library provides a simple to use solution to realize touch sensitive interfaces on most Atmel

AVR microcontrollers. The patented charge-transfer signal acquisition offers robust sensing and includes fully

debounced reporting of touch keys and includes Adjacent Key Suppression® (AKS®) technology for

unambiguous detection of key events. The QTouch library includes support for the QTouch and QMatrix

acquisition methods.

Touch sensing can be added to any application by linking the appropriate Atmel QTouch library for the AVR

microcontroller. This is done by using a simple set of APIs to define the touch channels and sensors, and then

calling the touch sensing APIs to retrieve the channel information and determine the touch sensor states.

The QTouch library is FREE and downloadable from the Atmel website at the following location:

www.atmel.com/qtouchlibrary. For implementation details and other information, refer to the QTouch library

user guide - also available for download from the Atmel website.

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

6. AVR CPU

6.1 Features

z8/16-bit, high-performance Atmel AVR RISC CPU

142 instructions

Hardware multiplier

z32x8-bit registers directly connected to the ALU

zStack in RAM

zStack pointer accessible in I/O memory space

zDirect addressing of up to 16MB of program memory and 16MB of data memory

zTrue 16/24-bit access to 16/24-bit I/O registers

zEfficient support for 8-, 16-, and 32-bit arithmetic

zConfiguration change protection of system-critical features

6.2 Overview

All Atmel AVR XMEGA devices use the 8/16-bit AVR CPU. The main function of the CPU is to execute the code

and perform all calculations. The CPU is able to access memories, perform calculations, control peripherals,

and execute the program in the flash memory. Interrupt handling is described in a separate section, refer to

“Interrupts and Programmable Multilevel Interrupt Controller” on page 30.

6.3 Architectural Overview

In order to maximize performance and parallelism, the AVR CPU uses a Harvard architecture with separate

memories and buses for program and data. Instructions in the program memory are executed with single-level

pipelining. While one instruction is being executed, the next instruction is pre-fetched from the program memory.

This enables instructions to be executed on every clock cycle. For details of all AVR instructions, refer to

http://www.atmel.com/avr.

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Figure 6-1. Block diagram of the AVR CPU architecture.

The arithmetic logic unit (ALU) supports arithmetic and logic operations between registers or between a

constant and a register. Single-register operations can also be executed in the ALU. After an arithmetic

operation, the status register is updated to reflect information about the result of the operation.

The ALU is directly connected to the fast-access register file. The 32 x 8-bit general purpose working registers

all have single clock cycle access time allowing single-cycle arithmetic logic unit (ALU) operation between

registers or between a register and an immediate. Six of the 32 registers can be used as three 16-bit address

pointers for program and data space addressing, enabling efficient address calculations.

The memory spaces are linear. The data memory space and the program memory space are two different

memory spaces.

The data memory space is divided into I/O registers, SRAM, and external RAM. In addition, the EEPROM can

be memory mapped in the data memory.

All I/O status and control registers reside in the lowest 4KB addresses of the data memory. This is referred to as

the I/O memory space. The lowest 64 addresses can be accessed directly, or as the data space locations from

0x00 to 0x3F. The rest is the extended I/O memory space, ranging from 0x0040 to 0x0FFF. I/O registers here

must be accessed as data space locations using load (LD/LDS/LDD) and store (ST/STS/STD) instructions.

The SRAM holds data. Code execution from SRAM is not supported. It can easily be accessed through the five

different addressing modes supported in the AVR architecture. The first SRAM address is 0x2000.

Data addresses 0x1000 to 0x1FFF are reserved for memory mapping of EEPROM.

The program memory is divided in two sections, the application program section and the boot program section.

Both sections have dedicated lock bits for write and read/write protection. The SPM instruction that is used for

self-programming of the application flash memory must reside in the boot program section. The application

section contains an application table section with separate lock bits for write and read/write protection. The

application table section can be used for safe storing of nonvolatile data in the program memory.

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

6.4 ALU - Arithmetic Logic Unit

The arithmetic logic unit (ALU) supports arithmetic and logic operations between registers or between a

constant and a register. Single-register operations can also be executed. The ALU operates in direct connection

with all 32 general purpose registers. In a single clock cycle, arithmetic operations between general purpose

registers or between a register and an immediate are executed and the result is stored in the register file. After

an arithmetic or logic operation, the status register is updated to reflect information about the result of the

operation.

ALU operations are divided into three main categories – arithmetic, logical, and bit functions. Both 8- and 16-bit

arithmetic is supported, and the instruction set allows for efficient implementation of 32-bit aritmetic. The

hardware multiplier supports signed and unsigned multiplication and fractional format.

6.4.1 Hardware Multiplier

The multiplier is capable of multiplying two 8-bit numbers into a 16-bit result. The hardware multiplier supports

different variations of signed and unsigned integer and fractional numbers:

zMultiplication of unsigned integers

zMultiplication of signed integers

zMultiplication of a signed integer with an unsigned integer

zMultiplication of unsigned fractional numbers

zMultiplication of signed fractional numbers

zMultiplication of a signed fractional number with an unsigned one

A multiplication takes two CPU clock cycles.

6.5 Program Flow

After reset, the CPU starts to execute instructions from the lowest address in the flash programmemory ‘0.’ The

program counter (PC) addresses the next instruction to be fetched.

Program flow is provided by conditional and unconditional jump and call instructions capable of addressing the

whole address space directly. Most AVR instructions use a 16-bit word format, while a limited number use a 32-

bit format.

During interrupts and subroutine calls, the return address PC is stored on the stack. The stack is allocated in the

general data SRAM, and consequently the stack size is only limited by the total SRAM size and the usage of the

SRAM. After reset, the stack pointer (SP) points to the highest address in the internal SRAM. The SP is

read/write accessible in the I/O memory space, enabling easy implementation of multiple stacks or stack areas.

The data SRAM can easily be accessed through the five different addressing modes supported in the AVR

CPU.

6.6 Status Register

The status register (SREG) contains information about the result of the most recently executed arithmetic or

logic instruction. This information can be used for altering program flow in order to perform conditional

operations. Note that the status register is updated after all ALU operations, as specified in the instruction set

reference. This will in many cases remove the need for using the dedicated compare instructions, resulting in

faster and more compact code.

The status register is not automatically stored when entering an interrupt routine nor restored when returning

from an interrupt. This must be handled by software.

The status register is accessible in the I/O memory space.

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

6.7 Stack and Stack Pointer

The stack is used for storing return addresses after interrupts and subroutine calls. It can also be used for

storing temporary data. The stack pointer (SP) register always points to the top of the stack. It is implemented

as two 8-bit registers that are accessible in the I/O memory space. Data are pushed and popped from the stack

using the PUSH and POP instructions. The stack grows from a higher memory location to a lower memory

location. This implies that pushing data onto the stack decreases the SP, and popping data off the stack

increases the SP. The SP is automatically loaded after reset, and the initial value is the highest address of the

internal SRAM. If the SP is changed, it must be set to point above address 0x2000, and it must be defined

before any subroutine calls are executed or before interrupts are enabled.

During interrupts or subroutine calls, the return address is automatically pushed on the stack. The return

address can be two or three bytes, depending on program memory size of the device. For devices with 128KB

or less of program memory, the return address is two bytes, and hence the stack pointer is

decremented/incremented by two. For devices with more than 128KB of program memory, the return address is

three bytes, and hence the SP is decremented/incremented by three. The return address is popped off the stack

when returning from interrupts using the RETI instruction, and from subroutine calls using the RET instruction.

The SP is decremented by one when data are pushed on the stack with the PUSH instruction, and incremented

by one when data is popped off the stack using the POP instruction.

To prevent corruption when updating the stack pointer from software, a write to SPL will automatically disable

interrupts for up to four instructions or until the next I/O memory write.

After reset the stack pointer is initialized to the highest address of the SRAM. See Figure 7-3 on page 16.

6.8 Register File

The register file consists of 32 x 8-bit general purpose working registers with single clock cycle access time. The

zOne 8-bit output operand and one 8-bit result input

zTwo 8-bit output operands and one 8-bit result input

zTwo 8-bit output operands and one 16-bit result input

zOne 16-bit output operand and one 16-bit result input

Six of the 32 registers can be used as three 16-bit address register pointers for data space addressing, enabling

efficient address calculations. One of these address pointers can also be used as an address pointer for lookup

tables in flash program memory.

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

7. Memories

7.1 Features

zFlash program memory

One linear address space

In-system programmable

Self-programming and boot loader support

Application section for application code

Application table section for application code or data storage

Boot section for application code or boot loader code

Separate read/write protection lock bits for all sections

Built in fast CRC check of a selectable flash program memory section

zData memory

One linear address space

Single-cycle access from CPU

SRAM

EEPROM

zByte and page accessible

zOptional memory mapping for direct load and store

I/O memory

zConfiguration and status registers for all peripherals and modules

z16 bit-accessible general purpose registers for global variables or flags

Bus arbitration

zDeterministic priority handling between CPU, DMA controller, and other bus masters

Separate buses for SRAM, EEPROM and I/O memory

zSimultaneous bus access for CPU and DMA controller

zProduction signature row memory for factory programmed data

ID for each microcontroller device type

Serial number for each device

Calibration bytes for factory calibrated peripherals

zUser signature row

One flash page in size

Can be read and written from software

Content is kept after chip erase

7.2 Overview

The Atmel AVR architecture has two main memory spaces, the program memory and the data memory.

Executable code can reside only in the program memory, while data can be stored in the program memory and

the data memory. The data memory includes the internal SRAM, and EEPROM for nonvolatile data storage. All

memory spaces are linear and require no memory bank switching. Nonvolatile memory (NVM) spaces can be

locked for further write and read/write operations. This prevents unrestricted access to the application software.

A separate memory section contains the fuse bytes. These are used for configuring important system functions,

and can only be written by an external programmer.

The available memory size configurations are shown in “Ordering Information” on page 3. In addition, each

device has a Flash memory signature row for calibration data, device identification, serial number etc.

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

7.3 Flash Program Memory

The Atmel AVR XMEGA devices contain on-chip, in-system reprogrammable flash memory for program

storage. The flash memory can be accessed for read and write from an external programmer through the PDI or

from application software running in the device.

All AVR CPU instructions are 16 or 32 bits wide, and each flash location is 16 bits wide. The flash memory is

organized in two main sections, the application section and the boot loader section. The sizes of the different

sections are fixed, but device-dependent. These two sections have separate lock bits, and can have different

levels of protection. The store program memory (SPM) instruction, which is used to write to the flash from the

application software, will only operate when executed from the boot loader section.

The application section contains an application table section with separate lock settings. This enables safe

storage of nonvolatile data in the program memory.

Table 7-1. Flash Program Memory (Hexadecimal address).

7.3.1 Application Section

The Application section is the section of the flash that is used for storing the executable application code. The

protection level for the application section can be selected by the boot lock bits for this section. The application

section can not store any boot loader code since the SPM instruction cannot be executed from the application

section.

7.3.2 Application Table Section

The application table section is a part of the application section of the flash memory that can be used for storing

data. The size is identical to the boot loader section. The protection level for the application table section can be

selected by the boot lock bits for this section. The possibilities for different protection levels on the application

section and the application table section enable safe parameter storage in the program memory. If this section

is not used for data, application code can reside here.

7.3.3 Boot Loader Section

While the application section is used for storing the application code, the boot loader software must be located

in the boot loader section because the SPM instruction can only initiate programming when executing from this

section. The SPM instruction can access the entire flash, including the boot loader section itself. The protection

level for the boot loader section can be selected by the boot loader lock bits. If this section is not used for boot

loader software, application code can be stored here.

Word Address

ATxmega256A3U ATxmega192A3U ATxmega128A3U ATxmega64A3U

0000

Application Section

(256K/192K/128K/64K)

...

1EFFF / 16FFF / 37FF / 77FF

1F000 / 17000 / EFFF / 7800 Application Table Section

(8K/8K/8K/4K)

1FFFF / 17FFF / F000 / 7FFF

20000 / 18000 / 10000 / 8000 Boot Section

(8K/8K/8K/4K)

20FFF/ 18FFF/ 10FFF/ 87FF

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7.3.4 Production Signature Row

The production signature row is a separate memory section for factory programmed data. It contains calibration

data for functions such as oscillators and analog modules. Some of the calibration values will be automatically

loaded to the corresponding module or peripheral unit during reset. Other values must be loaded from the

signature row and written to the corresponding peripheral registers from software. For details on calibration

conditions, refer to “Electrical Characteristics” on page 73.

The production signature row also contains an ID that identifies each microcontroller device type and a serial

number for each manufactured device. The serial number consists of the production lot number, wafer number,

and wafer coordinates for the device. The device ID for the available devices is shown in Table 7-2.

The production signature row cannot be written or erased, but it can be read from application software and

external programmers.

Table 7-2. Device ID bytes for Atmel AVR XMEGA A3U devices.

7.3.5 User Signature Row

The user signature row is a separate memory section that is fully accessible (read and write) from application

software and external programmers. It is one flash page in size, and is meant for static user parameter storage,

such as calibration data, custom serial number, identification numbers, random number seeds, etc. This section

is not erased by chip erase commands that erase the flash, and requires a dedicated erase command. This

ensures parameter storage during multiple program/erase operations and on-chip debug sessions.

7.4 Fuses and Lock bits

The fuses are used to configure important system functions, and can only be written from an external

programmer. The application software can read the fuses. The fuses are used to configure reset sources such

as brownout detector and watchdog, startup configuration, JTAG enable, and JTAG user ID.

The lock bits are used to set protection levels for the different flash sections (that is, if read and/or write access

should be blocked). Lock bits can be written by external programmers and application software, but only to

stricter protection levels. Chip erase is the only way to erase the lock bits. To ensure that flash contents are

protected even during chip erase, the lock bits are erased after the rest of the flash memory has been erased.

An unprogrammed fuse or lock bit will have the value one, while a programmed fuse or lock bit will have the

value zero.

Both fuses and lock bits are reprogrammable like the flash program memory.

7.5 Data Memory

The data memory contains the I/O memory, internal SRAM, optionally memory mapped EEPROM, and external

memory if available. The data memory is organized as one continuous memory section, see Table 7-3 on page

16. To simplify development, I/O Memory, EEPROM and SRAM will always have the same start addresses for

all Atmel AVR XMEGA devices.

Device Device ID bytes

Byte 2 Byte 1 Byte 0

ATxmega64A3U 42 96 1E

ATxmega128A3U 42 97 1E

ATxmega192A3U 44 97 1E

ATxmega256A3U 42 98 1E

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Table 7-3. Data memory map (Hexadecimal address).

7.6 EEPROM

XMEGA AU devices have EEPROM for nonvolatile data storage. It is either addressable in a separate data

space (default) or memory mapped and accessed in normal data space. The EEPROM supports both byte and

page access. Memory mapped EEPROM allows highly efficient EEPROM reading and EEPROM buffer loading.

When doing this, EEPROM is accessible using load and store instructions. Memory mapped EEPROM will

always start at hexadecimal address 0x1000.

7.7 I/O Memory

The status and configuration registers for peripherals and modules, including the CPU, are addressable through

I/O memory locations. All I/O locations can be accessed by the load (LD/LDS/LDD) and store (ST/STS/STD)

instructions, which are used to transfer data between the 32 registers in the register file and the I/O memory.

The IN and OUT instructions can address I/O memory locations in the range of 0x00 to 0x3F directly. In the

address range 0x00 - 0x1F, single-cycle instructions for manipulation and checking of individual bits are

available.

The I/O memory address for all peripherals and modules in XMEGA A3U is shown in the “Peripheral Module

Address Map” on page 64.

7.7.1 General Purpose I/O Registers

The lowest 16 I/O memory addresses are reserved as general purpose I/O registers. These registers can be

used for storing global variables and flags, as they are directly bit-accessible using the SBI, CBI, SBIS, and

SBIC instructions.

Byte Address ATxmega192A3U Byte Address ATxmega128A3U Byte Address ATxmega64A3U

I/O Registers (4K)

FFF FFF FFF

1000

EEPROM (2K)

1000

EEPROM (2K)

1000

EEPROM (2K)

17FF 17FF 17FF

RESERVED RESERVED RESERVED

2000 Internal

SRAM (16K)

2000

Internal SRAM (8K)

2000

Internal SRAM (4K)

5FFF 3FFF 2FFF

Byte Address ATxmega256A3U

I/O Registers (4K)

FFF

1000

EEPROM (4K)

13FF

RESERVED

2000 Internal

SRAM (16K)

27FF

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7.8 Data Memory and Bus Arbitration

Since the data memory is organized as four separate sets of memories, the different bus masters (CPU, DMA

controller read and DMA controller write, etc.) can access different memory sections at the same time.

7.9 Memory Timing

Read and write access to the I/O memory takes one CPU clock cycle. A write to SRAM takes one cycle, and a

read from SRAM takes two cycles. For burst read (DMA), new data are available every cycle. EEPROM page

load (write) takes one cycle, and three cycles are required for read. For burst read, new data are available every

second cycle. Refer to the instruction summary for more details on instructions and instruction timing.

7.10 Device ID and Revision

Each device has a three-byte device ID. This ID identifies Atmel as the manufacturer of the device and the

device type. A separate register contains the revision number of the device.

7.11 JTAG Disable

It is possible to disable the JTAG interface from the application software. This will prevent all external JTAG

access to the device until the next device reset or until JTAG is enabled again from the application software. As

long as JTAG is disabled, the I/O pins required for JTAG can be used as normal I/O pins.

7.12 I/O Memory Protection

Some features in the device are regarded as critical for safety in some applications. Due to this, it is possible to

lock the I/O register related to the clock system, the event system, and the advanced waveform extensions. As

long as the lock is enabled, all related I/O registers are locked and they can not be written from the application

software. The lock registers themselves are protected by the configuration change protection mechanism.

7.13 Flash and EEPROM Page Size

The flash program memory and EEPROM data memory are organized in pages. The pages are word accessible

for the flash and byte accessible for the EEPROM.

Table 7-4 on page 17 shows the Flash Program Memory organization and Program Counter (PC) size. Flash

write and erase operations are performed on one page at a time, while reading the Flash is done one byte at a

time. For Flash access the Z-pointer (Z[m:n]) is used for addressing. The most significant bits in the address

(FPAGE) give the page number and the least significant address bits (FWORD) give the word in the page.

Table 7-4. Number of words and pages in the flash.

Table 7-5 on page 18 shows EEPROM memory organization for the Atmel AVR XMEGA A3U devices.

EEEPROM write and erase operations can be performed one page or one byte at a time, while reading the

EEPROM is done one byte at a time. For EEPROM access the NVM address register (ADDR[m:n]) is used for

Devices PC size Flash size Page Size FWORD FPAGE Application Boot

bits bytes words Size No of

pages Size No of

pages

ATxmega64A3U 16 64K + 4K 128 Z[7:1] Z[16:8] 64K 256 4K 16

ATxmega128A3U 17 128K + 8K 256 Z[8:1] Z[17:9] 128K 256 8K 16

ATxmega192A3U 17 192K + 8K 256 Z[8:1] Z[17:9] 192K 384 8K 16

ATxmega256A3U 18 256K + 8K 256 Z[8:1] Z[18:9] 256K 512 8K 16

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addressing. The most significant bits in the address (E2PAGE) give the page number and the least significant

address bits (E2BYTE) give the byte in the page.

Table 7-5. Number of bytes and pages in the EEPROM.

Devices EEPROM Page Size E2BYTE E2PAGE No of Pages

Size bytes

ATxmega64A3U 2K 32 ADDR[4:0] ADDR[10:5] 64

ATxmega128A3U 2K 32 ADDR[4:0] ADDR[10:5] 64

ATxmega192A3U 2K 32 ADDR[4:0] ADDR[10:5] 64

ATxmega256A3U 4K 32 ADDR[4:0] ADDR[11:5] 128

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8. DMAC – Direct Memory Access Controller

8.1 Features

zAllows high speed data transfers with minimal CPU intervention

from data memory to data memory

from data memory to peripheral

from peripheral to data memory

from peripheral to peripheral

zFour DMA channels with separate

transfer triggers

interrupt vectors

addressing modes

zProgrammable channel priority

zFrom 1 byte to 16MB of data in a single transaction

Up to 64KB block transfers with repeat

1, 2, 4, or 8 byte burst transfers

zMultiple addressing modes

Static

Incremental

Decremental

zOptional reload of source and destination addresses at the end of each

Burst

Block

Transaction

zOptional interrupt on end of transaction

zOptional connection to CRC generator for CRC on DMA data

8.2 Overview

The four-channel direct memory access (DMA) controller can transfer data between memories and peripherals,

and thus offload these tasks from the CPU. It enables high data transfer rates with minimum CPU intervention,

and frees up CPU time. The four DMA channels enable up to four independent and parallel transfers.

The DMA controller can move data between SRAM and peripherals, between SRAM locations and directly

between peripheral registers. With access to all peripherals, the DMA controller can handle automatic transfer

of data to/from communication modules. The DMA controller can also read from memory mapped EEPROM.

Data transfers are done in continuous bursts of 1, 2, 4, or 8 bytes. They build block transfers of configurable size

from 1 byte to 64KB. A repeat counter can be used to repeat each block transfer for single transactions up to

16MB. Source and destination addressing can be static, incremental or decremental. Automatic reload of

source and/or destination addresses can be done after each burst or block transfer, or when a transaction is

complete. Application software, peripherals, and events can trigger DMA transfers.

The four DMA channels have individual configuration and control settings. This include source, destination,

transfer triggers, and transaction sizes. They have individual interrupt settings. Interrupt requests can be

generated when a transaction is complete or when the DMA controller detects an error on a DMA channel.

To allow for continuous transfers, two channels can be interlinked so that the second takes over the transfer

when the first is finished, and vice versa.

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9. Event System

9.1 Features

zSystem for direct peripheral-to-peripheral communication and signaling

zPeripherals can directly send, receive, and react to peripheral events

CPU and DMA controller independent operation

100% predictable signal timing

Short and guaranteed response time

zEight event channels for up to eight different and parallel signal routing configurations

zEvents can be sent and/or used by most peripherals, clock system, and software

zAdditional functions include

Quadrature decoders

Digital filtering of I/O pin state

zWorks in active mode and idle sleep mode

9.2 Overview

The event system enables direct peripheral-to-peripheral communication and signaling. It allows a change in

one peripheral’s state to automatically trigger actions in other peripherals. It is designed to provide a predictable

system for short and predictable response times between peripherals. It allows for autonomous peripheral

control and interaction without the use of interrupts, CPU, or DMA controller resources, and is thus a powerful

tool for reducing the complexity, size and execution time of application code. It also allows for synchronized

timing of actions in several peripheral modules.

A change in a peripheral’s state is referred to as an event, and usually corresponds to the peripheral’s interrupt

conditions. Events can be directly passed to other peripherals using a dedicated routing network called the

event routing network. How events are routed and used by the peripherals is configured in software.

Figure 9-1 on page 21 shows a basic diagram of all connected peripherals. The event system can directly

connect together analog and digital converters, analog comparators, I/O port pins, the real-time counter,

timer/counters, IR communication module (IRCOM), and USB interface. It can also be used to trigger DMA

transactions (DMA controller). Events can also be generated from software and the peripheral clock.

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Figure 9-1. Event system overview and connected peripherals.

The event routing network consists of eight software-configurable multiplexers that control how events are

routed and used. These are called event channels, and allow for up to eight parallel event routing

configurations. The maximum routing latency is two peripheral clock cycles. The event system works in both

active mode and idle sleep mode.

DAC

Timer /

Counters

USB

ADC

Real Time

Counter

Port pins

CPU /

Software

DMA

Controller

IRCOM

Event Routing Network

Event

System

Controller

clkPER

Prescaler

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10. System Clock and Clock options

10.1 Features

zFast start-up time

zSafe run-time clock switching

zInternal oscillators:

32MHz run-time calibrated and tuneable oscillator

2MHz run-time calibrated oscillator

32.768kHz calibrated oscillator

32kHz ultra low power (ULP) oscillator with 1kHz output

zExternal clock options

0.4MHz - 16MHz crystal oscillator

32.768kHz crystal oscillator

External clock

zPLL with 20MHz - 128MHz output frequency

Internal and external clock options and 1x to 31x multiplication

Lock detector

zClock prescalers with 1x to 2048x division

zFast peripheral clocks running at two and four times the CPU clock

zAutomatic run-time calibration of internal oscillators

zExternal oscillator and PLL lock failure detection with optional non-maskable interrupt

10.2 Overview

Atmel AVR XMEGA A3U devices have a flexible clock system supporting a large number of clock sources. It

incorporates both accurate internal oscillators and external crystal oscillator and resonator support. A high-

frequency phase locked loop (PLL) and clock prescalers can be used to generate a wide range of clock

frequencies. A calibration feature (DFLL) is available, and can be used for automatic run-time calibration of the

internal oscillators to remove frequency drift over voltage and temperature. An oscillator failure monitor can be

enabled to issue a non-maskable interrupt and switch to the internal oscillator if the external oscillator or PLL

fails.

When a reset occurs, all clock sources except the 32kHz ultra low power oscillator are disabled. After reset, the

device will always start up running from the 2MHz internal oscillator. During normal operation, the system clock

source and prescalers can be changed from software at any time.

Figure 10-1 on page 23 presents the principal clock system in the XMEGA A3U family of devices. Not all of the

clocks need to be active at a given time. The clocks for the CPU and peripherals can be stopped using sleep

modes and power reduction registers, as described in “Power Management and Sleep Modes” on page 25.

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Figure 10-1. The clock system, clock sources and clock distribution.

10.3 Clock Sources

The clock sources are divided in two main groups: internal oscillators and external clock sources. Most of the

clock sources can be directly enabled and disabled from software, while others are automatically enabled or

disabled, depending on peripheral settings. After reset, the device starts up running from the 2MHz internal

oscillator. The other clock sources, DFLLs and PLL, are turned off by default.

The internal oscillators do not require any external components to run. For details on characteristics and

accuracy of the internal oscillators, refer to the device datasheet.

10.3.1 32kHz Ultra Low Power Internal Oscillator

This oscillator provides an approximate 32kHz clock. The 32kHz ultra low power (ULP) internal oscillator is a

very low power clock source, and it is not designed for high accuracy. The oscillator employs a built-in prescaler

Real Time

Counter Peripherals RAM AVR CPU Non-Volatile

Memory

Watchdog

Timer

Brown-out

Detector

System Clock Prescalers

USB

Prescaler

System Clock Multiplexer

(SCLKSEL)

PLLSRC

RTCSRC

DIV32

32kHz

Int. ULP

32.768kHz

Int. OSC

32.768kHz

TOSC

2MHz

Int. Osc

32MHz

Int. Osc

0.4 – 16MHz

XTAL

DIV32

DIV4

XOSCSEL

PLL

USBSRC

TOSC1

TOSC2

XTAL1

XTAL2

clk

SYS

clk

RTC

clk

PER2

clk

PER

clk

CPU

clk

PER4

clk

USB

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that provides a 1kHz output. The oscillator is automatically enabled/disabled when it is used as clock source for

any part of the device. This oscillator can be selected as the clock source for the RTC.

10.3.2 32.768kHz Calibrated Internal Oscillator

This oscillator provides an approximate 32.768kHz clock. It is calibrated during production to provide a default

frequency close to its nominal frequency. The calibration register can also be written from software for run-time

calibration of the oscillator frequency. The oscillator employs a built-in prescaler, which provides both a

32.768kHz output and a 1.024kHz output.

10.3.3 32.768kHz Crystal Oscillator

A 32.768kHz crystal oscillator can be connected between the TOSC1 and TOSC2 pins and enables a dedicated

low frequency oscillator input circuit. A low power mode with reduced voltage swing on TOSC2 is available. This

oscillator can be used as a clock source for the system clock and RTC, and as the DFLL reference clock.

10.3.4 0.4 - 16MHz Crystal Oscillator

This oscillator can operate in four different modes optimized for different frequency ranges, all within 0.4 -

16MHz.

10.3.5 2MHz Run-time Calibrated Internal Oscillator

The 2MHz run-time calibrated internal oscillator is the default system clock source after reset. It is calibrated

during production to provide a default frequency close to its nominal frequency. A DFLL can be enabled for

automatic run-time calibration of the oscillator to compensate for temperature and voltage drift and optimize the

oscillator accuracy.

10.3.6 32MHz Run-time Calibrated Internal Oscillator

The 32MHz run-time calibrated internal oscillator is a high-frequency oscillator. It is calibrated during production

to provide a default frequency close to its nominal frequency. A digital frequency looked loop (DFLL) can be

enabled for automatic run-time calibration of the oscillator to compensate for temperature and voltage drift and

optimize the oscillator accuracy. This oscillator can also be adjusted and calibrated to any frequency between

30MHz and 55MHz. The production signature row contains 48MHz calibration values intended used when the

oscillator is used a full-speed USB clock source.

10.3.7 External Clock Sources

The XTAL1 and XTAL2 pins can be used to drive an external oscillator, either a quartz crystal or a ceramic

resonator. XTAL1 can be used as input for an external clock signal. The TOSC1 and TOSC2 pins is dedicated

to driving a 32.768kHz crystal oscillator.

10.3.8 PLL with 1x-31x Multiplication Factor

The built-in phase locked loop (PLL) can be used to generate a high-frequency system clock. The PLL has a

user-selectable multiplication factor of from 1 to 31. In combination with the prescalers, this gives a wide range

of output frequencies from all clock sources.

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11. Power Management and Sleep Modes

11.1 Features

zPower management for adjusting power consumption and functions

zFive sleep modes

Idle

Power down

Power save

Standby

Extended standby

zPower reduction register to disable clock and turn off unused peripherals in active and idle modes

11.2 Overview

Various sleep modes and clock gating are provided in order to tailor power consumption to application

requirements. This enables the Atmel AVR XMEGA microcontroller to stop unused modules to save power.

All sleep modes are available and can be entered from active mode. In active mode, the CPU is executing

application code. When the device enters sleep mode, program execution is stopped and interrupts or a reset is

used to wake the device again. The application code decides which sleep mode to enter and when. Interrupts

from enabled peripherals and all enabled reset sources can restore the microcontroller from sleep to active

mode.

In addition, power reduction registers provide a method to stop the clock to individual peripherals from software.

When this is done, the current state of the peripheral is frozen, and there is no power consumption from that

peripheral. This reduces the power consumption in active mode and idle sleep modes and enables much more

fine-tuned power management than sleep modes alone.

11.3 Sleep Modes

Sleep modes are used to shut down modules and clock domains in the microcontroller in order to save power.

XMEGA microcontrollers have five different sleep modes tuned to match the typical functional stages during

application execution. A dedicated sleep instruction (SLEEP) is available to enter sleep mode. Interrupts are

used to wake the device from sleep, and the available interrupt wake-up sources are dependent on the

configured sleep mode. When an enabled interrupt occurs, the device will wake up and execute the interrupt

service routine before continuing normal program execution from the first instruction after the SLEEP

instruction. If other, higher priority interrupts are pending when the wake-up occurs, their interrupt service

routines will be executed according to their priority before the interrupt service routine for the wake-up interrupt

is executed. After wake-up, the CPU is halted for four cycles before execution starts.

The content of the register file, SRAM and registers are kept during sleep. If a reset occurs during sleep, the

device will reset, start up, and execute from the reset vector.

11.3.1 Idle Mode

In idle mode the CPU and nonvolatile memory are stopped (note that any ongoing programming will be

completed), but all peripherals, including the interrupt controller, event system and DMA controller are kept

running. Any enabled interrupt will wake the device.

11.3.2 Power-down Mode

In power-down mode, all clocks, including the real-time counter clock source, are stopped. This allows operation

only of asynchronous modules that do not require a running clock. The only interrupts that can wake up the

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MCU are the two-wire interface address match interrupt, asynchronous port interrupts, and the USB resume

interrupt.

11.3.3 Power-save Mode

Power-save mode is identical to power down, with one exception. If the real-time counter (RTC) is enabled, it

will keep running during sleep, and the device can also wake up from either an RTC overflow or compare match

interrupt.

11.3.4 Standby Mode

Standby mode is identical to power down, with the exception that the enabled system clock sources are kept

running while the CPU, peripheral, and RTC clocks are stopped. This reduces the wake-up time.

11.3.5 Extended Standby Mode

Extended standby mode is identical to power-save mode, with the exception that the enabled system clock

sources are kept running while the CPU and peripheral clocks are stopped. This reduces the wake-up time.

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12. System Control and Reset

12.1 Features

zReset the microcontroller and set it to initial state when a reset source goes active

zMultiple reset sources that cover different situations

Power-on reset

External reset

Watchdog reset

Brownout reset

PDI reset

Software reset

zAsynchronous operation

No running system clock in the device is required for reset

zReset status register for reading the reset source from the application code

12.2 Overview

The reset system issues a microcontroller reset and sets the device to its initial state. This is for situations where

operation should not start or continue, such as when the microcontroller operates below its power supply rating.

If a reset source goes active, the device enters and is kept in reset until all reset sources have released their

reset. The I/O pins are immediately tri-stated. The program counter is set to the reset vector location, and all I/O

registers are set to their initial values. The SRAM content is kept. However, if the device accesses the SRAM

when a reset occurs, the content of the accessed location can not be guaranteed.

After reset is released from all reset sources, the default oscillator is started and calibrated before the device

starts running from the reset vector address. By default, this is the lowest program memory address, 0, but it is

possible to move the reset vector to the lowest address in the boot section.

The reset functionality is asynchronous, and so no running system clock is required to reset the device. The

software reset feature makes it possible to issue a controlled system reset from the user software.

The reset status register has individual status flags for each reset source. It is cleared at power-on reset, and

shows which sources have issued a reset since the last power-on.

12.3 Reset Sequence

A reset request from any reset source will immediately reset the device and keep it in reset as long as the

request is active. When all reset requests are released, the device will go through three stages before the

device starts running again:

zReset counter delay

zOscillator startup

zOscillator calibration

If another reset requests occurs during this process, the reset sequence will start over again.

12.4 Reset Sources

12.4.1 Power-on Reset

A power-on reset (POR) is generated by an on-chip detection circuit. The POR is activated when the VCC rises

and reaches the POR threshold voltage (VPOT), and this will start the reset sequence.

The POR is also activated to power down the device properly when the VCC falls and drops below the VPOT level.

The VPOT level is higher for falling VCC than for rising VCC. Consult the datasheet for POR characteristics data.

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12.4.2 Brownout Detection

The on-chip brownout detection (BOD) circuit monitors the VCC level during operation by comparing it to a fixed,

programmable level that is selected by the BODLEVEL fuses. If disabled, BOD is forced on at the lowest level

during chip erase and when the PDI is enabled.

12.4.3 External Reset

The external reset circuit is connected to the external RESET pin. The external reset will trigger when the

RESET pin is driven below the RESET pin threshold voltage, VRST, for longer than the minimum pulse period,

tEXT. The reset will be held as long as the pin is kept low. The RESET pin includes an internal pull-up resistor.

12.4.4 Watchdog Reset

The watchdog timer (WDT) is a system function for monitoring correct program operation. If the WDT is not

reset from the software within a programmable timeout period, a watchdog reset will be given. The watchdog

reset is active for one to two clock cycles of the 2MHz internal oscillator. For more details see “WDT – Watchdog

Timer” on page 29.

12.4.5 Software Reset

The software reset makes it possible to issue a system reset from software by writing to the software reset bit in

the reset control register.The reset will be issued within two CPU clock cycles after writing the bit. It is not

possible to execute any instruction from when a software reset is requested until it is issued.

12.4.6 Program and Debug Interface Reset

The program and debug interface reset contains a separate reset source that is used to reset the device during

external programming and debugging. This reset source is accessible only from external debuggers and

programmers.

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13. WDT – Watchdog Timer

13.1 Features

zIssues a device reset if the timer is not reset before its timeout period

zAsynchronous operation from dedicated oscillator

z1kHz output of the 32kHz ultra low power oscillator

z11 selectable timeout periods, from 8ms to 8s

zTwo operation modes:

Normal mode

Window mode

zConfiguration lock to prevent unwanted changes

13.2 Overview

The watchdog timer (WDT) is a system function for monitoring correct program operation. It makes it possible to

recover from error situations such as runaway or deadlocked code. The WDT is a timer, configured to a

predefined timeout period, and is constantly running when enabled. If the WDT is not reset within the timeout

period, it will issue a microcontroller reset. The WDT is reset by executing the WDR (watchdog timer reset)

instruction from the application code.

The window mode makes it possible to define a time slot or window inside the total timeout period during which

WDT must be reset. If the WDT is reset outside this window, either too early or too late, a system reset will be

issued. Compared to the normal mode, this can also catch situations where a code error causes constant WDR

execution.

The WDT will run in active mode and all sleep modes, if enabled. It is asynchronous, runs from a CPU-

independent clock source, and will continue to operate to issue a system reset even if the main clocks fail.

The configuration change protection mechanism ensures that the WDT settings cannot be changed by accident.

For increased safety, a fuse for locking the WDT settings is also available.

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14. Interrupts and Programmable Multilevel Interrupt Controller

14.1 Features

zShort and predictable interrupt response time

zSeparate interrupt configuration and vector address for each interrupt

zProgrammable multilevel interrupt controller

Interrupt prioritizing according to level and vector address

Three selectable interrupt levels for all interrupts: low, medium and high

Selectable, round-robin priority scheme within low-level interrupts

Non-maskable interrupts for critical functions

zInterrupt vectors optionally placed in the application section or the boot loader section

14.2 Overview

Interrupts signal a change of state in peripherals, and this can be used to alter program execution. Peripherals

can have one or more interrupts, and all are individually enabled and configured. When an interrupt is enabled

and configured, it will generate an interrupt request when the interrupt condition is present. The programmable

multilevel interrupt controller (PMIC) controls the handling and prioritizing of interrupt requests. When an

interrupt request is acknowledged by the PMIC, the program counter is set to point to the interrupt vector, and

the interrupt handler can be executed.

All peripherals can select between three different priority levels for their interrupts: low, medium, and high.

Interrupts are prioritized according to their level and their interrupt vector address. Medium-level interrupts will

interrupt low-level interrupt handlers. High-level interrupts will interrupt both medium- and low-level interrupt

handlers. Within each level, the interrupt priority is decided from the interrupt vector address, where the lowest

interrupt vector address has the highest interrupt priority. Low-level interrupts have an optional round-robin

scheduling scheme to ensure that all interrupts are serviced within a certain amount of time.

Non-maskable interrupts (NMI) are also supported, and can be used for system critical functions.

14.3 Interrupt vectors

The interrupt vector is the sum of the peripheral’s base interrupt address and the offset address for specific

interrupts in each peripheral. The base addresses for the Atmel AVR XMEGA A3U devices are shown in Table

14-1. Offset addresses for each interrupt available in the peripheral are described for each peripheral in the

XMEGA AU manual. For peripherals or modules that have only one interrupt, the interrupt vector is shown in

Table 14-1. The program address is the word address.

Table 14-1. Reset and interrupt vectors.

Program address

(base address) Source Interrupt description

0x000 RESET

0x002 OSCF_INT_vect Crystal oscillator failure interrupt vector (NMI)

0x004 PORTC_INT_base Port C interrupt base

0x008 PORTR_INT_base Port R interrupt base

0x00C DMA_INT_base DMA controller interrupt base

0x014 RTC_INT_base Real Time Counter Interrupt base

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0x018 TWIC_INT_base Two-Wire Interface on Port C Interrupt base

0x01C TCC0_INT_base Timer/Counter 0 on port C Interrupt base

0x028 TCC1_INT_base Timer/Counter 1 on port C Interrupt base

0x030 SPIC_INT_vect SPI on port C Interrupt vector

0x032 USARTC0_INT_base USART 0 on port C Interrupt base

0x038 USARTC1_INT_base USART 1 on port C Interrupt base

0x03E AES_INT_vect AES Interrupt vector

0x040 NVM_INT_base Non-Volatile Memory Interrupt base

0x044 PORTB_INT_base Port B Interrupt base

0x048 ACB_INT_base Analog Comparator on Port B Interrupt base

0x04E ADCB_INT_base Analog to Digital Converter on Port B Interrupt base

0x056 PORTE_INT_base Port E INT base

0x05A TWIE_INT_base Two-Wire Interface on Port E Interrupt base

0x05E TCE0_INT_base Timer/Counter 0 on port E Interrupt base

0x06A TCE1_INT_base Timer/Counter 1 on port E Interrupt base

0x072 SPIE_INT_vect SPI on port E Interrupt vector

0x074 USARTE0_INT_base USART 0 on port E Interrupt base

0x07A USARTE1_INT_base USART 1 on port E Interrupt base

0x080 PORTD_INT_base Port D Interrupt base

0x084 PORTA_INT_base Port A Interrupt base

0x088 ACA_INT_base Analog Comparator on Port A Interrupt base

0x08E ADCA_INT_base Analog to Digital Converter on Port A Interrupt base

0x09A TCD0_INT_base Timer/Counter 0 on port D Interrupt base

0x0A6 TCD1_INT_base Timer/Counter 1 on port D Interrupt base

0x0AE SPID_INT_vector SPI D Interrupt vector

0x0B0 USARTD0_INT_base USART 0 on port D Interrupt base

0x0B6 USARTD1_INT_base USART 1 on port D Interrupt base

0x0D0 PORTF_INT_base Port F Interrupt base

0x0D8 TCF0_INT_base Timer/Counter 0 on port F Interrupt base

0x0EE USARTF0_INT_base USART 0 on port F Interrupt base

0x0FA USB_INT_base USB on port D Interrupt base

Program address

(base address) Source Interrupt description

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15. I/O Ports

15.1 Features

z50 general purpose input and output pins with individual configuration

zOutput driver with configurable driver and pull settings:

Totem-pole

Wired-AND

Wired-OR

Bus-keeper

Inverted I/O

zInput with synchronous and/or asynchronous sensing with interrupts and events

Sense both edges

Sense rising edges

Sense falling edges

Sense low level

zOptional pull-up and pull-down resistor on input and Wired-OR/AND configurations

zOptional slew rate control

zAsynchronous pin change sensing that can wake the device from all sleep modes

zTwo port interrupts with pin masking per I/O port

zEfficient and safe access to port pins

Hardware read-modify-write through dedicated toggle/clear/set registers

Configuration of multiple pins in a single operation

Mapping of port registers into bit-accessible I/O memory space

zPeripheral clocks output on port pin

zReal-time counter clock output to port pin

zEvent channels can be output on port pin

zRemapping of digital peripheral pin functions

Selectable USART, SPI, and timer/counter input/output pin locations

15.2 Overview

One port consists of up to eight port pins: pin 0 to 7. Each port pin can be configured as input or output with

configurable driver and pull settings. They also implement synchronous and asynchronous input sensing with

interrupts and events for selectable pin change conditions. Asynchronous pin-change sensing means that a pin

change can wake the device from all sleep modes, included the modes where no clocks are running.

All functions are individual and configurable per pin, but several pins can be configured in a single operation.

The pins have hardware read-modify-write (RMW) functionality for safe and correct change of drive value and/or

pull resistor configuration. The direction of one port pin can be changed without unintentionally changing the

direction of any other pin.

The port pin configuration also controls input and output selection of other device functions. It is possible to have

both the peripheral clock and the real-time clock output to a port pin, and available for external use. The same

applies to events from the event system that can be used to synchronize and control external functions. Other

digital peripherals, such as USART, SPI, and timer/counters, can be remapped to selectable pin locations in

order to optimize pin-out versus application needs.

The notation of the ports are PORTA, PORTB, PORTC, PORTD, PORTE, PORTF and PORTR.

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15.3 Output Driver

All port pins (Pn) have programmable output configuration. The port pins also have configurable slew rate

limitation to reduce electromagnetic emission.

15.3.1 Push-pull

Figure 15-1. I/O configuration - Totem-pole.

15.3.2 Pull-down

Figure 15-2. I/O configuration - Totem-pole with pull-down (on input).

15.3.3 Pull-up

Figure 15-3. I/O configuration - Totem-pole with pull-up (on input).

INn

OUTn

DIRn

INn

OUTn

DIRn

INn

OUTn

DIRn

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15.3.4 Bus-keeper

The bus-keeper’s weak output produces the same logical level as the last output level. It acts as a pull-up if the

last level was ‘1’, and pull-down if the last level was ‘0’.

Figure 15-4. I/O configuration - Totem-pole with bus-keeper.

15.3.5 Others

Figure 15-5. Output configuration - Wired-OR with optional pull-down.

Figure 15-6. I/O configuration - Wired-AND with optional pull-up.

INn

OUTn

DIRn

INn

OUTn

INn

OUTn

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15.4 Input sensing

Input sensing is synchronous or asynchronous depending on the enabled clock for the ports, and the

configuration is shown in Figure 15-7.

Figure 15-7. Input sensing system overview.

When a pin is configured with inverted I/O, the pin value is inverted before the input sensing.

15.5 Alternate Port Functions

Most port pins have alternate pin functions in addition to being a general purpose I/O pin. When an alternate

function is enabled, it might override the normal port pin function or pin value. This happens when other

peripherals that require pins are enabled or configured to use pins. If and how a peripheral will override and use

pins is described in the section for that peripheral. “Pinout and Pin Functions” on page 59 shows which modules

on peripherals that enable alternate functions on a pin, and which alternate functions that are available on a pin.

NVERTED I/O

Interrupt

Control

Pxn Synchronizer

INn EDGE

DETECT

Synchronous sensing

EDGE

DETECT

Asynchronous sensing

IRQ

Synchronous

Events

Asynchronou

Events

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16. TC0/1 – 16-bit Timer/Counter Type 0 and 1

16.1 Features

zSeven 16-bit timer/counters

Four timer/counters of type 0

Three timer/counters of type 1

Split-mode enabling two 8-bit timer/counter from each timer/counter type 0

z32-bit Timer/Counter support by cascading two timer/counters

zUp to four compare or capture (CC) channels

Four CC channels for timer/counters of type 0

Two CC channels for timer/counters of type 1

zDouble buffered timer period setting

zDouble buffered capture or compare channels

zWaveform generation:

Frequency generation

Single-slope pulse width modulation

Dual-slope pulse width modulation

zInput capture:

Input capture with noise cancelling

Frequency capture

Pulse width capture

32-bit input capture

zTimer overflow and error interrupts/events

zOne compare match or input capture interrupt/event per CC channel

zCan be used with event system for:

Quadrature decoding

Count and direction control

Capture

zCan be used with DMA and to trigger DMA transactions

zHigh-resolution extension

Increases frequency and waveform resolution by 4x (2-bit) or 8x (3-bit)

zAdvanced waveform extension:

Low- and high-side output with programmable dead-time insertion (DTI)

zEvent controlled fault protection for safe disabling of drivers

16.2 Overview

Atmel AVR XMEGA devices have a set of seven flexible 16-bit Timer/Counters (TC). Their capabilities include

accurate program execution timing, frequency and waveform generation, and input capture with time and

frequency measurement of digital signals. Two timer/counters can be cascaded to create a 32-bit timer/counter

with optional 32-bit capture.

A timer/counter consists of a base counter and a set of compare or capture (CC) channels. The base counter

can be used to count clock cycles or events. It has direction control and period setting that can be used for

timing. The CC channels can be used together with the base counter to do compare match control, frequency

generation, and pulse width waveform modulation, as well as various input capture operations. A timer/counter

can be configured for either capture or compare functions, but cannot perform both at the same time.

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A timer/counter can be clocked and timed from the peripheral clock with optional prescaling or from the event

system. The event system can also be used for direction control and capture trigger or to synchronize

operations.

There are two differences between timer/counter type 0 and type 1. Timer/counter 0 has four CC channels, and

timer/counter 1 has two CC channels. All information related to CC channels 3 and 4 is valid only for

timer/counter 0. Only Timer/Counter 0 has the split mode feature that split it into two 8-bit Timer/Counters with

four compare channels each.

Some timer/counters have extensions to enable more specialized waveform and frequency generation. The

advanced waveform extension (AWeX) is intended for motor control and other power control applications. It

enables low- and high-side output with dead-time insertion, as well as fault protection for disabling and shutting

down external drivers. It can also generate a synchronized bit pattern across the port pins.

The advanced waveform extension can be enabled to provide extra and more advanced features for the

Timer/Counter. This are only available for Timer/Counter 0. See “AWeX – Advanced Waveform Extension” on

page 39 for more details.

The high-resolution (hi-res) extension can be used to increase the waveform output resolution by four or eight

times by using an internal clock source running up to four times faster than the peripheral clock. See “Hi-Res –

High Resolution Extension” on page 40 for more details.

Figure 16-1. Overview of a Timer/Counter and closely related peripherals.

PORTC, PORTD and PORTE each has one Timer/Counter 0 and one Timer/Counter1. PORTF has one

Timer/Counter 0. Notation of these are TCC0 (Time/Counter C0), TCC1, TCD0, TCD1, TCE0, TCE1 and TCF0,

respectively.

AWeX

Compare/Capture Channel D

Compare/Capture Channel C

Compare/Capture Channel B

Compare/Capture Channel A

Waveform

Generation

Buffer

Comparator

Hi-Res

Fault

Protection

Capture

Control

Base Counter

Counter

Control Logic

Timer Period

Prescaler

Dead-Time

Insertion

Pattern

Generation

clkPER4

PORT

Event

System

clkPER

Timer/Counter

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17. TC2 - Timer/Counter Type 2

17.1 Features

zEight eight-bit timer/counters

Four Low-byte timer/counter

Four High-byte timer/counter

zUp to eight compare channels in each Timer/Counter 2

Four compare channels for the low-byte timer/counter

Four compare channels for the high-byte timer/counter

zWaveform generation

Single slope pulse width modulation

zTimer underflow interrupts/events

zOne compare match interrupt/event per compare channel for the low-byte timer/counter

zCan be used with the event system for count control

zCan be used to trigger DMA transactions

17.2 Overview

There are four Timer/Counter 2. These are realized when a Timer/Counter 0 is set in split mode. It is then a

system of two eight-bit timer/counters, each with four compare channels. This results in eight configurable pulse

width modulation (PWM) channels with individually controlled duty cycles, and is intended for applications that

require a high number of PWM channels.

The two eight-bit timer/counters in this system are referred to as the low-byte timer/counter and high-byte

timer/counter, respectively. The difference between them is that only the low-byte timer/counter can be used to

generate compare match interrupts, events and DMA triggers. The two eight-bit timer/counters have a shared

clock source and separate period and compare settings. They can be clocked and timed from the peripheral

clock, with optional prescaling, or from the event system. The counters are always counting down.

PORTC, PORTD, PORTE and PORTF each has one Timer/Counter 2. Notation of these are TCC2

(Time/Counter C2), TCD2, TCE2 and TCF2, respectively.

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18. AWeX – Advanced Waveform Extension

18.1 Features

zWaveform output with complementary output from each compare channel

zFour dead-time insertion (DTI) units

8-bit resolution

Separate high and low side dead-time setting

Double buffered dead time

Optionally halts timer during dead-time insertion

zPattern generation unit creating synchronised bit pattern across the port pins

Double buffered pattern generation

Optional distribution of one compare channel output across the port pins

zEvent controlled fault protection for instant and predictable fault triggering

18.2 Overview

The advanced waveform extension (AWeX) provides extra functions to the timer/counter in waveform

generation (WG) modes. It is primarily intended for use with different types of motor control and other power

control applications. It enables low- and high side output with dead-time insertion and fault protection for

disabling and shutting down external drivers. It can also generate a synchronized bit pattern across the port

pins.

Each of the waveform generator outputs from the timer/counter 0 are split into a complimentary pair of outputs

when any AWeX features are enabled. These output pairs go through a dead-time insertion (DTI) unit that

generates the non-inverted low side (LS) and inverted high side (HS) of the WG output with dead-time insertion

between LS and HS switching. The DTI output will override the normal port value according to the port override

setting.

The pattern generation unit can be used to generate a synchronized bit pattern on the port it is connected to. In

addition, the WG output from compare channel A can be distributed to and override all the port pins. When the

pattern generator unit is enabled, the DTI unit is bypassed.

The fault protection unit is connected to the event system, enabling any event to trigger a fault condition that will

disable the AWeX output. The event system ensures predictable and instant fault reaction, and gives flexibility in

the selection of fault triggers.

The AWeX is available for TCC0. The notation of this is AWEXC.

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19. Hi-Res – High Resolution Extension

19.1 Features

zIncreases waveform generator resolution up to 8x (three bits)

zSupports frequency, single-slope PWM, and dual-slope PWM generation

zSupports the AWeX when this is used for the same timer/counter

19.2 Overview

The high-resolution (hi-res) extension can be used to increase the resolution of the waveform generation output

from a timer/counter by four or eight. It can be used for a timer/counter doing frequency, single-slope PWM, or

dual-slope PWM generation. It can also be used with the AWeX if this is used for the same timer/counter.

The hi-res extension uses the peripheral 4x clock (ClkPER4). The system clock prescalers must be configured so

the peripheral 4x clock frequency is four times higher than the peripheral and CPU clock frequency when the hi-

res extension is enabled.

There are four hi-res extensions that each can be enabled for each timer/counters pair on PORTC, PORTD,

PORTE and PORTF. The notation of these are HIRESC, HIRESD, HIRESE and HIRESF, respectively.

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20. RTC – 16-bit Real-Time Counter

20.1 Features

z16-bit resolution

zSelectable clock source

32.768kHz external crystal

External clock

32.768kHz internal oscillator

32kHz internal ULP oscillator

zProgrammable 10-bit clock prescaling

zOne compare register

zOne period register

zClear counter on period overflow

zOptional interrupt/event on overflow and compare match

20.2 Overview

The 16-bit real-time counter (RTC) is a counter that typically runs continuously, including in low-power sleep

modes, to keep track of time. It can wake up the device from sleep modes and/or interrupt the device at regular

intervals.

The reference clock is typically the 1.024kHz output from a high-accuracy crystal of 32.768kHz, and this is the

configuration most optimized for low power consumption. The faster 32.768kHz output can be selected if the

RTC needs a resolution higher than 1ms. The RTC can also be clocked from an external clock signal, the

32.768kHz internal oscillator or the 32kHz internal ULP oscillator.

The RTC includes a 10-bit programmable prescaler that can scale down the reference clock before it reaches

the counter. A wide range of resolutions and time-out periods can be configured. With a 32.768kHz clock

source, the maximum resolution is 30.5µs, and time-out periods can range up to 2000 seconds. With a

resolution of 1s, the maximum timeout period is more than18 hours (65536 seconds). The RTC can give a

compare interrupt and/or event when the counter equals the compare register value, and an overflow interrupt

and/or event when it equals the period register value.

Figure 20-1. Real-time counter overview.

32.768kHz Crystal Osc

32.768kHz Int. Osc

TOSC1

TOSC2

External Clock

DIV32

32kHz int ULP (DIV32)

RTCSRC

10-bit

prescaler

clkRTC

CNT

PER

COMP

”match”/

Compare

TOP/

Overflow

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21. USB – Universal Serial Bus Interface

21.1 Features

zOne USB 2.0 full speed (12Mbps) and low speed (1.5Mbps) device compliant interface

zIntegrated on-chip USB transceiver, no external components needed

z16 endpoint addresses with full endpoint flexibility for up to 31 endpoints

One input endpoint per endpoint address

One output endpoint per endpoint address

zEndpoint address transfer type selectable to

Control transfers

Interrupt transfers

Bulk transfers

Isochronous transfers

zConfigurable data payload size per endpoint, up to 1023 bytes

zEndpoint configuration and data buffers located in internal SRAM

Configurable location for endpoint configuration data

Configurable location for each endpoint's data buffer

zBuilt-in direct memory access (DMA) to internal SRAM for:

Endpoint configurations

Reading and writing endpoint data

zPing-pong operation for higher throughput and double buffered operation

Input and output endpoint data buffers used in a single direction

CPU/DMA controller can update data buffer during transfer

zMultipacket transfer for reduced interrupt load and software intervention

Data payload exceeding maximum packet size is transferred in one continuous transfer

No interrupts or software interaction on packet transaction level

zTransaction complete FIFO for workflow management when using multiple endpoints

Tracks all completed transactions in a first-come, first-served work queue

zClock selection independent of system clock source and selection

zMinimum 1.5MHz CPU clock required for low speed USB operation

zMinimum 12MHz CPU clock required for full speed operation

zConnection to event system

zOn chip debug possibilities during USB transactions

21.2 Overview

The USB module is a USB 2.0 full speed (12Mbps) and low speed (1.5Mbps) device compliant interface.

The USB supports 16 endpoint addresses. All endpoint addresses have one input and one output endpoint, for

a total of 31 configurable endpoints and one control endpoint. Each endpoint address is fully configurable and

can be configured for any of the four transfer types; control, interrupt, bulk, or isochronous. The data payload

size is also selectable, and it supports data payloads up to 1023 bytes.

No dedicated memory is allocated for or included in the USB module. Internal SRAM is used to keep the

configuration for each endpoint address and the data buffer for each endpoint. The memory locations used for

endpoint configurations and data buffers are fully configurable. The amount of memory allocated is fully

dynamic, according to the number of endpoints in use and the configuration of these. The USB module has

built-in direct memory access (DMA), and will read/write data from/to the SRAM when a USB transaction takes

place.

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To maximize throughput, an endpoint address can be configured for ping-pong operation. When done, the input

and output endpoints are both used in the same direction. The CPU or DMA controller can then read/write one

data buffer while the USB module writes/reads the others, and vice versa. This gives double buffered

communication.

Multipacket transfer enables a data payload exceeding the maximum packet size of an endpoint to be

transferred as multiple packets without software intervention. This reduces the CPU intervention and the

interrupts needed for USB transfers.

For low-power operation, the USB module can put the microcontroller into any sleep mode when the USB bus is

idle and a suspend condition is given. Upon bus resumes, the USB module can wake up the microcontroller

from any sleep mode.

PORTD has one USB. Notation of this is USB.

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22. TWI – Two-Wire Interface

22.1 Features

zTwo Identical two-wire interface peripherals

zBidirectional, two-wire communication interface

Phillips I2C compatible

System Management Bus (SMBus) compatible

zBus master and slave operation supported

Slave operation

Single bus master operation

Bus master in multi-master bus environment

Multi-master arbitration

zFlexible slave address match functions

7-bit and general call address recognition in hardware

10-bit addressing supported

Address mask register for dual address match or address range masking

Optional software address recognition for unlimited number of addresses

zSlave can operate in all sleep modes, including power-down

zSlave address match can wake device from all sleep modes

z100kHz and 400kHz bus frequency support

zSlew-rate limited output drivers

zInput filter for bus noise and spike suppression

zSupport arbitration between start/repeated start and data bit (SMBus)

zSlave arbitration allows support for address resolve protocol (ARP) (SMBus)

22.2 Overview

The two-wire interface (TWI) is a bidirectional, two-wire communication interface. It is I2C and System

Management Bus (SMBus) compatible. The only external hardware needed to implement the bus is one pull-up

resistor on each bus line.

A device connected to the bus must act as a master or a slave. The master initiates a data transaction by

addressing a slave on the bus and telling whether it wants to transmit or receive data. One bus can have many

slaves and one or several masters that can take control of the bus. An arbitration process handles priority if

more than one master tries to transmit data at the same time. Mechanisms for resolving bus contention are

inherent in the protocol.

The TWI module supports master and slave functionality. The master and slave functionality are separated from

each other, and can be enabled and configured separately. The master module supports multi-master bus

operation and arbitration. It contains the baud rate generator. Both 100kHz and 400kHz bus frequency is

supported. Quick command and smart mode can be enabled to auto-trigger operations and reduce software

complexity.

The slave module implements 7-bit address match and general address call recognition in hardware. 10-bit

addressing is also supported. A dedicated address mask register can act as a second address match register or

as a register for address range masking. The slave continues to operate in all sleep modes, including power-

down mode. This enables the slave to wake up the device from all sleep modes on TWI address match. It is

possible to disable the address matching to let this be handled in software instead.

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The TWI module will detect START and STOP conditions, bus collisions, and bus errors. Arbitration lost, errors,

collision, and clock hold on the bus are also detected and indicated in separate status flags available in both

master and slave modes.

It is possible to disable the TWI drivers in the device, and enable a four-wire digital interface for connecting to an

external TWI bus driver. This can be used for applications where the device operates from a different VCC

voltage than used by the TWI bus.

PORTC and PORTE each has one TWI. Notation of these peripherals are TWIC and TWIE.

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23. SPI – Serial Peripheral Interface

23.1 Features

zThree Identical SPI peripherals

zFull-duplex, three-wire synchronous data transfer

zMaster or slave operation

zLsb first or msb first data transfer

zEight programmable bit rates

zInterrupt flag at the end of transmission

zWrite collision flag to indicate data collision

zWake up from idle sleep mode

zDouble speed master mode

23.2 Overview

The Serial Peripheral Interface (SPI) is a high-speed synchronous data transfer interface using three or four

pins. It allows fast communication between an Atmel AVR XMEGA device and peripheral devices or between

several microcontrollers. The SPI supports full-duplex communication.

A device connected to the bus must act as a master or slave. The master initiates and controls all data

transactions.

PORTC, PORTD, and PORTE each has one SPI. Notation of these peripherals are SPIC, SPID, and SPIE

respectivel

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24. USART

24.1 Features

zSeven identical USART peripherals

zFull-duplex operation

zAsynchronous or synchronous operation

Synchronous clock rates up to 1/2 of the device clock frequency

Asynchronous clock rates up to 1/8 of the device clock frequency

zSupports serial frames with 5, 6, 7, 8, or 9 data bits and 1 or 2 stop bits

zFractional baud rate generator

Can generate desired baud rate from any system clock frequency

No need for external oscillator with certain frequencies

zBuilt-in error detection and correction schemes

Odd or even parity generation and parity check

Data overrun and framing error detection

Noise filtering includes false start bit detection and digital low-pass filter

zSeparate interrupts for

Transmit complete

Transmit data register empty

Receive complete

zMultiprocessor communication mode

Addressing scheme to address a specific devices on a multidevice bus

Enable unaddressed devices to automatically ignore all frames

zMaster SPI mode

Double buffered operation

Operation up to 1/2 of the peripheral clock frequency

zIRCOM module for IrDA compliant pulse modulation/demodulation

24.2 Overview

The universal synchronous and asynchronous serial receiver and transmitter (USART) is a fast and flexible

serial communication module. The USART supports full-duplex communication and asynchronous and

synchronous operation. The USART can be configured to operate in SPI master mode and used for SPI

communication.

Communication is frame based, and the frame format can be customized to support a wide range of standards.

The USART is buffered in both directions, enabling continued data transmission without any delay between

frames. Separate interrupts for receive and transmit complete enable fully interrupt driven communication.

Frame error and buffer overflow are detected in hardware and indicated with separate status flags. Even or odd

parity generation and parity check can also be enabled.

The clock generator includes a fractional baud rate generator that is able to generate a wide range of USART

baud rates from any system clock frequencies. This removes the need to use an external crystal oscillator with

a specific frequency to achieve a required baud rate. It also supports external clock input in synchronous slave

operation.

When the USART is set in master SPI mode, all USART-specific logic is disabled, leaving the transmit and

receive buffers, shift registers, and baud rate generator enabled. Pin control and interrupt generation are

identical in both modes. The registers are used in both modes, but their functionality differs for some control

settings.

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An IRCOM module can be enabled for one USART to support IrDA 1.4 physical compliant pulse modulation and

demodulation for baud rates up to 115.2Kbps.

PORTC, PORTD, and PORTE each has two USARTs, while PORTF has one USART only. Notation of these

peripherals are USARTC0, USARTC1, USARTD0, USARTD1, USARTE0, USARTE1 and USARTF0,

respectively.

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25. IRCOM – IR Communication Module

25.1 Features

zPulse modulation/demodulation for infrared communication

zIrDA compatible for baud rates up to 115.2Kbps

zSelectable pulse modulation scheme

3/16 of the baud rate period

Fixed pulse period, 8-bit programmable

Pulse modulation disabled

zBuilt-in filtering

zCan be connected to and used by any USART

25.2 Overview

Atmel AVR XMEGA devices contain an infrared communication module (IRCOM) that is IrDA compatible for

baud rates up to 115.2Kbps. It can be connected to any USART to enable infrared pulse encoding/decoding for

that USART.

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26. AES and DES Crypto Engine

26.1 Features

zData Encryption Standard (DES) CPU instruction

zAdvanced Encryption Standard (AES) crypto module

zDES Instruction

Encryption and decryption

DES supported

Encryption/decryption in 16 CPU clock cycles per 8-byte block

zAES crypto module

Encryption and decryption

Supports 128-bit keys

Supports XOR data load mode to the state memory

Encryption/decryption in 375 clock cycles per 16-byte block

26.2 Overview

The Advanced Encryption Standard (AES) and Data Encryption Standard (DES) are two commonly used

standards for cryptography. These are supported through an AES peripheral module and a DES CPU

instruction, and the communication interfaces and the CPU can use these for fast, encrypted communication

and secure data storage.

DES is supported by an instruction in the AVR CPU. The 8-byte key and 8-byte data blocks must be loaded into

the register file, and then the DES instruction must be executed 16 times to encrypt/decrypt the data block.

The AES crypto module encrypts and decrypts 128-bit data blocks with the use of a 128-bit key. The key and

data must be loaded into the key and state memory in the module before encryption/decryption is started. It

takes 375 peripheral clock cycles before the encryption/decryption is done. The encrypted/encrypted data can

then be read out, and an optional interrupt can be generated. The AES crypto module also has DMA support

with transfer triggers when encryption/decryption is done and optional auto-start of encryption/decryption when

the state memory is fully loaded.

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27. CRC – Cyclic Redundancy Check Generator

27.1 Features

zCyclic redundancy check (CRC) generation and checking for

Communication data

Program or data in flash memory

Data in SRAM and I/O memory space

zIntegrated with flash memory, DMA controller and CPU

Continuous CRC on data going through a DMA channel

Automatic CRC of the complete or a selectable range of the flash memory

CPU can load data to the CRC generator through the I/O interface

zCRC polynomial software selectable to

CRC-16 (CRC-CCITT)

CRC-32 (IEEE 802.3)

zZero remainder detection

27.2 Overview

A cyclic redundancy check (CRC) is an error detection technique test algorithm used to find accidental errors in

data, and it is commonly used to determine the correctness of a data transmission, and data present in the data

and program memories. A CRC takes a data stream or a block of data as input and generates a 16- or 32-bit

output that can be appended to the data and used as a checksum. When the same data are later received or

read, the device or application repeats the calculation. If the new CRC result does not match the one calculated

earlier, the block contains a data error. The application will then detect this and may take a corrective action,

such as requesting the data to be sent again or simply not using the incorrect data.

Typically, an n-bit CRC applied to a data block of arbitrary length will detect any single error burst not longer

than n bits (any single alteration that spans no more than n bits of the data), and will detect the fraction 1-2-n of

all longer error bursts. The CRC module in Atmel AVR XMEGA devices supports two commonly used CRC

polynomials; CRC-16 (CRC-CCITT) and CRC-32 (IEEE 802.3).

zCRC-16:

zCRC-32:

Polynomial: x16+x12+x5+1

Hex value: 0x1021

Polynomial: x32+x26+x23+x22+x16+x12+x11+x10+x8+x7+x5+x4+x2+x+1

Hex value: 0x04C11DB7

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28. ADC – 12-bit Analog to Digital Converter

28.1 Features

zTwo Analog to Digital Converters (ADCs)

z12-bit resolution

zUp to two million samples per second

Two inputs can be sampled simultaneously using ADC and 1x gain stage

Four inputs can be sampled within 1.5µs

Down to 2.5µs conversion time with 8-bit resolution

Down to 3.5µs conversion time with 12-bit resolution

zDifferential and single-ended input

Up to 16 single-ended inputs

16x4 differential inputs without gain

8x4 differential input with gain

zBuilt-in differential gain stage

1/2x, 1x, 2x, 4x, 8x, 16x, 32x, and 64x gain options

zSingle, continuous and scan conversion options

zFour internal inputs

Internal temperature sensor

DAC output

AVCC voltage divided by 10

1.1V bandgap voltage

zFour conversion channels with individual input control and result registers

Enable four parallel configurations and results

zInternal and external reference options

zCompare function for accurate monitoring of user defined thresholds

zOptional event triggered conversion for accurate timing

zOptional DMA transfer of conversion results

zOptional interrupt/event on compare result

28.2 Overview

The ADC converts analog signals to digital values. The ADC has 12-bit resolution and is capable of converting

up to two million samples per second (msps). The input selection is flexible, and both single-ended and

differential measurements can be done. For differential measurements, an optional gain stage is available to

increase the dynamic range. In addition, several internal signal inputs are available. The ADC can provide both

signed and unsigned results.

This is a pipelined ADC that consists of several consecutive stages. The pipelined design allows a high sample

rate at a low system clock frequency. It also means that a new input can be sampled and a new ADC conversion

started while other ADC conversions are still ongoing. This removes dependencies between sample rate and

propagation delay.

The ADC has four conversion channels (0-3) with individual input selection, result registers, and conversion

start control. The ADC can then keep and use four parallel configurations and results, and this will ease use for

applications with high data throughput or for multiple modules using the ADC independently. It is possible to use

DMA to move ADC results directly to memory or peripherals when conversions are done.

XMEGA A3U [DATASHEET]

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Both internal and external reference voltages can be used. An integrated temperature sensor is available for

use with the ADC. The output from the DAC, AVCC/10 and the bandgap voltage can also be measured by the

ADC.

The ADC has a compare function for accurate monitoring of user defined thresholds with minimum software

intervention required.

Figure 28-1. ADC overview.

Two inputs can be sampled simultaneously as both the ADC and the gain stage include sample and hold

circuits, and the gain stage has 1x gain setting. Four inputs can be sampled within 1.5µs without any

intervention by the application.

The ADC may be configured for 8- or 12-bit result, reducing the minimum conversion time (propagation delay)

from 3.5µs for 12-bit to 2.5µs for 8-bit result.

ADC conversion results are provided left- or right adjusted with optional ‘1’ or ‘0’ padding. This eases calculation

when the result is represented as a signed integer (signed 16-bit number).

PORTA and PORTB each has one ADC. Notation of these peripherals are ADCA and ADCB, respectively.

CH1 Result

CH0 Result

CH2 Result

Compare

>Threshold

(Int Req)

Internal 1.00V

Internal AVCC/1.6V

AREFA

AREFB

VINP

VINN

Internal

signals

Internal AVCC/2

Internal

signals

CH3 Result

ADC0

ADC7

ADC4

ADC7

ADC0

ADC3

•

Int. signals

Reference

Voltage

½x - 64x

•

ADC0

ADC11

•

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29. DAC – 12-bit Digital to Analog Converter

29.1 Features

zOne Digital to Analog Converter (DAC)

z12-bit resolution

zTwo independent, continuous-drive output channels

zUp to one million samples per second conversion rate per DAC channel

zBuilt-in calibration that removes:

Offset error

Gain error

zMultiple conversion trigger sources

On new available data

Events from the event system

zHigh drive capabilities and support for

Resistive loads

Capacitive loads

Combined resistive and capacitive loads

zInternal and external reference options

zDAC output available as input to analog comparator and ADC

zLow-power mode, with reduced drive strength

zOptional DMA transfer of data

29.2 Overview

The digital-to-analog converter (DAC) converts digital values to voltages. The DAC has two channels, each with

12-bit resolution, and is capable of converting up to one million samples per second (msps) on each channel.

The built-in calibration system can remove offset and gain error when loaded with calibration values from

software.

Figure 29-1. DAC overview.

DAC0

DAC1

CTRLA

CH1DATA

CH0DATA

Trigger

Internal Output

enable

Enable

Internal 1.00V

AREFA

AREFB

Reference

selection

AVCC

Output

Driver

Output

Driver

Int.

driver

CTRLB

DMA req

(Data Empty)

DMA req

(Data Empty)

Select

Enable

AC/ADC

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A DAC conversion is automatically started when new data to be converted are available. Events from the event

system can also be used to trigger a conversion, and this enables synchronized and timed conversions between

the DAC and other peripherals, such as a timer/counter. The DMA controller can be used to transfer data to the

DAC.

The DAC has high drive strength, and is capable of driving both resistive and capacitive loads, aswell as loads

which combine both. A low-power mode is available, which will reduce the drive strength of the output. Internal

and external voltage references can be used. The DAC output is also internally available for use as input to the

analog comparator or ADC.

PORTB has one DAC. Notation of this peripheral is DACB.

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30. AC – Analog Comparator

30.1 Features

zFour Analog Comparators (AC)

zSelectable propagation delay versus current consumption

zSelectable hysteresis

No

Small

Large

zAnalog comparator output available on pin

zFlexible input selection

All pins on the port

Output from the DAC

Bandgap reference voltage

A 64-level programmable voltage scaler of the internal AVCC voltage

zInterrupt and event generation on:

Rising edge

Falling edge

Toggle

zWindow function interrupt and event generation on:

Signal above window

Signal inside window

Signal below window

zConstant current source with configurable output pin selection

30.2 Overview

The analog comparator (AC) compares the voltage levels on two inputs and gives a digital output based on this

comparison. The analog comparator may be configured to generate interrupt requests and/or events upon

several different combinations of input change.

Two important properties of the analog comparator’s dynamic behavior are: hysteresis and propagation delay.

Both of these parameters may be adjusted in order to achieve the optimal operation for each application.

The input selection includes analog port pins, several internal signals, and a 64-level programmable voltage

scaler. The analog comparator output state can also be output on a pin for use by external devices.

A constant current source can be enabled and output on a selectable pin. This can be used to replace, for

example, external resistors used to charge capacitors in capacitive touch sensing applications.

The analog comparators are always grouped in pairs on each port. These are called analog comparator 0 (AC0)

and analog comparator 1 (AC1). They have identical behavior, but separate control registers. Used as pair, they

can be set in window mode to compare a signal to a voltage range instead of a voltage level.

PORTA and PORTB each has one AC pair. Notations are ACA and ACB, respectively.

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Figure 30-1. Analog comparator overview.

The window function is realized by connecting the external inputs of the two analog comparators in a pair as

shown in Figure 30-2.

Figure 30-2. Analog comparator window function.

ACnMUXCTRL ACnCTRL

Interrupt

Mode

Enable

Hysteresis

AC1OUT

WINCTRL

Interrupt

Sensititivity

Control

Window

Function

Events

Interrupts

AC0OUT

Pin Input

Voltage

Scaler

DAC

Bandgap

AC0

AC1

Input signal

Upper limit of window

Lower limit of window

Interrupt

sensitivity

control

Interrupts

Events

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31. Programming and Debugging

31.1 Features

zProgramming

External programming through PDI or JTAG interfaces

zMinimal protocol overhead for fast operation

zBuilt-in error detection and handling for reliable operation

Boot loader support for programming through any communication interface

zDebugging

Nonintrusive, real-time, on-chip debug system

No software or hardware resources required from device except pin connection

Program flow control

zGo, Stop, Reset, Step Into, Step Over, Step Out, Run-to-Cursor

Unlimited number of user program breakpoints

Unlimited number of user data breakpoints, break on:

zData location read, write, or both read and write

zData location content equal or not equal to a value

zData location content is greater or smaller than a value

zData location content is within or outside a range

No limitation on device clock frequency

zProgram and Debug Interface (PDI)

Two-pin interface for external programming and debugging

Uses the Reset pin and a dedicated pin

No I/O pins required during programming or debugging

zJTAG interface

Four-pin, IEEE Std. 1149.1 compliant interface for programming and debugging

Boundary scan capabilities according to IEEE Std. 1149.1 (JTAG)

31.2 Overview

The Program and Debug Interface (PDI) is an Atmel proprietary interface for external programming and on-chip

debugging of a device.

The PDI supports fast programming of nonvolatile memory (NVM) spaces; flash, EEPOM, fuses, lock bits, and

the user signature row.

Debug is supported through an on-chip debug system that offers nonintrusive, real-time debug. It does not

require any software or hardware resources except for the device pin connection. Using the Atmel tool chain, it

offers complete program flow control and support for an unlimited number of program and complex data

breakpoints. Application debug can be done from a C or other high-level language source code level, as well as

from an assembler and disassembler level.

Programming and debugging can be done through two physical interfaces. The primary one is the PDI physical

layer, which is available on all devices. This is a two-pin interface that uses the Reset pin for the clock input

(PDI_CLK) and one other dedicated pin for data input and output (PDI_DATA). A JTAG interface is also

available on most devices, and this can be used for programming and debugging through the four-pin JTAG

interface. The JTAG interface is IEEE Std. 1149.1 compliant, and supports boundary scan. Any external

programmer or on-chip debugger/emulator can be directly connected to either of these interfaces. Unless

otherwise stated, all references to the PDI assume access through the PDI physical layer.

XMEGA A3U [DATASHEET]

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32. Pinout and Pin Functions

The device pinout is shown in “Pinout/Block Diagram” on page 5. In addition to general purpose I/O

functionality, each pin can have several alternate functions. This will depend on which peripheral is enabled and

connected to the actual pin. Only one of the pin functions can be used at time.

32.1 Alternate Pin Function Description

The tables below show the notation for all pin functions available and describe its function.

32.1.1 Operation/Power Supply

32.1.2 Port Interrupt functions

32.1.3 Analog functions

32.1.4 Timer/Counter and AWEX functions

32.1.5 Communication functions

VCC Digital supply voltage

AVCC Analog supply voltage

GND Ground

SYNC Port pin with full synchronous and limited asynchronous interrupt function

ASYNC Port pin with full synchronous and full asynchronous interrupt function

ACn Analog Comparator input pin n

ACnOUT Analog Comparator n Output

ADCn Analog to Digital Converter input pin n

DACn Digital to Analog Converter output pin n

AREF Analog Reference input pin

OCnxLS Output Compare Channel x Low Side for Timer/Counter n

OCnxHS Output Compare Channel x High Side for Timer/Counter n

SCL Serial Clock for TWI

SDA Serial Data for TWI

SCLIN Serial Clock In for TWI when external driver interface is enabled

SCLOUT Serial Clock Out for TWI when external driver interface is enabled

SDAIN Serial Data In for TWI when external driver interface is enabled

SDAOUT Serial Data Out for TWI when external driver interface is enabled

XCKn Transfer Clock for USART n

RXDn Receiver Data for USART n

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32.1.6 Oscillators, Clock and Event

32.1.7 Debug/System functions

TXDn Transmitter Data for USART n

SS Slave Select for SPI

MOSI Master Out Slave In for SPI

MISO Master In Slave Out for SPI

SCK Serial Clock for SPI

D- Data- for USB

D+ Data+ for USB

TOSCn Timer Oscillator pin n

XTALn Input/Output for Oscillator pin n

CLKOUT Peripheral Clock Output

EVOUT Event Channel Output

RTCOUT RTC Clock Source Output

RESET Reset pin

PDI_CLK Program and Debug Interface Clock pin

PDI_DATA Program and Debug Interface Data pin

TCK JTAG Test Clock

TDI JTAG Test Data In

TDO JTAG Test Data Out

TMS JTAG Test Mode Select

XMEGA A3U [DATASHEET]

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32.2 Alternate Pin Functions

The tables below show the primary/default function for each pin on a port in the first column, the pin number in

the second column, and then all alternate pin functions in the remaining columns. The head row shows what

peripheral that enable and use the alternate pin functions.

For better flexibility, some alternate functions also have selectable pin locations for their functions, this is noted

under the first table where this apply.

Table 32-1. Port A - alternate functions.

Table 32-2. Port B - alternate functions.

PORTA PIN# INTERRUPT ADCAPOS/

GAINPOS

ADCA

NEG

ADCA

GAINNEG

ACA

POS

ACA

NEG

ACA

OUT

REFA

GND 60

AVCC 61

PA0 62 SYNC ADC0 ADC0 AC0 AC0 AREF

PA1 63 SYNC ADC1 ADC1 AC1 AC1

PA2 64 SYNC/

ASYNC ADC2 ADC2 AC2

PA3 1SYNC ADC3 ADC3 AC3 AC3

PA4 2SYNC ADC4 ADC4 AC4

PA5 3SYNC ADC5 ADC5 AC5 AC5

PA6 4SYNC ADC6 ADC6 AC6 AC1OUT

PA7 5SYNC ADC7 ADC7 AC7 AC0OUT

PORTB PIN# INTERRUPT ADCAPOS/

GAINPOS

ADCBPOS/

GAINPOS

ADCB

NEG

ADCB

GAINNEG

ACB

POS

ACB

NEG

ACBOUT DACB REFB JTAG

PB0 6SYNC ADC8 ADC0 ADC0 AC0 AC0 AREF

PB1 7SYNC ADC9 ADC1 ADC1 AC1 AC1

PB2 8SYNC/

ASYNC ADC10 ADC2 ADC2 AC2 DAC0

PB3 9SYNC ADC11 ADC3 ADC3 AC3 AC3 DAC1

PB4 10 SYNC ADC12 ADC4 ADC4 AC4 TMS

PB5 11 SYNC ADC13 ADC5 ADC5 AC5 AC5 TDI

PB6 12 SYNC ADC14 ADC6 ADC6 AC6 AC1OUT TCK

PB7 13 SYNC ADC15 ADC7 ADC7 AC7 AC0OUT TDO

GND 14

VCC 15

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Table 32-3. Port C - alternate functions.

Notes: 1. Pin mapping of all TC0 can optionally be moved to high nibble of port.

2. If TC0 is configured as TC2 all eight pins can be used for PWM output.

3. Pin mapping of all USART0 can optionally be moved to high nibble of port.

4. Pins MOSI and SCK for all SPI can optionally be swapped.

5. CLKOUT can optionally be moved between port C, D and E and be on pin 4 or 7.

6. EVOUT can optionally be moved between port C, D and E and be on pin 4 or 7.

Table 32-4. Port D - alternate functions.

Notes: 1. Pin mapping of all TC0 can optionally be moved to high nibble of port.

2. If TC0 is configured as TC2 all eight pins can be used for PWM output.

3. Pin mapping of all USART0 can optionally be moved to high nibble of port.

4. Pins MOSI and SCK for all SPI can optionally be swapped.

5. CLKOUT can optionally be moved between port C, D and E and be on pin 4 or 7.

6. EVOUT can optionally be moved between port C, D and E and be on pin 4 or 7.

PORTC PIN# INTERRUPT TCC0

(1)(2)

AWEXC TCC1 USART

C0 (3)

USART

SPIC

(4) TWIC

TWIC

w/ext

driver

CLOCKOUT

(5)

EVENTOUT

(6)

PC0 16 SYNC OC0A OC0ALS SDA SDAIN

PC1 17 SYNC OC0B OC0AHS XCK0 SCL SCLIN

PC2 18 SYNC/

ASYNC OC0C OC0BLS RXD0 SDAOUT

PC3 19 SYNC OC0D OC0BHS TXD0 SCLOUT

PC4 20 SYNC OC0CLS OC1A SS

PC5 21 SYNC OC0CHS OC1B XCK1 MOSI

PC6 22 SYNC OC0DLS RXD1 MISO RTCOUT

PC7 23 SYNC OC0DHS TXD1 SCK clkPER EVOUT

GND 24

VCC 25

PORT D PIN # INTERRUPT TCD0 TCD1 USBD USARTD0 USARTD1 SPID CLOCKOUT EVENTOUT

PD0 26 SYNC OC0A

PD1 27 SYNC OC0B XCK0

PD2 28 SYNC/ASYNC OC0C RXD0

PD3 29 SYNC OC0D TXD0

PD4 30 SYNC OC1A SS

PD5 31 SYNC OC1B XCK1 MOSI

PD6 32 SYNC D- RXD1 MISO

PD7 33 SYNC D+ TXD1 SCK clkPER EVOUT

GND 34

VCC 35

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Table 32-5. Port E - alternate functions.

Notes: 1. Pin mapping of all TC0 can optionally be moved to high nibble of port.

2. If TC0 is configured as TC2 all eight pins can be used for PWM output.

3. Pin mapping of all USART0 can optionally be moved to high nibble of port.

4. Pins MOSI and SCK for all SPI can optionally be swapped.

5. CLKOUT can optionally be moved between port C, D and E and be on pin 4 or 7.

6. EVOUT can optionally be moved between port C, D and E and be on pin 4 or 7.

Table 32-6. Port F - alternate functions.

Table 32-7. Port R - alternate functions.

PORTE PIN # INTERRUPT TCE0 TCE1 USART

USART

SPIE TWIE

TWIE

w/ext

driver

TOSC CLOCKOUT EVENTOUT

PE0 36 SYNC OC0A SDA SDAIN

PE1 37 SYNC OC0B XCK0 SCL SCLIN

PE2 38 SYNC/ASYNC OC0C RXD0 SDAOUT

PE3 39 SYNC OC0D TXD0 SCLOUT

PE4 40 SYNC OC1A SS

PE5 41 SYNC OC1B XCK1 MOSI

PE6 42 SYNC RXD1 MISO TOSC2

PE7 43 SYNC TXD1 SCK TOSC1 clkPER EVOUT

GND 44

VCC 45

PORTF PIN# INTERRUPT TCF0 USARTF0

PF0 46 SYNC OC0A

PF1 47 SYNC OC0B XCK0

PF2 48 SYNC/ASYNC OC0C RXD0

PF3 49 SYNC OC0D TXD0

PF4 50 SYNC

PF5 51 SYNC

GND 52

VCC 53

PF6 54 SYNC

PF7 55 SYNC

PORTR PIN# INTERRUPT PDI XTAL

PDI 56 PDI_DATA

RESET 57 PDI_CLOCK

PR0 58 SYNC XTAL2

PR1 59 SYNC XTAL1

XMEGA A3U [DATASHEET]

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33. Peripheral Module Address Map

The address maps show the base address for each peripheral and module in Atmel AVR XMEGA A3U. For

complete register description and summary for each peripheral module, refer to the XMEGA AU manual.

Table 33-1. Peripheral module address map.

Base address Name Description

0x0000 GPIO General Purpose IO Registers

0x0010 VPORT0 Virtual Port 0

0x0014 VPORT1 Virtual Port 1

0x0018 VPORT2 Virtual Port 2

0x001C VPORT3 Virtual Port 2

0x0030 CPU CPU

0x0040 CLK Clock Control

0x0048 SLEEP Sleep Controller

0x0050 OSC Oscillator Control

0x0060 DFLLRC32M DFLL for the 32MHz Internal RC Oscillator

0x0068 DFLLRC2M DFLL for the 2MHz RC Oscillator

0x0070 PR Power Reduction

0x0078 RST Reset Controller

0x0080 WDT Watch-Dog Timer

0x0090 MCU MCU Control

0x00A0 PMIC Programmable MUltilevel Interrupt Controller

0x00B0 PORTCFG Port Configuration

0x00C0 AES AES Module

0x00D0 CRC CRC Module

0x0100 DMA DMA Module

0x0180 EVSYS Event System

0x01C0 NVM Non Volatile Memory (NVM) Controller

0x0200 ADCA Analog to Digital Converter on port A

0x0240 ADCB Analog to Digital Converter on port B

0x0320 DACB Digital to Analog Converter on port B

0x0380 ACA Analog Comparator pair on port A

0x0390 ACB Analog Comparator pair on port B

0x0400 RTC Real Time Counter

0x0480 TWIC Two Wire Interface on port C

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

0x04A0 TWIE Two Wire Interface on port E

0x04C0 USB Universal Serial Bus Interface

0x0600 PORTA Port A

0x0620 PORTB Port B

0x0640 PORTC Port C

0x0660 PORTD Port D

0x0680 PORTE Port E

0x06A0 PORTF Port F

0x07E0 PORTR Port R

0x0800 TCC0 Timer/Counter 0 on port C

0x0840 TCC1 Timer/Counter 1 on port C

0x0880 AWEXC Advanced Waveform Extension on port C

0x0890 HIRESC High Resolution Extension on port C

0x08A0 USARTC0 USART 0 on port C

0x08B0 USARTC1 USART 1 on port C

0x08C0 SPIC Serial Peripheral Interface on port C

0x08F8 IRCOM Infrared Communication Module

0x0900 TCD0 Timer/Counter 0 on port D

0x0940 TCD1 Timer/Counter 1 on port D

0x0990 HIRESD High Resolution Extension on port D

0x09A0 USARTD0 USART 0 on port D

0x09B0 USARTD1 USART 1 on port D

0x09C0 SPID Serial Peripheral Interface on port D

0x0A00 TCE0 Timer/Counter 0 on port E

0x0A90 HIRESE High Resolution Extension on port E

0x0AA0 USARTE0 USART 0 on port E

0x0AB0 USARTE1 USART 1 on port E

0x0AC0 SPIE Serial Peripheral Interface on port E

0x0B00 TCF0 Timer/Counter 0 on port F

Base address Name Description

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

34. Instruction Set Summary

Mnemonics Operands Description Operation Flags #Clocks

Arithmetic and Logic Instructions

ADD Rd, Rr Add without Carry Rd ←Rd + Rr Z,C,N,V,S,H 1

ADC Rd, Rr Add with Carry Rd ←Rd + Rr + C Z,C,N,V,S,H 1

ADIW Rd, K Add Immediate to Word Rd ←Rd + 1:Rd + K Z,C,N,V,S 2

SUB Rd, Rr Subtract without Carry Rd ←Rd - Rr Z,C,N,V,S,H 1

SUBI Rd, K Subtract Immediate Rd ←Rd - K Z,C,N,V,S,H 1

SBC Rd, Rr Subtract with Carry Rd ←Rd - Rr - C Z,C,N,V,S,H 1

SBCI Rd, K Subtract Immediate with Carry Rd ←Rd - K - C Z,C,N,V,S,H 1

SBIW Rd, K Subtract Immediate from Word Rd + 1:Rd ←Rd + 1:Rd - K Z,C,N,V,S 2

AND Rd, Rr Logical AND Rd ←Rd • Rr Z,N,V,S 1

ANDI Rd, K Logical AND with Immediate Rd ←Rd • K Z,N,V,S 1

OR Rd, Rr Logical OR Rd ←Rd v Rr Z,N,V,S 1

ORI Rd, K Logical OR with Immediate Rd ←Rd v K Z,N,V,S 1

EOR Rd, Rr Exclusive OR Rd ←Rd ⊕ Rr Z,N,V,S 1

COM Rd One’s Complement Rd ←$FF - Rd Z,C,N,V,S 1

NEG Rd Two’s Complement Rd ←$00 - Rd Z,C,N,V,S,H 1

SBR Rd,K Set Bit(s) in Register Rd ←Rd v K Z,N,V,S 1

CBR Rd,K Clear Bit(s) in Register Rd ←Rd • ($FFh - K) Z,N,V,S 1

INC Rd Increment Rd ←Rd + 1 Z,N,V,S 1

DEC Rd Decrement Rd ←Rd - 1 Z,N,V,S 1

TST Rd Test for Zero or Minus Rd ←Rd • Rd Z,N,V,S 1

CLR Rd Clear Register Rd ←Rd ⊕ Rd Z,N,V,S 1

SER Rd Set Register Rd ←$FF None 1

MUL Rd,Rr Multiply Unsigned R1:R0 ←Rd x Rr (UU) Z,C 2

MULS Rd,Rr Multiply Signed R1:R0 ←Rd x Rr (SS) Z,C 2

MULSU Rd,Rr Multiply Signed with Unsigned R1:R0 ←Rd x Rr (SU) Z,C 2

FMUL Rd,Rr Fractional Multiply Unsigned R1:R0 ←Rd x Rr<<1 (UU) Z,C 2

FMULS Rd,Rr Fractional Multiply Signed R1:R0 ←Rd x Rr<<1 (SS) Z,C 2

FMULSU Rd,Rr Fractional Multiply Signed with Unsigned R1:R0 ←Rd x Rr<<1 (SU) Z,C 2

DES KData Encryption if (H = 0) then R15:R0

else if (H = 1) then R15:R0

←

Encrypt(R15:R0, K)

Decrypt(R15:R0, K)

1/2

Branch instructions

RJMP kRelative Jump PC ←PC + k + 1 None 2

IJMP Indirect Jump to (Z) PC(15:0)

PC(21:16)

←

None 2

EIJMP Extended Indirect Jump to (Z) PC(15:0)

PC(21:16)

←

EIND

None 2

JMP kJump PC ←kNone 3

RCALL kRelative Call Subroutine PC ←PC + k + 1 None 2 / 3 (1)

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

ICALL Indirect Call to (Z) PC(15:0)

PC(21:16)

←

None 2 / 3 (1)

EICALL Extended Indirect Call to (Z) PC(15:0)

PC(21:16)

←

EIND

None 3 (1)

CALL kcall Subroutine PC ←kNone 3 / 4 (1)

RET Subroutine Return PC ←STACK None 4 / 5 (1)

RETI Interrupt Return PC ←STACK I4 / 5 (1)

CPSE Rd,Rr Compare, Skip if Equal if (Rd = Rr) PC ←PC + 2 or 3 None 1 / 2 / 3

CP Rd,Rr Compare Rd - Rr Z,C,N,V,S,H 1

CPC Rd,Rr Compare with Carry Rd - Rr - C Z,C,N,V,S,H 1

CPI Rd,K Compare with Immediate Rd - K Z,C,N,V,S,H 1

SBRC Rr, b Skip if Bit in Register Cleared if (Rr(b) = 0) PC ←PC + 2 or 3 None 1 / 2 / 3

SBRS Rr, b Skip if Bit in Register Set if (Rr(b) = 1) PC ←PC + 2 or 3 None 1 / 2 / 3

SBIC A, b Skip if Bit in I/O Register Cleared if (I/O(A,b) = 0) PC ←PC + 2 or 3 None 2 / 3 / 4

SBIS A, b Skip if Bit in I/O Register Set If (I/O(A,b) =1) PC ←PC + 2 or 3 None 2 / 3 / 4

BRBS s, k Branch if Status Flag Set if (SREG(s) = 1) then PC ←PC + k + 1 None 1 / 2

BRBC s, k Branch if Status Flag Cleared if (SREG(s) = 0) then PC ←PC + k + 1 None 1 / 2

BREQ k Branch if Equal if (Z = 1) then PC ←PC + k + 1 None 1 / 2

BRNE k Branch if Not Equal if (Z = 0) then PC ←PC + k + 1 None 1 / 2

BRCS k Branch if Carry Set if (C = 1) then PC ←PC + k + 1 None 1 / 2

BRCC k Branch if Carry Cleared if (C = 0) then PC ←PC + k + 1 None 1 / 2

BRSH k Branch if Same or Higher if (C = 0) then PC ←PC + k + 1 None 1 / 2

BRLO k Branch if Lower if (C = 1) then PC ←PC + k + 1 None 1 / 2

BRMI k Branch if Minus if (N = 1) then PC ←PC + k + 1 None 1 / 2

BRPL k Branch if Plus if (N = 0) then PC ←PC + k + 1 None 1 / 2

BRGE k Branch if Greater or Equal, Signed if (N ⊕ V= 0) then PC ←PC + k + 1 None 1 / 2

BRLT k Branch if Less Than, Signed if (N ⊕ V= 1) then PC ←PC + k + 1 None 1 / 2

BRHS k Branch if Half Carry Flag Set if (H = 1) then PC ←PC + k + 1 None 1 / 2

BRHC k Branch if Half Carry Flag Cleared if (H = 0) then PC ←PC + k + 1 None 1 / 2

BRTS k Branch if T Flag Set if (T = 1) then PC ←PC + k + 1 None 1 / 2

BRTC k Branch if T Flag Cleared if (T = 0) then PC ←PC + k + 1 None 1 / 2

BRVS k Branch if Overflow Flag is Set if (V = 1) then PC ←PC + k + 1 None 1 / 2

BRVC k Branch if Overflow Flag is Cleared if (V = 0) then PC ←PC + k + 1 None 1 / 2

BRIE k Branch if Interrupt Enabled if (I = 1) then PC ←PC + k + 1 None 1 / 2

BRID k Branch if Interrupt Disabled if (I = 0) then PC ←PC + k + 1 None 1 / 2

Data transfer instructions

MOV Rd, Rr Copy Register Rd ←Rr None 1

MOVW Rd, Rr Copy Register Pair Rd+1:Rd ←Rr+1:Rr None 1

LDI Rd, K Load Immediate Rd ←KNone 1

Mnemonics Operands Description Operation Flags #Clocks

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

LDS Rd, k Load Direct from data space Rd ←(k) None 2 (1)(2)

LD Rd, X Load Indirect Rd ←(X) None 1 (1)(2)

LD Rd, X+ Load Indirect and Post-Increment Rd

←

(X)

X + 1

None 1 (1)(2)

LD Rd, -X Load Indirect and Pre-Decrement X ← X - 1,

Rd ← (X)

←

X - 1

(X)

None 2 (1)(2)

LD Rd, Y Load Indirect Rd ← (Y) ←(Y) None 1 (1)(2)

LD Rd, Y+ Load Indirect and Post-Increment Rd

←

(Y)

Y + 1

None 1 (1)(2)

LD Rd, -Y Load Indirect and Pre-Decrement Y

←

Y - 1

(Y)

None 2 (1)(2)

LDD Rd, Y+q Load Indirect with Displacement Rd ←(Y + q) None 2 (1)(2)

LD Rd, Z Load Indirect Rd ←(Z) None 1 (1)(2)

LD Rd, Z+ Load Indirect and Post-Increment Rd

←

(Z),

Z+1

None 1 (1)(2)

LD Rd, -Z Load Indirect and Pre-Decrement Z

←

Z - 1,

(Z)

None 2 (1)(2)

LDD Rd, Z+q Load Indirect with Displacement Rd ←(Z + q) None 2 (1)(2)

STS k, Rr Store Direct to Data Space (k) ←Rd None 2 (1)

ST X, Rr Store Indirect (X) ←Rr None 1 (1)

ST X+, Rr Store Indirect and Post-Increment (X)

←

Rr,

X + 1

None 1 (1)

ST -X, Rr Store Indirect and Pre-Decrement X

(X)

←

X - 1,

None 2 (1)

ST Y, R r Store Indirect (Y) ←Rr None 1 (1)

ST Y+, Rr Store Indirect and Post-Increment (Y)

←

Rr,

Y + 1

None 1 (1)

ST -Y, Rr Store Indirect and Pre-Decrement Y

(Y)

←

Y - 1,

None 2 (1)

STD Y+q, Rr Store Indirect with Displacement (Y + q) ←Rr None 2 (1)

ST Z, Rr Store Indirect (Z) ←Rr None 1 (1)

ST Z+, Rr Store Indirect and Post-Increment (Z)

←

Z + 1

None 1 (1)

ST -Z, Rr Store Indirect and Pre-Decrement Z←Z - 1 None 2 (1)

STD Z+q,Rr Store Indirect with Displacement (Z + q) ←Rr None 2 (1)

LPM Load Program Memory R0 ←(Z) None 3

LPM Rd, Z Load Program Memory Rd ←(Z) None 3

LPM Rd, Z+ Load Program Memory and Post-Increment Rd

←

(Z),

Z + 1

None 3

ELPM Extended Load Program Memory R0 ←(RAMPZ:Z) None 3

ELPM Rd, Z Extended Load Program Memory Rd ←(RAMPZ:Z) None 3

ELPM Rd, Z+ Extended Load Program Memory and Post-

Increment

←

(RAMPZ:Z),

Z + 1

None 3

SPM Store Program Memory (RAMPZ:Z) ←R1:R0 None -

SPM Z+ Store Program Memory and Post-Increment

by 2

(RAMPZ:Z)

←

R1:R0,

Z + 2

None -

Mnemonics Operands Description Operation Flags #Clocks

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

IN Rd, A In From I/O Location Rd ←I/O(A) None 1

OUT A, Rr Out To I/O Location I/O(A) ←Rr None 1

PUSH Rr Push Register on Stack STACK ←Rr None 1 (1)

POP Rd Pop Register from Stack Rd ←STACK None 2 (1)

XCH Z, Rd Exchange RAM location Tem p

(Z)

←

Rd,

(Z),

Tem p

None 2

LAS Z, Rd Load and Set RAM location Temp

(Z)

←

Rd,

(Z),

Tem p v ( Z)

None 2

LAC Z, Rd Load and Clear RAM location Tem p

(Z)

←

Rd,

(Z),

($FFh – Rd) z (Z)

None 2

LAT Z, Rd Load and Toggle RAM location Te mp

(Z)

←

Rd,

(Z),

Tem p ⊕ (Z)

None 2

Bit and bit-test instructions

LSL Rd Logical Shift Left Rd(n+1)

Rd(0)

←

Rd(n),

Rd(7)

Z,C,N,V,H 1

LSR Rd Logical Shift Right Rd(n)

Rd(7)

←

Rd(n+1),

Rd(0)

Z,C,N,V 1

ROL Rd Rotate Left Through Carry Rd(0)

Rd(n+1)

←

Rd(n),

Rd(7)

Z,C,N,V,H 1

ROR Rd Rotate Right Through Carry Rd(7)

Rd(n)

←

Rd(n+1),

Rd(0)

Z,C,N,V 1

ASR Rd Arithmetic Shift Right Rd(n) ←Rd(n+1), n=0..6 Z,C,N,V 1

SWAP Rd Swap Nibbles Rd(3..0) ↔Rd(7..4) None 1

BSET sFlag Set SREG(s) ←1SREG(s) 1

BCLR sFlag Clear SREG(s) ←0SREG(s) 1

SBI A, b Set Bit in I/O Register I/O(A, b) ←1None 1

CBI A, b Clear Bit in I/O Register I/O(A, b) ←0None 1

BST Rr, b Bit Store from Register to T T←Rr(b) T 1

BLD Rd, b Bit load from T to Register Rd(b) ←TNone 1

SEC Set Carry C←1 C 1

CLC Clear Carry C←0 C 1

SEN Set Negative Flag N←1 N 1

CLN Clear Negative Flag N←0 N 1

SEZ Set Zero Flag Z←1 Z 1

CLZ Clear Zero Flag Z←0 Z 1

SEI Global Interrupt Enable I←1 I 1

CLI Global Interrupt Disable I←0 I 1

SES Set Signed Test Flag S←1 S 1

CLS Clear Signed Test Flag S←0 S 1

Mnemonics Operands Description Operation Flags #Clocks

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Notes: 1. Cycle times for Data memory accesses assume internal memory accesses, and are not valid for accesses via the external RAM interface.

2. One extra cycle must be added when accessing Internal SRAM.

SEV Set Two’s Complement Overflow V←1 V 1

CLV Clear Two’s Complement Overflow V←0 V 1

SET Set T in SREG T←1 T 1

CLT Clear T in SREG T←0 T 1

SEH Set Half Carry Flag in SREG H←1 H 1

CLH Clear Half Carry Flag in SREG H←0 H 1

MCU control instructions

BREAK Break (See specific descr. for BREAK) None 1

NOP No Operation None 1

SLEEP Sleep (see specific descr. for Sleep) None 1

WDR Watchdog Reset (see specific descr. for WDR) None 1

Mnemonics Operands Description Operation Flags #Clocks

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

35. Packaging information

35.1 64A

2325 Orchard Parkway

San Jose, CA 95131

TITLE DRAWING NO. REV.

64A, 64-lead, 14 x 14mm Body Size, 1.0mm Body Thickness,

0.8mm Lead Pitch, Thin Prole Plastic Quad Flat Package (TQFP) C

64A

2010-10-20

PIN 1 IDENTIFIER

0°~7°

PIN 1

A1 A2 A

E1 E

COMMON DIMENSIONS

(Unit of measure = mm)

SYMBOL MIN NOM MAX NOTE

Notes:

1.This package conforms to JEDEC reference MS-026, Variation AEB.

2. Dimensions D1 and E1 do not include mold protrusion. Allowable

protrusion is 0.25mm per side. Dimensions D1 and E1 are maximum

plastic body size dimensions including mold mismatch.

3. Lead coplanarity is 0.10mm maximum.

A – – 1.20

A1 0.05 – 0.15

A2 0.95 1.00 1.05

D 15.75 16.00 16.25

D1 13.90 14.00 14.10 Note 2

E 15.75 16.00 16.25

E1 13.90 14.00 14.10 Note 2

B 0.30 – 0.45

C 0.09 – 0.20

L 0.45 – 0.75

e 0.80 TYP

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

35.2 64M2

2325 Orchard Parkway

San Jose, CA 95131

TITLE DRAWING NO. REV.

64M2, 64-pad, 9 x 9 x 1.0mm Bod y, Lead Pitch 0.50mm , F

64M2

2014-05-30

COMMON DIMENSIONS

(Unit of Measure = mm)

SYMBOL MIN NOM MAX NOTE

A 0.80 0.90 1.00

A1 – 0.02 0.05

0.18 0.25 0.30

7.50 7.65 7.80

8.90 9.00 9.10

7.50 7.65 7.80

0.50 BSC

L 0.35 0.40

0.45

TOP VIEW

SIDE VIEW

BOTTOM VIEW

Marked Pin# 1 ID

SEATING PLANE

0.08

K0.20 0.27 0.40

2. Dimension and tolerance conform to ASMEY14.5M-1994.

0.20 REF

Pin #1 Corner

Pin #1

Triangle

Pin #1

Chamfer

(C 0.30)

Option A

Option B

Pin #1

Notch

(0.20 R)

Option C

Notes: 1. JEDEC Standard MO-220, (SAW Singulation) Fig. 1, VMMD.

7.65mm Exposed Pad, Package (QFN)

Quad Flat No Lead

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36. Electrical Characteristics

All typical values are measured at T = 25°C unless other temperature condition is given. All minimum and

maximum values are valid across operating temperature and voltage unless other conditions are given.

Note: For devices that are not available yet, preliminary values in this datasheet are based on simulations, and/or

characterization of similar AVR XMEGA microcontrollers. After the device is characterized the final values will be

available, hence existing values can change. Missing minimum and maximum values will be available after the

device is characterized.

36.1 ATxmega64A3U

36.1.1 Absolute Maximum Ratings

Stresses beyond those listed in Table 36-1 under may cause permanent damage to the device. This is a stress

rating only and functional operation of the device at these or other conditions beyond those indicated in the

operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for

extended periods may affect device reliability.

Table 36-1. Absolute maximum ratings.

36.1.2 General Operating Ratings

The device must operate within the ratings listed in Table 36-2 in order for all other electrical characteristics and

typical characteristics of the device to be valid.

Table 36-2. General operating conditions.

Symbol Parameter Condition Min. Typ. Max. Units

VCC Power Supply Voltage -0.3 4 V

IVCC Current into a VCC pin 200 mA

IGND Current out of a Gnd pin 200 mA

VPIN

Pin voltage with respect to

Gnd and VCC

-0.5 VCC+0.5 V

IPIN I/O pin sink/source current -25 25 mA

TAStorage temperature -65 150 °C

TjJunction temperature 150 °C

Symbol Parameter Condition Min. Typ. Max. Units

VCC Power Supply Voltage 1.60 3.6 V

AVCC Analog Supply Voltage 1.60 3.6 V

TATemperature range

85 °C -40 85

°C

105 °C -40 105

TjJunction temperature

85°C -40 105

°C

105°C -40 125

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Table 36-3. Operating voltage and frequency.

The maximum CPU clock frequency depends on VCC. As shown in Figure 36-1 the Frequency vs. VCC curve is

linear between 1.8V < VCC <2.7V.

Figure 36-1. Maximum Frequency vs. VCC.

Symbol Parameter Condition Min. Typ. Max. Units

ClkCPU CPU clock frequency

VCC = 1.6V 012

MHz

VCC = 1.8V 012

VCC = 2.7V 032

VCC = 3.6V 032

1.8

MHz

2.7 3.6

1.6

Safe Operating Area

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.3 Current consumption

Table 36-4. Current consumption for active mode and sleep modes.

Notes: 1. All Power Reduction Registers set.

2. Maximum limits are based on characterization, and not tested in production.

Symbol Parameter Condition Min. Typ. Max. Units

ICC

Active Power

consumption (1)

32kHz, Ext. Clk

VCC = 1.8V 50

µA

VCC = 3.0V 125

1MHz, Ext. Clk

VCC = 1.8V 250

VCC = 3.0V 520

2MHz, Ext. Clk

VCC = 1.8V 450 550

VCC = 3.0V

0.9 1.4

32MHz, Ext. Clk 9.5 15

Idle Power

consumption (1)

32kHz, Ext. Clk

VCC = 1.8V 3.0

µA

VCC = 3.0V 4.8

1MHz, Ext. Clk

VCC = 1.8V 75

VCC = 3.0V 140

2MHz, Ext. Clk

VCC = 1.8V 145 250

VCC = 3.0V

275 450

32MHz, Ext. Clk 4.4 7.0 mA

Power-down power

consumption

T = 25°C

VCC = 3.0V

0.1 1.0

µA

T = 85°C 1.6 5.0

T = 105°C 1.6 7

WDT and Sampled BOD enabled,

T = 25°C

VCC = 3.0V

1.3 3.0

WDT and Sampled BOD enabled,

T = 85°C 2.5 7.0

WDT and Sampled BOD enabled,

T = 105°C 2.5 8

Power-save power

consumption (2)

RTC from ULP clock, WDT and

sampled BOD enabled, T = 25°C

VCC = 1.8V 1.2

µA

VCC = 3.0V 1.3

RTC from 1.024kHz low power

32.768kHz TOSC, T = 25°C

VCC = 1.8V 0.6 2

VCC = 3.0V 0.7 2

RTC from low power 32.768kHz

TOSC, T = 25°C

VCC = 1.8V 0.8 3

VCC = 3.0V 1.0 3

Reset power consumption Current through RESET pin

substracted VCC = 3.0V 150 µA

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Table 36-5. Current consumption for modules and peripherals.

Note: 1. All parameters measured as the difference in current consumption between module enabled and disabled. All data at VCC = 3.0V, ClkSYS = 1MHz external

clock without prescaling, T = 25°C unless other conditions are given.

Symbol Parameter Condition(1) Min. Typ. Max. Units

ICC

ULP oscillator 1.0 µA

32.768kHz int. oscillator 26 µA

2MHz int. oscillator

µA

DFLL enabled with 32.768kHz int. osc. as reference 115

32MHz int. oscillator

270

µA

DFLL enabled with 32.768kHz int. osc. as reference 460

PLL 20x multiplication factor,

32MHz int. osc. DIV4 as reference 220 µA

Watchdog Timer 1µA

BOD

Continuous mode 138

µA

Sampled mode, includes ULP oscillator 1.2

Internal 1.0V reference 100 µA

Temperature sensor 95 µA

ADC 250ksps

VREF = Ext ref

3.0

CURRLIMIT = LOW 2.6

CURRLIMIT = MEDIUM 2.1

CURRLIMIT = HIGH 1.6

DAC

250ksps

VREF = Ext ref

No load

Normal mode 1.9

Low Power mode 1.1

High Speed Mode 330

µA

Low Power Mode 130

DMA 615KBps between I/O registers and SRAM 115 µA

Timer/Counter 16 µA

USART Rx and Tx enabled, 9600 BAUD 2.5 µA

Flash memory and EEPROM programming 4mA

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.4 Wake-up time from sleep modes

Table 36-6. Device wake-up time from sleep modes with various system clock sources.

Note: 1. The wake-up time is the time from the wake-up request is given until the peripheral clock is available on pin, see Figure 36-2. All peripherals and modules

start execution from the first clock cycle, expect the CPU that is halted for four clock cycles before program execution starts.

Figure 36-2. Wake-up time definition.

Symbol Parameter Condition Min. Typ. (1) Max. Units

twakeup

Wake-up time from Idle,

Standby, and Extended Standby

mode

External 2MHz clock 2

µs

32.768kHz internal oscillator 120

2MHz internal oscillator 2

32MHz internal oscillator 0.2

Wake-up time from Power-save

and Power-down mode

External 2MHz clock 4.5

µs

32.768kHz internal oscillator 320

2MHz internal oscillator 9

32MHz internal oscillator 5

Wakeup request

Clock output

Wakeup time

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.5 I/O Pin Characteristics

The I/O pins comply with the JEDEC LVTTL and LVCMOS specification and the high- and low level input and

output voltage limits reflect or exceed this specification.

Table 36-7. I/O pin characteristics.

Notes: 1. The sum of all IOH for PORTA and PORTB must not exceed 100mA.

The sum of all IOH for PORTC, PORTD, PORTE must for each port not exceed 200mA.

The sum of all IOH for pins PF[0-5] on PORTF must not exceed 200mA.

The sum of all IOL for pins PF[6-7] on PORTF, PORTR and PDI must not exceed 100mA.

2. The sum of all IOL for PORTA and PORTB must not exceed 100mA.

The sum of all IOL for PORTC, PORTD, PORTE must for each port not exceed 200mA.

The sum of all IOL for pins PF[0-5] on PORTF must not exceed 200mA.

The sum of all IOL for pins PF[6-7] on PORTF, PORTR and PDI must not exceed 100mA.

Symbol Parameter Condition Min. Typ. Max. Units

IOH (1)/

IOL (2) I/O pin source/sink current -20 20 mA

VIH High Level Input Voltage

VCC = 2.7 - 3.6V 2 VCC+0.3

VVCC = 2.0 - 2.7V 0.7*VCC VCC+0.3

VCC = 1.6 - 2.0V 0.8*VCC VCC+0.3

VIL Low Level Input Voltage

VCC = 2.7- 3.6V -0.3 0.8

VVCC = 2.0 - 2.7V -0.3 0.3*VCC

VCC = 1.6 - 2.0V -0.3 0.2*VCC

VOH High Level Output Voltage

VCC = 3.0 - 3.6V IOH = -2mA 2.4 0.94*VCC

VCC = 2.3 - 2.7V

IOH = -1mA 2.0 0.96*VCC

IOH = -2mA 1.7 0.92*VCC

VCC = 3.3V IOH = -8mA 2.6 2.9

VCC = 3.0V IOH = -6mA 2.1 2.6

VCC = 1.8V IOH = -2mA 1.4 1.6

VOL Low Level Output Voltage

VCC = 3.0 - 3.6V IOL = 2mA 0.05*VCC 0.4

VCC = 2.3 - 2.7V

IOL = 1mA 0.03*VCC 0.4

IOL = 2mA 0.06*VCC 0.7

VCC = 3.3V IOL = 15mA 0.4 0.76

VCC = 3.0V IOL = 10mA 0.3 0.64

VCC = 1.8V IOL = 5mA 0.3 0.46

IIN Input Leakage Current T = 25°C <0.01 0.1 µA

RPPull/Buss keeper Resistor 27 kΩ

trRise time No load

slew rate limitation 7

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.6 ADC characteristics

Table 36-8. Power supply, reference and input range.

Table 36-9. Clock and timing.

Symbol Parameter Condition Min. Typ. Max. Units

AVCC Analog supply voltage VCC- 0.3 VCC+ 0.3 V

VREF Reference voltage 1AVCC- 0.6 V

Rin Input resistance Switched 5.0 kΩ

Csample Input capacitance Switched 5.0 pF

RAREF Reference input resistance (leakage only) >10 MΩ

CAREF Reference input capacitance Static load 7pF

VIN Input range -0.1 AVCC+0.1 V

Conversion range Differential mode, Vinp - Vinn -VREF VREF V

VIN Conversion range Single ended unsigned mode, Vinp -ΔV VREF-ΔV V

∆VFixed offset voltage 190 LSB

Symbol Parameter Condition Min. Typ. Max. Units

ClkADC ADC Clock frequency

Maximum is 1/4 of Peripheral clock

frequency 100 2000

kHz

Measuring internal signals 100 125

fADC Sample rate

Current limitation (CURRLIMIT) off 100 2000

ksps

CURRLIMIT = LOW 100 1500

CURRLIMIT = MEDIUM 100 1000

CURRLIMIT = HIGH 100 500

Sampling Time 1/2 ClkADC cycle 0.25 5µs

Conversion time (latency) (RES+2)/2+(GAIN !=0)

RES (Resolution) = 8 or 12 5 8 ClkADC

cycles

Start-up time ADC clock cycles 12 24 ClkADC

cycles

ADC settling time

After changing reference or input mode 7 7 ClkADC

cycles

After ADC flush 1 1

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Table 36-10. Accuracy characteristics.

Notes: 1. Maximum numbers are based on characterisation and not tested in production, and valid for 5% to 95% input voltage range.

2. Unless otherwise noted all linearity, offset and gain error numbers are valid under the condition that external VREF is used.

Table 36-11. Gain stage characteristics.

Symbol Parameter Condition (2) Min. Typ. Max. Units

RES Resolution Programmable to 8 or 12 bit 812 12 Bits

INL (1) Integral non-linearity

500ksps

VCC-1.0V < VREF< VCC-0.6V ±1.2 ±2

lsb

All VREF ±1.5 ±3

2000ksps

VCC-1.0V < VREF< VCC-0.6V ±1.0 ±2

All VREF ±1.5 ±3

DNL (1) Differential non-linearity guaranteed monotonic <±0.8 <±1 lsb

Offset Error

-1 mV

Temperature drift <0.01 mV/K

Operating voltage drift <0.6 mV/V

Gain Error

Differential

mode

External reference -1

AVCC/1.6 10

AVCC/2.0 8

Bandgap ±5

Temperature drift <0.02 mV/K

Operating voltage drift <0.5 mV/V

Noise Differential mode, shorted input

2msps, VCC = 3.6V, ClkPER = 16MHz 0.4 mV

rms

Symbol Parameter Condition Min. Typ. Max. Units

Rin Input resistance Switched in normal mode 4.0 kΩ

Csample Input capacitance Switched in normal mode 4.4 pF

Signal range Gain stage output 0 VCC- 0.6 V

Propagation delay ADC conversion rate 1ClkADC

cycles

Sample rate Same as ADC 100 1000 kHz

INL (1) Integral Non-Linearity 500ksps All gain

settings ±1.5 ±4 lsb

Gain Error

1x gain, normal mode -0.8

%8x gain, normal mode -2.5

64x gain, normal mode -3.5

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Note: 1. Maximum numbers are based on characterisation and not tested in production, and valid for 5% to 95% input voltage range.

36.1.7 DAC Characteristics

Table 36-12. Power supply, reference and output range.

Table 36-13. Clock and timing.

Offset Error,

input referred

1x gain, normal mode -2

mV8x gain, normal mode -5

64x gain, normal mode -4

Noise

1x gain, normal mode

VCC = 3.6V

Ext. VREF

0.5

rms

8x gain, normal mode 1.5

64x gain, normal mode 11

Symbol Parameter Condition Min. Typ. Max. Units

AVCC Analog supply voltage VCC- 0.3 VCC+ 0.3

AVREF External reference voltage 1.0 VCC- 0.6 V

Rchannel DC output impedance 50 Ω

Linear output voltage range 0.15 AVCC-0.15 V

RAREF Reference input resistance >10 MΩ

CAREF Reference input capacitance Static load 7pF

Minimum Resistance load 1 kΩ

Maximum capacitance load

100 pF

1000Ω serial resistance 1nF

Output sink/source

Operating within accuracy specification AVCC/1000

Safe operation 10

Symbol Parameter Condition Min. Typ. Max. Units

fDAC Conversion rate Cload=100pF,

maximum step size

Normal mode 01000

ksps

Low power mode 0500

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Table 36-14. Accuracy characteristics.

Note: 1. Maximum numbers are based on characterisation and not tested in production, and valid for 5% to 95% output voltage range.

36.1.8 Analog Comparator Characteristics

Table 36-15. Analog Comparator characteristics.

Symbol Parameter Condition Min. Typ. Max. Units

RES Input Resolution 12 Bits

INL (1) Integral non-linearity

VREF= Ext 1.0V

VCC = 1.6V ±2.0 ±3

lsb

VCC = 3.6V ±1.5 ±2.5

VREF=AVCC

VCC = 1.6V ±2.0 ±4

VCC = 3.6V ±1.5 ±4

VREF=INT1V

VCC = 1.6V ±5.0

VCC = 3.6V ±5.0

DNL (1) Differential non-linearity

VREF=Ext 1.0V

VCC = 1.6V ±1.5 3

lsb

VCC = 3.6V ±0.6 1.5

VREF=AVCC

VCC = 1.6V ±1.0 3.5

VCC = 3.6V ±0.6 1.5

VREF=INT1V

VCC = 1.6V ±4.5

VCC = 3.6V ±4.5

Gain error After calibration <4 lsb

Gain calibration step size 4lsb

Gain calibration drift VREF= Ext 1.0V <0.2 mV/K

Offset error After calibration <1 lsb

Offset calibration step size 1

Symbol Parameter Condition Min. Typ. Max. Units

Voff Input Offset Voltage <±10 mV

Ilk Input Leakage Current <1 nA

Input voltage range -0.1 AVCC V

AC startup time 100 µs

Vhys1 Hysteresis, None 0mV

Vhys2 Hysteresis, Small

mode = High Speed (HS) 13

mode = Low Power (LP) 30

Vhys3 Hysteresis, Large

mode = HS 30

mode = LP 60

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.9 Bandgap and Internal 1.0V Reference Characteristics

Table 36-16. Bandgap and Internal 1.0V reference characteristics.

36.1.10 Brownout Detection Characteristics

Table 36-17. Brownout detection characteristics.

tdelay Propagation delay

mode = HS

VCC = 3.0V,

T= 85°C 60 90

VCC = 1.6V - 3.6V

mode = LP 160

64-Level Voltage Scaler Integral non-linearity (INL) 0.3 0.5 lsb

Symbol Parameter Condition Min. Typ. Max. Units

Startup time

As reference for ADC or DAC 1 ClkPER + 2.5µs

µs

As input voltage to ADC and AC 1.5

Bandgap voltage 1.1 V

INT1V Internal 1.00V reference T= 85°C, after calibration 0.99 11.01 V

Variation over voltage and temperature Relative to T= 85°C, VCC = 3.0V ±1.0 %

Symbol Parameter Condition Min. Typ. Max. Units

VBOT

BOD level 0 falling VCC 1.60 1.62 1.72

BOD level 1 falling VCC 1.8

BOD level 2 falling VCC 2.0

BOD level 3 falling VCC 2.2

BOD level 4 falling VCC 2.4

BOD level 5 falling VCC 2.6

BOD level 6 falling VCC 2.8

BOD level 7 falling VCC 3.0

tBOD Detection time

Continuous mode 0.4

µs

Sampled mode 1000

VHYST Hysteresis 1.6 %

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.11 External Reset Characteristics

Table 36-18. External reset characteristics.

36.1.12 Power-on Reset Characteristics

Table 36-19. Power-on reset characteristics.

Note: 1. VPOT- values are only valid when BOD is disabled. When BOD is enabled VPOT- = VPOT+.

36.1.13 Flash and EEPROM Memory Characteristics

Table 36-20. Endurance and data retention.

Symbol Parameter Condition Min. Typ. Max. Units

tEXT Minimum reset pulse width 95 1000 ns

VRST

Reset threshold voltage (VIH)

VCC = 2.7 - 3.6V 0.60*VCC

VCC = 1.6 - 2.7V 0.70*VCC

Reset threshold voltage (VIL)

VCC = 2.7 - 3.6V 0.40*VCC

VCC = 1.6 - 2.7V 0.30*VCC

RRST Reset pin Pull-up Resistor 25 kΩ

Symbol Parameter Condition Min. Typ. Max. Units

VPOT- (1) POR threshold voltage falling VCC

VCC falls faster than 1V/ms 0.4 1.0

VCC falls at 1V/ms or slower 0.8 1.0

VPOT+ POR threshold voltage rising VCC 1.3 1.59 V

Symbol Parameter Condition Min. Typ. Max. Units

Flash

Write/Erase cycles

25°C 10K

Cycle85°C 10K

105°C 2K

Data retention

25°C 100

Year85°C 25

105°C 10

EEPROM

Write/Erase cycles

25°C 100K

Cycle85°C 100K

105°C 30K

Data retention

25°C 100

Year85°C 25

105°C 10

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Table 36-21. Programming time.

Notes: 1. Programming is timed from the 2MHz internal oscillator.

2. EEPROM is not erased if the EESAVE fuse is programmed.

36.1.14 Clock and Oscillator Characteristics

36.1.14.1 Calibrated 32.768kHz Internal Oscillator characteristics

Table 36-22. 32.768kHz internal oscillator characteristics.

36.1.14.2 Calibrated 2MHz RC Internal Oscillator characteristics

Table 36-23. 2MHz internal oscillator characteristics.

Symbol Parameter Condition Min. Typ. (1) Max. Units

Chip Erase 64KB Flash, EEPROM (2) and SRAM Erase 55 ms

Application Erase Section erase 6ms

Flash

Page Erase 4

msPage Write 4

Atomic Page Erase and Write 8

EEPROM

Page Erase 4

msPage Write 4

Atomic Page Erase and Write 8

Symbol Parameter Condition Min. Typ. Max. Units

Frequency 32.768 kHz

Factory calibration accuracy T = 85°C, VCC = 3.0V -0.5 0.5 %

User calibration accuracy -0.5 0.5 %

Symbol Parameter Condition Min. Typ. Max. Units

Frequency range DFLL can tune to this frequency over

voltage and temperature 1.8 2.2 MHz

Factory calibrated frequency 2.0 MHz

Factory calibration accuracy T = 85°C, VCC= 3.0V -1.5 1.5 %

User calibration accuracy -0.2 0.2 %

DFLL calibration stepsize 0.22 %

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.14.3 Calibrated and tunable 32MHz internal oscillator characteristics

Table 36-24. 32MHz internal oscillator characteristics.

36.1.14.4 32kHz Internal ULP Oscillator characteristics

Table 36-25. 32kHz internal ULP oscillator characteristics.

36.1.14.5 Internal Phase Locked Loop (PLL) characteristics

Table 36-26. Internal PLL characteristics.

Note: 1. The maximum output frequency vs. supply voltage is linear between 1.8V and 2.7V, and can never be higher than four times the maximum CPU frequency.

Symbol Parameter Condition Min. Typ. Max. Units

Frequency range DFLL can tune to this frequency over

voltage and temperature 30 55 MHz

Factory calibrated frequency 32 MHz

Factory calibration accuracy T = 85°C, VCC= 3.0V -1.5 1.5 %

User calibration accuracy -0.2 0.2 %

DFLL calibration step size 0.23 %

Symbol Parameter Condition Min. Typ. Max. Units

Output frequency 32 kHz

Accuracy -30 30 %

Symbo

lParameter Condition Min. Typ. Max. Units

fIN Input Frequency Output frequency must be within fOUT 0.4 64 MHz

fOUT Output frequency (1) VCC= 1.6 - 1.8V 20 48

MHz

VCC= 2.7 - 3.6V 20 128

Start-up time 25 µs

Re-lock time 25 µs

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.14.6 External clock characteristics

Figure 36-3. External clock drive waveform

Table 36-27. External clock used as system clock without prescaling.

Note: 1. The maximum frequency vs. supply voltage is linear between 1.8V and 2.7V, and the same applies for all other parameters with supply voltage conditions.

tCH

tCL

tCK

tCH

VIL1

VIH1

tCR tCF

Symbol Parameter Condition Min. Typ. Max. Units

1/tCK Clock Frequency (1) VCC = 1.6 - 1.8V 012

MHz

VCC = 2.7 - 3.6V 032

tCK Clock Period

VCC = 1.6 - 1.8V 83.3

VCC = 2.7 - 3.6V 31.5

tCH Clock High Time

VCC = 1.6 - 1.8V 30.0

VCC = 2.7 - 3.6V 12.5

tCL Clock Low Time

VCC = 1.6 - 1.8V 30.0

VCC = 2.7 - 3.6V 12.5

tCR Rise Time (for maximum frequency)

VCC = 1.6 - 1.8V 10

VCC = 2.7 - 3.6V 3

tCF Fall Time (for maximum frequency)

VCC = 1.6 - 1.8V 10

VCC = 2.7 - 3.6V 3

ΔtCK Change in period from one clock cycle to the next 10 %

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Table 36-28. External clock with prescaler (1)for system clock.

Notes: 1. System Clock Prescalers must be set so that maximum CPU clock frequency for device is not exceeded.

2. The maximum frequency vs. supply voltage is linear between 1.6V and 2.7V, and the same applies for all other parameters with supply voltage conditions.

36.1.14.7 External 16MHz crystal oscillator and XOSC characteristics

Table 36-29. External 16MHz crystal oscillator and XOSC characteristics..

Symbol Parameter Condition Min. Typ. Max. Units

1/tCK Clock Frequency (2) VCC = 1.6 - 1.8V 090

MHz

VCC = 2.7 - 3.6V 0142

tCK Clock Period

VCC = 1.6 - 1.8V 11

VCC = 2.7 - 3.6V 7

tCH Clock High Time

VCC = 1.6 - 1.8V 4.5

VCC = 2.7 - 3.6V 2.4

tCL Clock Low Time

VCC = 1.6 - 1.8V 4.5

VCC = 2.7 - 3.6V 2.4

tCR Rise Time (for maximum frequency)

VCC = 1.6 - 1.8V 1.5

VCC = 2.7 - 3.6V 1.0

tCF Fall Time (for maximum frequency)

VCC = 1.6 - 1.8V 1.5

VCC = 2.7 - 3.6V 1.0

ΔtCK Change in period from one clock cycle to the next 10 %

Symbol Parameter Condition Min. Typ. Max. Units

Cycle to cycle jitter

XOSCPWR=0

FRQRANGE=0 <10

nsFRQRANGE=1, 2, or 3 <1

XOSCPWR=1 <1

Long term jitter

XOSCPWR=0

FRQRANGE=0 <6

nsFRQRANGE=1, 2, or 3 <0.5

XOSCPWR=1 <0.5

Frequency error

XOSCPWR=0

FRQRANGE=0 <0.1

FRQRANGE=1 <0.05

FRQRANGE=2 or 3 <0.005

XOSCPWR=1 <0.005

Duty cycle

XOSCPWR=0

FRQRANGE=0 40

FRQRANGE=1 42

FRQRANGE=2 or 3 45

XOSCPWR=1 48

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Note: 1. Numbers for negative impedance are not tested in production but guaranteed from design and characterization.

Negative impedance

(1)

XOSCPWR=0,

FRQRANGE=0

0.4MHz resonator,

CL=100pF 2.4k

1MHz crystal, CL=20pF 8.7k

2MHz crystal, CL=20pF 2.1k

XOSCPWR=0,

FRQRANGE=1,

CL=20pF

2MHz crystal 4.2k

8MHz crystal 250

9MHz crystal 195

XOSCPWR=0,

FRQRANGE=2,

CL=20pF

8MHz crystal 360

9MHz crystal 285

12MHz crystal 155

XOSCPWR=0,

FRQRANGE=3,

CL=20pF

9MHz crystal 365

12MHz crystal 200

16MHz crystal 105

XOSCPWR=1,

FRQRANGE=0,

CL=20pF

9MHz crystal 435

12MHz crystal 235

16MHz crystal 125

XOSCPWR=1,

FRQRANGE=1,

CL=20pF

9MHz crystal 495

12MHz crystal 270

16MHz crystal 145

XOSCPWR=1,

FRQRANGE=2,

CL=20pF

12MHz crystal 305

16MHz crystal 160

XOSCPWR=1,

FRQRANGE=3,

CL=20pF

12MHz crystal 380

16MHz crystal 205

ESR SF = Safety factor min(RQ)/SF kΩ

CXTAL1

Parasitic

capacitance XTAL1

5.2 pF

CXTAL2

Parasitic

capacitance XTAL2

6.8 pF

CLOAD

Parasitic

capacitance load 2.95 pF

Symbol Parameter Condition Min. Typ. Max. Units

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.14.8 External 32.768kHz crystal oscillator and TOSC characteristics

Table 36-30. External 32.768kHz crystal oscillator and TOSC characteristics.

Note: 1. See Figure 36-4 for definition.

Figure 36-4. TOSC input capacitance.

The parasitic capacitance between the TOSC pins is CL1 + CL2 in series as seen from the crystal when

oscillating without external capacitors.

Symbol Parameter Condition Min. Typ. Max. Units

ESR/R1 Recommended crystal equivalent

series resistance (ESR)

Crystal load capacitance 6.5pF 60

kΩ

Crystal load capacitance 9.0pF 35

CTOSC1 Parasitic capacitance TOSC1 pin 4.2 pF

CTOSC2 Parasitic capacitance TOSC2 pin 4.3 pF

Recommended safety factor capacitance load matched to

crystal specification 3

2CS

TDevice internal

External

32.768kHz crystal

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.15 SPI Characteristics

Figure 36-5. SPI timing requirements in master mode.

Figure 36-6. SPI timing requirements in slave mode.

MSB LSB

BSLBSM

MOS

MIS

MIH

SCKW

SCK

MOH

SCKF

SCKR

SCKW

MOSI

(Data Output)

MISO

(Data Input)

SCK

(CPOL = 1)

SCK

(CPOL = 0)

MSB LSB

BSLBSM

SIS

SIH

SSCKW

SSCK

SSH

SOSSH

SCKR

SCKF

SOS

SSS

SOSSS

MISO

(Data Output)

MOSI

(Data Input)

SCK

(CPOL = 1)

SCK

(CPOL = 0)

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Table 36-31. SPI timing characteristics and requirements.

Symbol Parameter Condition Min. Typ. Max. Units

tSCK SCK Period Master (See Table 21-4 in

XMEGA AU Manual)

tSCKW SCK high/low width Master 0.5*SCK

tSCKR SCK Rise time Master 2.7

tSCKF SCK Fall time Master 2.7

tMIS MISO setup to SCK Master 11

tMIH MISO hold after SCK Master 0

tMOS MOSI setup SCK Master 0.5*tSCK

tMOH MOSI hold after SCK Master 1

tSSCK Slave SCK Period Slave 4*t ClkPER

tSSCKW SCK high/low width Slave 2*t ClkPER

tSSCKR SCK Rise time Slave 1600

tSSCKF SCK Fall time Slave 1600

tSIS MOSI setup to SCK Slave 3

tSIH MOSI hold after SCK Slave tsck

tSSS SS setup to SCK Slave 20

tSSH SS hold after SCK Slave 20

tSOS MISO setup SCK Slave 8

tSOH MISO hold after SCK Slave 13

tSOSS MISO setup after SS low Slave 11

tSOSH MISO hold after SS high Slave 8

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.1.16 Two-Wire Interface Characteristics

Table 36-32 describes the requirements for devices connected to the Two-Wire Interface Bus. The Atmel AVR

XMEGA Two-Wire Interface meets or exceeds these requirements under the noted conditions. Timing symbols

refer to Figure 36-7.

Figure 36-7. Two-wire interface bus timing.

Table 36-32. Two-wire interface characteristics.

tHD;STA

tof

SDA

SCL

tLOW

tHIGH

tSU;STA

tBUF

tHD;DAT tSU;DAT tSU;STO

Symbol Parameter Condition Min. Typ. Max. Units

VIH Input High Voltage 0.7*VCC VCC+0.5 V

VIL Input Low Voltage -0.5 0.3*VCC V

Vhys Hysteresis of Schmitt Trigger Inputs 0.05*VCC (1) 0 V

VOL Output Low Voltage 3mA, sink current 00.4 V

trRise Time for both SDA and SCL 20+0.1Cb (1)(2) 0ns

tof Output Fall Time from VIHmin to VILmax 10pF < Cb < 400pF (2) 20+0.1Cb (1)(2) 300 ns

tSP Spikes Suppressed by Input Filter 050 ns

IIInput Current for each I/O Pin 0.1VCC < VI < 0.9VCC -10 10 µA

CICapacitance for each I/O Pin 10 pF

fSCL SCL Clock Frequency fPER (3)>max(10fSCL, 250kHz) 0400 kHz

RPValue of Pull-up resistor

fSCL ≤ 100kHz

fSCL > 100kHz

tHD;STA Hold Time (repeated) START condition

fSCL ≤ 100kHz 4.0

µs

fSCL > 100kHz 0.6

tLOW Low Period of SCL Clock

fSCL ≤ 100kHz 4.7

µs

fSCL > 100kHz 1.3

tHIGH High Period of SCL Clock

fSCL ≤ 100kHz 4.0

µs

fSCL > 100kHz 0.6

VCC 0.4V–

3mA

----------------------------

100ns

---------------

300ns

---------------

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Notes: 1. Required only for fSCL > 100kHz.

2. Cb = Capacitance of one bus line in pF.

3. fPER = Peripheral clock frequency.

tSU;STA

Set-up time for a repeated START

condition

fSCL ≤ 100kHz 4.7

µs

fSCL > 100kHz 0.6

tHD;DAT Data hold time

fSCL ≤ 100kHz 03.45

µs

fSCL > 100kHz 00.9

tSU;DAT Data setup time

fSCL ≤ 100kHz 250

fSCL > 100kHz 100

tSU;STO Setup time for STOP condition

fSCL ≤ 100kHz 4.0

µs

fSCL > 100kHz 0.6

tBUF

Bus free time between a STOP and

START condition

fSCL ≤ 100kHz 4.7

µs

fSCL > 100kHz 1.3

Symbol Parameter Condition Min. Typ. Max. Units

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.2 ATxmega128A3U

36.2.1 Absolute Maximum Ratings

Stresses beyond those listed in Table 36-1 under may cause permanent damage to the device. This is a stress

rating only and functional operation of the device at these or other conditions beyond those indicated in the

operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for

extended periods may affect device reliability.

Table 36-33. Absolute maximum ratings.

36.2.2 General Operating Ratings

The device must operate within the ratings listed in Table 36-2 in order for all other electrical characteristics and

typical characteristics of the device to be valid.

Table 36-34. General operating conditions.

Table 36-35. Operating voltage and frequency.

Symbol Parameter Condition Min. Typ. Max. Units

VCC Power Supply Voltage -0.3 4 V

IVCC Current into a VCC pin 200 mA

IGND Current out of a Gnd pin 200 mA

VPIN

Pin voltage with respect to

Gnd and VCC

-0.5 VCC+0.5 V

IPIN I/O pin sink/source current -25 25 mA

TAStorage temperature -65 150 °C

TjJunction temperature 150 °C

Symbol Parameter Condition Min. Typ. Max. Units

VCC Power Supply Voltage 1.60 3.6 V

AVCC Analog Supply Voltage 1.60 3.6 V

TATemperature range

85 °C -40 85

°C

105 °C -40 105

TjJunction temperature

85°C -40 105

°C

105°C -40 125

Symbol Parameter Condition Min. Typ. Max. Units

ClkCPU CPU clock frequency

VCC = 1.6V 012

MHz

VCC = 1.8V 012

VCC = 2.7V 032

VCC = 3.6V 032

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

The maximum CPU clock frequency depends on VCC. As shown in Figure 36-1 the Frequency vs. VCC curve is

linear between 1.8V < VCC <2.7V.

Figure 36-8. Maximum Frequency vs. VCC.

1.8

MHz

2.7 3.6

1.6

Safe Operating Area

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.2.3 Current consumption

Table 36-36. Current consumption for active mode and sleep modes.

Notes: 1. All Power Reduction Registers set.

2. Maximum limits are based on characterization, and not tested in production.

Symbol Parameter Condition Min. Typ. Max. Units

ICC

Active Power

consumption (1)

32kHz, Ext. Clk

VCC = 1.8V 60

µA

VCC = 3.0V 140

1MHz, Ext. Clk

VCC = 1.8V 280

VCC = 3.0V 600

2MHz, Ext. Clk

VCC = 1.8V 510 600

VCC = 3.0V

1.1 1.5

32MHz, Ext. Clk 10.5 15

Idle Power

consumption (1)

32kHz, Ext. Clk

VCC = 1.8V 4.3

µA

VCC = 3.0V 4.8

1MHz, Ext. Clk

VCC = 1.8V 78

VCC = 3.0V 147

2MHz, Ext. Clk

VCC = 1.8V 156 250

VCC = 3.0V

293 600

32MHz, Ext. Clk 4.7 7mA

Power-down power

consumption

T = 25°C

VCC = 3.0V

0.1 1.0

µA

T = 85°C 1.75 5.0

T= 105°C 4 8

WDT and Sampled BOD enabled,

T = 25°C

VCC = 3.0V

1.2 3.0

WDT and Sampled BOD enabled,

T = 85°C 3.1 7

WDT and Sampled BOD enabled,

T = 105°C 5.3 10

Power-save power

consumption (2)

RTC from ULP clock, WDT and

sampled BOD enabled, T = 25°C

VCC = 1.8V 1.2

µA

VCC = 3.0V 1.3

RTC from 1.024kHz low power

32.768kHz TOSC, T = 25°C

VCC = 1.8V 0.5 2

VCC = 3.0V 0.7 2

RTC from low power 32.768kHz

TOSC, T = 25°C

VCC = 1.8V 0.9 3

VCC = 3.0V 1.2 3.5

Reset power consumption Current through RESET pin

substracted VCC = 3.0V 150 µA

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

Table 36-37. Current consumption for modules and peripherals.

Note: 1. All parameters measured as the difference in current consumption between module enabled and disabled. All data at

VCC = 3.0V, ClkSYS = 1MHz external clock without prescaling, T = 25°C unless other conditions are givenAll parameters

measured as the difference in current consumption between module enabled and disabled. All data at VCC = 3.0V, ClkSYS = 1MHz external clock without

prescaling, T = 25°C unless other conditions are given.

Symbol Parameter Condition(1) Min. Typ. Max. Units

ICC

ULP oscillator 1.0 µA

32.768kHz int. oscillator 27 µA

2MHz int. oscillator

µA

DFLL enabled with 32.768kHz int. osc. as reference 115

32MHz int. oscillator

270

µA

DFLL enabled with 32.768kHz int. osc. as reference 460

PLL 20x multiplication factor,

32MHz int. osc. DIV4 as reference 220 µA

Watchdog Timer 1µA

BOD

Continuous mode 138

µA

Sampled mode, includes ULP oscillator 1.2

Internal 1.0V reference 100 µA

Temperature sensor 95 µA

ADC 250ksps

VREF = Ext ref

3.0

CURRLIMIT = LOW 2.6

CURRLIMIT = MEDIUM 2.1

CURRLIMIT = HIGH 1.6

DAC

250ksps

VREF = Ext ref

No load

Normal mode 1.9

Low Power mode 1.1

High Speed Mode 330

µA

Low Power Mode 130

DMA 615KBps between I/O registers and SRAM 115 µA

Timer/Counter 16 µA

USART Rx and Tx enabled, 9600 BAUD 2.5 µA

Flash memory and EEPROM programming 4mA

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.2.4 Wake-up time from sleep modes

Table 36-38. Device wake-up time from sleep modes with various system clock sources.

Note: 1. The wake-up time is the time from the wake-up request is given until the peripheral clock is available on pin, see Figure 36-2. All peripherals and modules

start execution from the first clock cycle, expect the CPU that is halted for four clock cycles before program execution starts.

Figure 36-9. Wake-up time definition.

Symbol Parameter Condition Min. Typ. (1) Max. Units

twakeup

Wake-up time from Idle,

Standby, and Extended Standby

mode

External 2MHz clock 2

µs

32.768kHz internal oscillator 120

2MHz internal oscillator 2

32MHz internal oscillator 0.2

Wake-up time from Power-save

and Power-down mode

External 2MHz clock 4.5

µs

32.768kHz internal oscillator 320

2MHz internal oscillator 9

32MHz internal oscillator 5

Wakeup request

Clock output

Wakeup time

100

XMEGA A3U [DATASHEET]

Atmel-8386E-AVR-XMEGA A3U-Datasheet_09/2014

36.2.5 I/O Pin Characteristics

The I/O pins comply with the JEDEC LVTTL and LVCMOS specification and the high- and low level input and

output voltage limits reflect or exceed this specification.

Table 36-39. I/O pin characteristics.