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Programmers and Debuggers

Atmel-ICE

USER GUIDE

The Atmel-ICE Debugger

Atmel-ICE is a powerful development tool for debugging and programming

ARM® Cortex®-M based Atmel® SAM and Atmel AVR® microcontrollers with

On-Chip Debug capability.

It supports:

•Programming and on-chip debugging of all Atmel AVR 32-bit

microcontrollers on both JTAG and aWire interfaces

•Programming and on-chip debugging of all Atmel AVR XMEGA® family

devices on both JTAG and PDI 2-wire interfaces

•Programming (JTAG and SPI) and debugging of all Atmel AVR 8-bit

microcontrollers with OCD support on either JTAG or debugWIRE

interfaces

•Programming and debugging of all Atmel SAM ARM Cortex-M based

microcontrollers on both SWD and JTAG interfaces

•Programming (TPI) of all Atmel tinyAVR® 8-bit microcontrollers with

support for this interface

Consult the supported devices list in the Atmel Studio User Guide for a full

list of devices and interfaces supported by this firmware release.

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Table of Contents

The Atmel-ICE Debugger................................................................................................ 1

1. Introduction................................................................................................................5

1.1. Introduction to the Atmel-ICE....................................................................................................... 5

1.2. Atmel-ICE Features......................................................................................................................5

1.3. System Requirements.................................................................................................................. 5

2. Getting Started with the Atmel-ICE............................................................................7

2.1. Full Kit Contents........................................................................................................................... 7

2.2. Basic Kit Contents........................................................................................................................ 7

2.3. PCBA Kit Contents....................................................................................................................... 8

2.4. Spare Parts Kits............................................................................................................................8

2.5. Kit Overview................................................................................................................................. 9

2.6. Assembling the Atmel-ICE..........................................................................................................10

2.7. Opening the Atmel-ICE...............................................................................................................11

2.8. Powering the Atmel-ICE............................................................................................................. 13

2.9. Connecting to the Host Computer.............................................................................................. 13

2.10. USB Driver Installation............................................................................................................... 13

2.10.1. Windows...................................................................................................................... 13

3. Connecting the Atmel-ICE....................................................................................... 15

3.1. Connecting to AVR and SAM Target Devices.............................................................................15

3.2. Connecting to a JTAG Target..................................................................................................... 16

3.3. Connecting to an aWire Target...................................................................................................17

3.4. Connecting to a PDI Target........................................................................................................ 18

3.5. Connecting to a debugWIRE Target...........................................................................................18

3.6. Connecting to an SPI Target...................................................................................................... 20

3.7. Connecting to a TPI Target.........................................................................................................21

3.8. Connecting to an SWD Target....................................................................................................21

3.9. Connecting to Data Gateway Interface...................................................................................... 22

4. On-chip Debugging..................................................................................................24

4.1. Introduction.................................................................................................................................24

4.2. SAM Devices with JTAG/SWD................................................................................................... 24

4.2.1. ARM CoreSight Components...................................................................................... 24

4.2.2. JTAG Physical Interface...............................................................................................25

4.2.3. Connecting to a JTAG Target.......................................................................................27

4.2.4. SWD Physical Interface............................................................................................... 28

4.2.5. Connecting to an SWD Target..................................................................................... 28

4.2.6. Special Considerations................................................................................................ 29

4.3. AVR UC3 Devices with JTAG/aWire...........................................................................................30

4.3.1. Atmel AVR UC3 On-chip Debug System..................................................................... 30

4.3.2. JTAG Physical Interface...............................................................................................30

4.3.3. Connecting to a JTAG Target.......................................................................................33

4.3.4. aWire Physical Interface.............................................................................................. 34

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4.3.5. Connecting to an aWire Target.................................................................................... 34

4.3.6. Special Considerations................................................................................................ 35

4.3.7. EVTI / EVTO Usage.....................................................................................................35

4.4. tinyAVR, megaAVR, and XMEGA Devices.................................................................................36

4.4.1. JTAG Physical Interface...............................................................................................37

4.4.2. Connecting to a JTAG Target.......................................................................................37

4.4.3. SPI Physical Interface..................................................................................................38

4.4.4. Connecting to an SPI Target........................................................................................38

4.4.5. PDI Physical Interface................................................................................................. 39

4.4.6. Connecting to a PDI Target..........................................................................................40

4.4.7. TPI Physical Interface..................................................................................................40

4.4.8. Connecting to a TPI Target.......................................................................................... 41

4.4.9. Advanced Debugging (AVR JTAG /debugWIRE devices)........................................... 41

4.4.10. megaAVR Special Considerations............................................................................... 42

4.4.11. AVR XMEGA Special Considerations.......................................................................... 43

4.4.12. debugWIRE Special Considerations............................................................................44

4.4.13. debugWIRE Software Breakpoints.............................................................................. 45

4.4.14. Understanding debugWIRE and the DWEN Fuse....................................................... 46

5. Hardware Description.............................................................................................. 48

5.1. LEDs...........................................................................................................................................48

5.2. Rear Panel..................................................................................................................................48

5.3. Bottom Panel..............................................................................................................................49

5.4. Architecture Description............................................................................................................. 49

5.4.1. Atmel-ICE Main Board................................................................................................. 49

5.4.2. Atmel-ICE Target Connectors...................................................................................... 50

5.4.3. Atmel-ICE Target Connectors Part Numbers...............................................................50

6. Software Integration.................................................................................................51

6.1. Atmel Studio............................................................................................................................... 51

6.1.1. Software Integration in Atmel Studio........................................................................... 51

6.1.2. Programming Options..................................................................................................51

6.1.3. Debug Options.............................................................................................................51

6.2. Command Line Utility................................................................................................................. 52

7. Advanced Debugging Techniques........................................................................... 53

7.1. Atmel AVR UC3 Targets............................................................................................................. 53

7.1.1. EVTI / EVTO Usage.....................................................................................................53

7.2. debugWIRE Targets................................................................................................................... 53

7.2.1. debugWIRE Software Breakpoints.............................................................................. 53

8. Release History and Known issues......................................................................... 55

8.1. Firmware Release History.......................................................................................................... 55

8.2. Known Issues Concerning the Atmel-ICE.................................................................................. 55

8.2.1. General........................................................................................................................ 55

8.2.2. Atmel AVR XMEGA OCD Specific Issues....................................................................55

8.2.3. Atmel AVR - Device Specific Issues............................................................................ 55

9. Product Compliance................................................................................................ 56

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9.1. RoHS and WEEE....................................................................................................................... 56

9.2. CE and FCC............................................................................................................................... 56

10. Revision History.......................................................................................................57

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1. Introduction

1.1. Introduction to the Atmel-ICE

Atmel-ICE is a powerful development tool for debugging and programming ARM Cortex-M based Atmel

SAM and Atmel AVR microcontrollers with On-Chip Debug capability.

It supports:

•Programming and on-chip debugging of all Atmel AVR UC3 microcontrollers on both JTAG and

aWire interfaces

•Programming and on-chip debugging of all AVR XMEGA family devices on both JTAG and PDI 2-

wire interfaces

•Programming (JTAG and SPI) and debugging of all AVR 8-bit microcontrollers with OCD support on

both JTAG or debugWIRE interfaces

•Programming and debugging of all Atmel SAM ARM Cortex-M based microcontrollers on both SWD

and JTAG interfaces

•Programming (TPI) of all Atmel tinyAVR 8-bit microcontrollers with support for this interface

1.2. Atmel-ICE Features

•Fully compatible with Atmel Studio

•Supports programming and debugging of all Atmel AVR UC3 32-bit microcontrollers

•Supports programming and debugging of all 8-bit AVR XMEGA devices

•Supports programming and debugging of all 8-bit Atmel megaAVR® and tinyAVR devices with OCD

•Supports programming and debugging of all SAM ARM Cortex-M based microcontrollers

•Target operating voltage range of 1.62V to 5.5V

•Draws less than 3mA from target VTref when using debugWIRE interface and less than 1mA for all

other interfaces

•Supports JTAG clock frequencies from 32kHz to 7.5MHz

•Supports PDI clock frequencies from 32kHz to 7.5MHz

•Supports debugWIRE baud rates from 4kbit/s to 0.5Mbit/s

•Supports aWire baud rates from 7.5kbit/s to 7Mbit/s

•Supports SPI clock frequencies from 8kHz to 5MHz

•Supports SWD clock frequencies from 32kHz to 10MHz

•USB 2.0 high-speed host interface

•ITM serial trace capture at up to 3MB/s

•Supports DGI SPI and USART interfaces when not debugging or programming

•Supports 10-pin 50-mil JTAG connector with both AVR and Cortex pinouts. The standard probe

cable supports AVR 6-pin ISP/PDI/TPI 100-mil headers as well as 10-pin 50-mil. An adapter is

available to support 6-pin 50-mil, 10-pin 100-mil, and 20-pin 100-mil headers. Several kit options

are available with different cabling and adapters.

1.3. System Requirements

The Atmel-ICE unit requires that a front-end debugging environment Atmel Studio version 6.2 or later is

installed on your computer.

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The Atmel-ICE should be connected to the host computer using the USB cable provided, or a certified

Micro-USB cable.

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2. Getting Started with the Atmel-ICE

2.1. Full Kit Contents

The Atmel-ICE full kit contains these items:

•Atmel-ICE unit

•USB cable (1.8m, high-speed, Micro-B)

•Adapter board containing 50-mil AVR, 100-mil AVR/SAM, and 100-mil 20-pin SAM adapters

•IDC flat cable with 10-pin 50-mil connector and 6-pin 100-mil connector

•50-mil 10-pin mini squid cable with 10 x 100-mil sockets

Figure 2-1. Atmel-ICE Full Kit Contents

2.2. Basic Kit Contents

The Atmel-ICE basic kit contains these items:

•Atmel-ICE unit

•USB cable (1.8m, high-speed, Micro-B)

•IDC flat cable with 10-pin 50-mil connector and 6-pin 100-mil connector

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Figure 2-2. Atmel-ICE Basic Kit Contents

2.3. PCBA Kit Contents

The Atmel-ICE PCBA kit contains these items:

•Atmel-ICE unit without plastic encapsulation

Figure 2-3. Atmel-ICE PCBA Kit Contents

2.4. Spare Parts Kits

The following spare parts kits are available:

•Adapter kit

•Cable kit

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Figure 2-4. Atmel-ICE Adapter Kit Contents

Figure 2-5. Atmel-ICE Cable Kit Contents

2.5. Kit Overview

The Atmel-ICE kit options are shown diagrammatically here:

Figure 2-6. Atmel-ICE Kit Overview

PCBA

PCBA kit

basic kit

adapter kit

full kit

SAM AVR

cable kit

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2.6. Assembling the Atmel-ICE

The Atmel-ICE unit is shipped with no cables attached. Two cable options are provided in the full kit:

•50-mil 10-pin IDC flat cable with 6-pin ISP and 10-pin connectors

•50-mil 10-pin mini-squid cable with 10 x 100-mil sockets

Figure 2-7. Atmel-ICE Cables

For most purposes, the 50-mil 10-pin IDC flat cable can be used, connecting either natively to its 10-pin

or 6-pin connectors, or connecting via the adapter board. Three adapters are provided on one small

PCBA. The following adapters are included:

•100-mil 10-pin JTAG/SWD adapter

•100-mil 20-pin SAM JTAG/SWD adapter

•50-mil 6-pin SPI/debugWIRE/PDI/aWire adapter

Figure 2-8. Atmel-ICE Adapters

Note:

A 50-mil JTAG adapter has not been provided - this is because the 50-mil 10-pin IDC cable can be used

to connect directly to a 50-mil JTAG header. For the part number of the component used for the 50-mil

10-pin connector, see Atmel-ICE Target Connectors Part Numbers.

The 6-pin ISP/PDI header is included as part of the 10-pin IDC cable. This termination can be cut off if it

is not required.

To assemble your Atmel-ICE into its default configuration, connect the 10-pin 50-mil IDC cable to the unit

as shown below. Be sure to orient the cable so that the red wire (pin 1) on the cable aligns with the

triangular indicator on the blue belt of the enclosure. The cable should connect upwards from the unit. Be

sure to connect to the port corresponding to the pinout of your target - AVR or SAM.

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Figure 2-9. Atmel-ICE Cable Connection

Figure 2-10. Atmel-ICE AVR Probe Connection

Figure 2-11. Atmel-ICE SAM Probe Connection

2.7. Opening the Atmel-ICE

Note:

For normal operation, the Atmel-ICE unit must not be opened. Opening the unit is done at your own risk.

Anti-static precautions should be taken.

The Atmel-ICE enclosure consists of three separate plastic components - top cover, bottom cover, and

blue belt - which are snapped together during assembly. To open the unit, simply insert a large flat

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screwdriver into the openings in the blue belt, apply some inward pressure and twist gently. Repeat the

process on the other snapper holes, and the top cover will pop off.

Figure 2-12. Opening the Atmel-ICE (1)

Figure 2-13. Opening the Atmel-ICE (2)

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Figure 2-14. Opening the Atmel-ICE(3)

To close the unit again, simply align the top and bottom covers correctly, and press firmly together.

2.8. Powering the Atmel-ICE

The Atmel-ICE is powered by the USB bus voltage. It requires less than 100mA to operate, and can

therefore be powered through a USB hub. The power LED will illuminate when the unit is plugged in.

When not connected in an active programming or debugging session, the unit will enter low-power

consumption mode to preserve your computer's battery. The Atmel-ICE cannot be powered down - it

should be unplugged when not in use.

2.9. Connecting to the Host Computer

The Atmel-ICE communicates primarily using a standard HID interface, and does not require a special

driver on the host computer. To use the advanced Data Gateway functionality of the Atmel-ICE, be sure to

install the USB driver on the host computer. This is done automatically when installing the front-end

software provided free by Atmel. See www.atmel.com for further information or to download the latest

front-end software.

The Atmel-ICE must be connected to an available USB port on the host computer using the USB cable

provided, or suitable USB certified micro cable. The Atmel-ICE contains a USB 2.0 compliant controller,

and can operate in both full-speed and high-speed modes. For best results, connect the Atmel-ICE

directly to a USB 2.0 compliant high-speed hub on the host computer using the cable provided.

2.10. USB Driver Installation

2.10.1. Windows

When installing the Atmel-ICE on a computer running Microsoft® Windows®, the USB driver is loaded

when the Atmel-ICE is first plugged in.

Note:

Be sure to install the front-end software packages before plugging the unit in for the first time.

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Once successfully installed, the Atmel-ICE will appear in the device manager as a "Human Interface

Device".

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3. Connecting the Atmel-ICE

3.1. Connecting to AVR and SAM Target Devices

The Atmel-ICE is equipped with two 50-mil 10-pin JTAG connectors. Both connectors are directly

electrically connected, but conform to two different pinouts; the AVR JTAG header and the ARM Cortex

Debug header. The connector should be selected based on the pinout of the target board, and not the

target MCU type - for example a SAM device mounted in an AVR STK®600 stack should use the AVR

header.

Various cabling and adapters are available in the different Atmel-ICE kits. An overview of connection

options is shown.

Figure 3-1. Atmel-ICE Connection Options

6-pin 100-mil AVR ISP/

debugWIRE/PDI/aWire/

TPI header

10-pin 100-mil AVR

JTAG header

10-pin 50-mil AVR

JTAG header

SAM AVR

20-pin 100-mil SAM

header

(for EVKs etc)

10-pin 100-mil

JTAG/SWD header

10-pin 50-mil JTAG/SWD

(Cortex debug header)

SAM AVR

6-pin 50-mil AVR ISP/

debugWIRE/PDI/aWire/

TPI header

The red wire marks pin 1 of the 10-pin 50-mil connector. Pin 1 of the 6-pin 100-mil connector is placed to

the right of the keying when the connector is seen from the cable. Pin 1 of each connector on the adapter

is marked with a white dot. The figure below shows the pinout of the debug cable. The connector marked

A plugs into the debugger while the B side plugs into the target board.

Figure 3-2. Debug Cable Pinout

A B

1 2

9 1 2

9 10

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3.2. Connecting to a JTAG Target

The Atmel-ICE is equipped with two 50-mil 10-pin JTAG connectors. Both connectors are directly

electrically connected, but conform to two different pinouts; the AVR JTAG header and the ARM Cortex

Debug header. The connector should be selected based on the pinout of the target board, and not the

target MCU type - for example a SAM device mounted in an AVR STK600 stack should use the AVR

header.

The recommended pinout for the 10-pin AVR JTAG connector is shown in Figure 4-6 AVR JTAG Header

Pinout.

The recommended pinout for the 10-pin ARM Cortex Debug connector is shown in Figure 4-2 SAM JTAG

Header Pinout.

Direct connection to a standard 10-pin 50-mil header

Use the 50-mil 10-pin flat cable (included in some kits) to connect directly to a board supporting this

header type. Use the AVR connector port on the Atmel-ICE for headers with the AVR pinout, and the SAM

connector port for headers complying with the ARM Cortex Debug header pinout.

The pinouts for both 10-pin connector ports are shown below.

Connection to a standard 10-pin 100-mil header

Use a standard 50-mil to 100-mil adapter to connect to 100-mil headers. An adapter board (included in

some kits) can be used for this purpose, or alternatively the JTAGICE3 adapter can be used for AVR

targets.

Important:

The JTAGICE3 100-mil adapter cannot be used with the SAM connector port, since pins 2 and

10 (AVR GND) on the adapter are connected.

Connection to a custom 100-mil header

If your target board does not have a compliant 10-pin JTAG header in 50- or 100-mil, you can map to a

custom pinout using the 10-pin "mini-squid" cable (included in some kits), which gives access to ten

individual 100-mil sockets.

Connection to a 20-pin 100-mil header

Use the adapter board (included in some kits) to connect to targets with a 20-pin 100-mil header.

Table 3-1. Atmel-ICE JTAG Pin Description

Name AVR

port

SAM

port

Description

TCK 1 4 Test Clock (clock signal from the Atmel-ICE into the target device).

TMS 5 2 Test Mode Select (control signal from the Atmel-ICE into the target device).

TDI 9 8 Test Data In (data transmitted from the Atmel-ICE into the target device).

TDO 3 6 Test Data Out (data transmitted from the target device into the Atmel-ICE).

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Name AVR

port

SAM

port

Description

nTRST 8 - Test Reset (optional, only on some AVR devices). Used to reset the JTAG

TAP controller.

nSRST 6 10 Reset (optional). Used to reset the target device. Connecting this pin is

recommended since it allows the Atmel-ICE to hold the target device in a

reset state, which can be essential to debugging in certain scenarios.

VTG 4 1 Target voltage reference. The Atmel-ICE samples the target voltage on this

pin in order to power the level converters correctly. The Atmel-ICE draws

less than 3mA from this pin in debugWIRE mode and less than 1mA in

other modes.

GND 2, 10 3, 5, 9 Ground. All must be connected to ensure that the Atmel-ICE and the target

device share the same ground reference.

3.3. Connecting to an aWire Target

The aWire interface requires only one data line in addition to VCC and GND. On the target this line is the

nRESET line, although the debugger uses the JTAG TDO line as the data line.

The recommended pinout for the 6-pin aWire connector is shown in Figure 4-8 aWire Header Pinout.

Connection to a 6-pin 100-mil aWire header

Use the 6-pin 100-mil tap on the flat cable (included in some kits) to connect to a standard 100-mil aWire

header.

Connection to a 6-pin 50-mil aWire header

Use the adapter board (included in some kits) to connect to a standard 50-mil aWire header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR connector port and

the target board. Three connections are required, as described in the table below.

Table 3-2. Atmel-ICE aWire Pin Mapping

Atmel-ICE AVR port pins Target pins Mini-squid pin aWire pinout

Pin 1 (TCK) 1

Pin 2 (GND) GND 2 6

Pin 3 (TDO) DATA 3 1

Pin 4 (VTG) VTG 4 2

Pin 5 (TMS) 5

Pin 6 (nSRST) 6

Pin 7 (Not connected) 7

Pin 8 (nTRST) 8

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Atmel-ICE AVR port pins Target pins Mini-squid pin aWire pinout

Pin 9 (TDI) 9

Pin 10 (GND) 0

3.4. Connecting to a PDI Target

The recommended pinout for the 6-pin PDI connector is shown in Figure 4-11 PDI Header Pinout.

Connection to a 6-pin 100-mil PDI header

Use the 6-pin 100-mil tap on the flat cable (included in some kits) to connect to a standard 100-mil PDI

header.

Connection to a 6-pin 50-mil PDI header

Use the adapter board (included in some kits) to connect to a standard 50-mil PDI header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR connector port and

the target board. Four connections are required, as described in the table below.

Important:

The pinout required is different from the JTAGICE mkII JTAG probe, where PDI_DATA is

connected to pin 9. The Atmel-ICE is compatible with the pinout used by the Atmel-ICE,

JTAGICE3, AVR ONE!, and AVR Dragon™ products.

Table 3-3. Atmel-ICE PDI Pin Mapping

Atmel-ICE AVR port pin Target pins Mini-squid pin Atmel STK600 PDI pinout

Pin 1 (TCK) 1

Pin 2 (GND) GND 2 6

Pin 3 (TDO) PDI_DATA 3 1

Pin 4 (VTG) VTG 4 2

Pin 5 (TMS) 5

Pin 6 (nSRST) PDI_CLK 6 5

Pin 7 (not connected) 7

Pin 8 (nTRST) 8

Pin 9 (TDI) 9

Pin 10 (GND) 0

3.5. Connecting to a debugWIRE Target

The recommended pinout for the 6-pin debugWIRE (SPI) connector is shown in Table 3-5 Atmel-ICE SPI

Pin Mapping.

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Connection to a 6-pin 100-mil SPI header

Use the 6-pin 100-mil tap on the flat cable (included in some kits) to connect to a standard 100-mil SPI

header.

Connection to a 6-pin 50-mil SPI header

Use the adapter board (included in some kits) to connect to a standard 50-mil SPI header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR connector port and

the target board. Three connections are required, as described in Table 3-4 Atmel-ICE debugWIRE Pin

Mapping.

Although the debugWIRE interface only requires one signal line (RESET), VCC and GND to operate

correctly, it is advised to have access to the full SPI connector so that the debugWIRE interface can be

enabled and disabled using SPI programming.

When the DWEN fuse is enabled the SPI interface is overridden internally in order for the OCD module to

have control over the RESET pin. The debugWIRE OCD is capable of disabling itself temporarily (using

the button on the debugging tab in the properties dialog in Atmel Studio), thus releasing control of the

RESET line. The SPI interface is then available again (only if the SPIEN fuse is programmed), allowing

the DWEN fuse to be un-programmed using the SPI interface. If power is toggled before the DWEN fuse

is un-programmed, the debugWIRE module will again take control of the RESET pin.

Note:

It is highly advised to simply let Atmel Studio handle setting and clearing of the DWEN fuse.

It is not possible to use the debugWIRE interface if the lockbits on the target AVR device are

programmed. Always be sure that the lockbits are cleared before programming the DWEN fuse and never

set the lockbits while the DWEN fuse is programmed. If both the debugWIRE enable fuse (DWEN) and

lockbits are set, one can use High Voltage Programming to do a chip erase, and thus clear the lockbits.

When the lockbits are cleared the debugWIRE interface will be re-enabled. The SPI Interface is only

capable of reading fuses, reading signature and performing a chip erase when the DWEN fuse is un-

programmed.

Table 3-4. Atmel-ICE debugWIRE Pin Mapping

Atmel-ICE AVR port pin Target pins Mini-squid pin

Pin 1 (TCK) 1

Pin 2 (GND) GND 2

Pin 3 (TDO) 3

Pin 4 (VTG) VTG 4

Pin 5 (TMS) 5

Pin 6 (nSRST) RESET 6

Pin 7 (Not connected) 7

Pin 8 (nTRST) 8

Pin 9 (TDI) 9

Pin 10 (GND) 0

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3.6. Connecting to an SPI Target

The recommended pinout for the 6-pin SPI connector is shown in Figure 4-10 SPI Header Pinout.

Connection to a 6-pin 100-mil SPI header

Use the 6-pin 100-mil tap on the flat cable (included in some kits) to connect to a standard 100-mil SPI

header.

Connection to a 6-pin 50-mil SPI header

Use the adapter board (included in some kits) to connect to a standard 50-mil SPI header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR connector port and

the target board. Six connections are required, as described in the table below.

Important:

The SPI interface is effectively disabled when the debugWIRE enable fuse (DWEN) is

programmed, even if SPIEN fuse is also programmed. To re-enable the SPI interface, the

'disable debugWIRE' command must be issued while in a debugWIRE debugging session.

Disabling debugWIRE in this manner requires that the SPIEN fuse is already programmed. If

Atmel Studio fails to disable debugWIRE, it is probable because the SPIEN fuse is NOT

programmed. If this is the case, it is necessary to use a high-voltage programming interface to

program the SPIEN fuse.

Info:

The SPI interface is often referred to as "ISP", since it was the first In System Programming

interface on Atmel AVR products. Other interfaces are now available for In System

Programming.

Table 3-5. Atmel-ICE SPI Pin Mapping

Atmel-ICE AVR port pins Target pins Mini-squid pin SPI pinout

Pin 1 (TCK) SCK 1 3

Pin 2 (GND) GND 2 6

Pin 3 (TDO) MISO 3 1

Pin 4 (VTG) VTG 4 2

Pin 5 (TMS) 5

Pin 6 (nSRST) /RESET 6 5

Pin 7 (not connected) 7

Pin 8 (nTRST) 8

Pin 9 (TDI) MOSI 9 4

Pin 10 (GND) 0

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3.7. Connecting to a TPI Target

The recommended pinout for the 6-pin TPI connector is shown in Figure 4-12 TPI Header Pinout.

Connection to a 6-pin 100-mil TPI header

Use the 6-pin 100-mil tap on the flat cable (included in some kits) to connect to a standard 100-mil TPI

header.

Connection to a 6-pin 50-mil TPI header

Use the adapter board (included in some kits) to connect to a standard 50-mil TPI header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR connector port and

the target board. Six connections are required, as described in Table 3-6 Atmel-ICE TPI Pin Mapping.

Table 3-6. Atmel-ICE TPI Pin Mapping

Atmel-ICE AVR port pins Target pins Mini-squid pin TPI pinout

Pin 1 (TCK) CLOCK 1 3

Pin 2 (GND) GND 2 6

Pin 3 (TDO) DATA 3 1

Pin 4 (VTG) VTG 4 2

Pin 5 (TMS) 5

Pin 6 (nSRST) /RESET 6 5

Pin 7 (not connected) 7

Pin 8 (nTRST) 8

Pin 9 (TDI) 9

Pin 10 (GND) 0

3.8. Connecting to an SWD Target

The ARM SWD interface is a subset of the JTAG interface, making use of the TCK and TMS pins, which

means that when connecting to an SWD device, the 10-pin JTAG connector can technically be used. The

ARM JTAG and AVR JTAG connectors are however not pin-compatible, so this depends upon the layout

of the target board in use. When using an STK600 or a board making use of the AVR JTAG pinout, the

AVR connector port on the Atmel-ICE must be used. When connecting to a board which makes use of the

ARM JTAG pinout, the SAM connector port on the Atmel-ICE must be used.

The recommended pinout for the 10-pin Cortex Debug connector is shown in Figure 4-4 Recommended

ARM SWD/JTAG Header Pinout.

Connection to a 10-pin 50-mil Cortex header

Use the flat cable (included in some kits) to connect to a standard 50-mil Cortex header.

Connection to a 10-pin 100-mil Cortex-layout header

Use the adapter board (included in some kits) to connect to a 100-mil Cortex-pinout header.

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Connection to a 20-pin 100-mil SAM header

Use the adapter board (included in some kits) to connect to a 20-pin 100-mil SAM header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR or SAM connector

port and the target board. Six connections are required, as described in the table below.

Table 3-7. Atmel-ICE SWD Pin Mapping

Name AVR

port

SAM

port

Description

SWDC

1 4 Serial Wire Debug Clock.

SWDIO 5 2 Serial Wire Debug Data Input/Output.

SWO 3 6 Serial Wire Output (optional- not implemented on all devices).

nSRST 6 10 Reset.

VTG 4 1 Target voltage reference.

GND 2, 10 3, 5, 9 Ground.

3.9. Connecting to Data Gateway Interface

The Atmel-ICE supports a limited Data Gateway Interface (DGI) when debugging and programming is not

in use. Functionality is identical to that found on Atmel Xplained Pro kits powered by the Atmel EDBG

device.

The Data Gateway Interface is an interface for streaming data from the target device to a computer. This

is meant as an aid in application debugging as well as for demonstration of features in the application

running on the target device.

DGI consists of multiple channels for data streaming. The Atmel-ICE supports the following modes:

•USART

•SPI

Table 3-8. Atmel-ICE DGI USART Pinout

AVR port SAM port DGI USART pin Description

3 6 TX Transmit pin from Atmel-ICE to the target device

4 1 VTG Target voltage (reference voltage)

8 7 RX Receive pin from the target device to Atmel-ICE

9 8 CLK USART clock

2, 10 3, 5, 9 GND Ground

Table 3-9. Atmel-ICE DGI SPI Pinout

AVR port SAM port DGI SPI pin Description

1 4 SCK SPI clock

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3 6 MISO Master In Slave Out

4 1 VTG Target voltage (reference voltage)

5 2 nCS Chip select active low

9 8 MOSI Master Out Slave In

2, 10 3, 5, 9 GND Ground

Important: SPI and USART interfaces can not be used simultaneously.

Important: DGI and programming or debugging cannot be used simultaneously.

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4. On-chip Debugging

4.1. Introduction

On-chip Debugging

An on-chip debug module is a system allowing a developer to monitor and control execution on a device

from an external development platform, usually through a device known as a debugger or debug adapter.

With an OCD system the application can be executed whilst maintaining exact electrical and timing

characteristics in the target system, while being able to stop execution conditionally or manually and

inspect program flow and memory.

Run Mode

When in Run mode, the execution of code is completely independent of the Atmel-ICE. The Atmel-ICE

will continuously monitor the target device to see if a break condition has occurred. When this happens

the OCD system will interrogate the device through its debug interface, allowing the user to view the

internal state of the device.

Stopped Mode

When a breakpoint is reached, the program execution is halted, but some I/O may continue to run as if no

breakpoint had occurred. For example, assume that a USART transmit has just been initiated when a

breakpoint is reached. In this case the USART continues to run at full speed completing the transmission,

even though the core is in stopped mode.

Hardware Breakpoints

The target OCD module contains a number of program counter comparators implemented in the

hardware. When the program counter matches the value stored in one of the comparator registers, the

OCD enters stopped mode. Since hardware breakpoints require dedicated hardware on the OCD module,

the number of breakpoints available depends upon the size of the OCD module implemented on the

target. Usually one such hardware comparator is ‘reserved’ by the debugger for internal use.

Software Breakpoints

A software breakpoint is a BREAK instruction placed in program memory on the target device. When this

instruction is loaded, program execution will break and the OCD enters stopped mode. To continue

execution a "start" command has to be given from the OCD. Not all Atmel devices have OCD modules

supporting the BREAK instruction.

4.2. SAM Devices with JTAG/SWD

All SAM devices feature the SWD interface for programming and debugging. In addition, some SAM

devices feature a JTAG interface with identical functionality. Check the device datasheet for supported

interfaces of that device.

4.2.1. ARM CoreSight Components

Atmel ARM Cortex-M based microcontrollers implement CoreSight compliant OCD components. The

features of these components can vary from device to device. For further information consult the device's

datasheet as well as CoreSight documentation provided by ARM.

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4.2.2. JTAG Physical Interface

The JTAG interface consists of a 4-wire Test Access Port (TAP) controller that is compliant with the IEEE®

1149.1 standard. The IEEE standard was developed to provide an industry-standard way to efficiently test

circuit board connectivity (Boundary Scan). Atmel AVR and SAM devices have extended this functionality

to include full Programming and On-chip Debugging support.

Figure 4-1. JTAG Interface Basics

Vcc

TMS

TDI

TDO

TCK

programmer /

debugger

Atmel

target

device

4.2.2.1. SAM JTAG Pinout (Cortex-M debug connector)

When designing an application PCB which includes an Atmel SAM with the JTAG interface, it is

recommended to use the pinout as shown in Figure 4-2 SAM JTAG Header Pinout. Both 100-mil and 50-

mil variants of this pinout are supported, depending on the cabling and adapters included with the

particular kit.

Figure 4-2. SAM JTAG Header Pinout

TMS

TCK

TDO

TDI

nRESET

VCC

GND

(KEY)

GND

1 2

SAM JTAG

Table 4-1. SAM JTAG Pin Description

Name Pin Description

TCK 4 Test Clock (clock signal from the Atmel-ICE into the target device).

TMS 2 Test Mode Select (control signal from the Atmel-ICE into the target device).

TDI 8 Test Data In (data transmitted from the Atmel-ICE into the target device).

TDO 6 Test Data Out (data transmitted from the target device into the Atmel-ICE).

nRESET 10 Reset (optional). Used to reset the target device. Connecting this pin is

recommended since it allows the Atmel-ICE to hold the target device in a reset

state, which can be essential to debugging in certain scenarios.

VTG 1 Target voltage reference. The Atmel-ICE samples the target voltage on this pin in

order to power the level converters correctly. The Atmel-ICE draws less than 1mA

from this pin in this mode.

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Name Pin Description

GND 3, 5, 9 Ground. All must be connected to ensure that the Atmel-ICE and the target device

share the same ground reference.

KEY 7 Connected internally to the TRST pin on the AVR connector. Recommended as not

connected.

Tip: Remember to include a decoupling capacitor between pin 1 and GND.

4.2.2.2. JTAG Daisy Chaining

The JTAG interface allows for several devices to be connected to a single interface in a daisy chain

configuration. The target devices must all be powered by the same supply voltage, share a common

ground node, and must be connected as shown in the figure below.

Figure 4-3. JTAG Daisy Chain

TMS

TDI

TDO

TCK

target

device

target

device

target

device

programmer /

debugger

When connecting devices in a daisy chain, the following points must be considered:

•All devices must share a common ground, connected to GND on the Atmel-ICE probe

•All devices must be operating on the same target voltage. VTG on the Atmel-ICE must be

connected to this voltage.

•TMS and TCK are connected in parallel; TDI and TDO are connected in a serial chain.

•nSRST on the Atmel-ICE probe must be connected to RESET on the devices if any of the devices

in the chain disables its JTAG port

•"Devices before" refers to the number of JTAG devices that the TDI signal has to pass through in

the daisy chain before reaching the target device. Similarly "devices after" is the number of devices

that the signal has to pass through after the target device before reaching the Atmel-ICE TDO pin.

•"Instruction bits "before" and "after" refers to the total sum of all JTAG devices' instruction register

lengths, which are connected before and after the target device in the daisy chain

•The total IR length (instruction bits before + Atmel target device IR length + instruction bits after) is

limited to a maximum of 256 bits. The number of devices in the chain is limited to 15 before and 15

after.

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Tip:

Daisy chaining example: TDI → ATmega1280 → ATxmega128A1 → ATUC3A0512 → TDO.

In order to connect to the Atmel AVR XMEGA® device, the daisy chain settings are:

•Devices before: 1

•Devices after: 1

•Instruction bits before: 4 (8-bit AVR devices have 4 IR bits)

•Instruction bits after: 5 (32-bit AVR devices have 5 IR bits)

Table 4-2. IR Lengths of Atmel MCUs

Device type IR length

AVR 8-bit 4 bits

AVR 32-bit 5 bits

SAM 4 bits

4.2.3. Connecting to a JTAG Target

The Atmel-ICE is equipped with two 50-mil 10-pin JTAG connectors. Both connectors are directly

electrically connected, but conform to two different pinouts; the AVR JTAG header and the ARM Cortex

Debug header. The connector should be selected based on the pinout of the target board, and not the

target MCU type - for example a SAM device mounted in an AVR STK600 stack should use the AVR

header.

The recommended pinout for the 10-pin AVR JTAG connector is shown in Figure 4-6 AVR JTAG Header

Pinout.

The recommended pinout for the 10-pin ARM Cortex Debug connector is shown in Figure 4-2 SAM JTAG

Header Pinout.

Direct connection to a standard 10-pin 50-mil header

Use the 50-mil 10-pin flat cable (included in some kits) to connect directly to a board supporting this

header type. Use the AVR connector port on the Atmel-ICE for headers with the AVR pinout, and the SAM

connector port for headers complying with the ARM Cortex Debug header pinout.

The pinouts for both 10-pin connector ports are shown below.

Connection to a standard 10-pin 100-mil header

Use a standard 50-mil to 100-mil adapter to connect to 100-mil headers. An adapter board (included in

some kits) can be used for this purpose, or alternatively the JTAGICE3 adapter can be used for AVR

targets.

Important:

The JTAGICE3 100-mil adapter cannot be used with the SAM connector port, since pins 2 and

10 (AVR GND) on the adapter are connected.

Connection to a custom 100-mil header

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If your target board does not have a compliant 10-pin JTAG header in 50- or 100-mil, you can map to a

custom pinout using the 10-pin "mini-squid" cable (included in some kits), which gives access to ten

individual 100-mil sockets.

Connection to a 20-pin 100-mil header

Use the adapter board (included in some kits) to connect to targets with a 20-pin 100-mil header.

Table 4-3. Atmel-ICE JTAG Pin Description

Name AVR

port

SAM

port

Description

TCK 1 4 Test Clock (clock signal from the Atmel-ICE into the target device).

TMS 5 2 Test Mode Select (control signal from the Atmel-ICE into the target device).

TDI 9 8 Test Data In (data transmitted from the Atmel-ICE into the target device).

TDO 3 6 Test Data Out (data transmitted from the target device into the Atmel-ICE).

nTRST 8 - Test Reset (optional, only on some AVR devices). Used to reset the JTAG

TAP controller.

nSRST 6 10 Reset (optional). Used to reset the target device. Connecting this pin is

recommended since it allows the Atmel-ICE to hold the target device in a

reset state, which can be essential to debugging in certain scenarios.

VTG 4 1 Target voltage reference. The Atmel-ICE samples the target voltage on this

pin in order to power the level converters correctly. The Atmel-ICE draws

less than 3mA from this pin in debugWIRE mode and less than 1mA in

other modes.

GND 2, 10 3, 5, 9 Ground. All must be connected to ensure that the Atmel-ICE and the target

device share the same ground reference.

4.2.4. SWD Physical Interface

The ARM SWD interface is a subset of the JTAG interface, making use of TCK and TMS pins. The ARM

JTAG and AVR JTAG connectors are however not pin-compatible, so when designing an application PCB,

which uses a SAM device with SWD or JTAG interface, it is recommended to use the ARM pinout shown

in Figure 4-4 Recommended ARM SWD/JTAG Header Pinout. The SAM connector port on the Atmel-ICE

can connect directly to this pinout.

Figure 4-4. Recommended ARM SWD/JTAG Header Pinout

SWDIO

SWDCLK

SWO

nRESET

VCC

GND

(KEY)

GND

1 2

SAM SWD

(NC)

The Atmel-ICE is capable of streaming UART-format ITM trace to the host computer. Trace is captured on

the TRACE/SWO pin of the 10-pin header (JTAG TDO pin). Data is buffered internally on the Atmel-ICE

and is sent over the HID interface to the host computer. The maximum reliable data rate is about 3MB/s.

4.2.5. Connecting to an SWD Target

The ARM SWD interface is a subset of the JTAG interface, making use of the TCK and TMS pins, which

means that when connecting to an SWD device, the 10-pin JTAG connector can technically be used. The

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ARM JTAG and AVR JTAG connectors are however not pin-compatible, so this depends upon the layout

of the target board in use. When using an STK600 or a board making use of the AVR JTAG pinout, the

AVR connector port on the Atmel-ICE must be used. When connecting to a board which makes use of the

ARM JTAG pinout, the SAM connector port on the Atmel-ICE must be used.

The recommended pinout for the 10-pin Cortex Debug connector is shown in Figure 4-4 Recommended

ARM SWD/JTAG Header Pinout.

Connection to a 10-pin 50-mil Cortex header

Use the flat cable (included in some kits) to connect to a standard 50-mil Cortex header.

Connection to a 10-pin 100-mil Cortex-layout header

Use the adapter board (included in some kits) to connect to a 100-mil Cortex-pinout header.

Connection to a 20-pin 100-mil SAM header

Use the adapter board (included in some kits) to connect to a 20-pin 100-mil SAM header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR or SAM connector

port and the target board. Six connections are required, as described in the table below.

Table 4-4. Atmel-ICE SWD Pin Mapping

Name AVR

port

SAM

port

Description

SWDC

1 4 Serial Wire Debug Clock.

SWDIO 5 2 Serial Wire Debug Data Input/Output.

SWO 3 6 Serial Wire Output (optional- not implemented on all devices).

nSRST 6 10 Reset.

VTG 4 1 Target voltage reference.

GND 2, 10 3, 5, 9 Ground.

4.2.6. Special Considerations

ERASE pin

Some SAM devices include an ERASE pin which is asserted to perform a complete chip erase and

unlock devices on which the security bit is set. This feature is coupled to the device itself as well as the

flash controller and is not part of the ARM core.

The ERASE pin is NOT part of any debug header, and the Atmel-ICE is thus unable to assert this signal

to unlock a device. In such cases the user should perform the erase manually before starting a debug

session.

Physical interfaces

JTAG interface

The RESET line should always be connected so that the Atmel-ICE can enable the JTAG interface.

SWD interface

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The RESET line should always be connected so that the Atmel-ICE can enable the SWD interface.

4.3. AVR UC3 Devices with JTAG/aWire

All AVR UC3 devices feature the JTAG interface for programming and debugging. In addition, some AVR

UC3 devices feature the aWire interface with identical functionality using a single wire. Check the device

datasheet for supported interfaces of that device.

4.3.1. Atmel AVR UC3 On-chip Debug System

The Atmel AVR UC3 OCD system is designed in accordance with the Nexus 2.0 standard (IEEE-ISTO

5001™-2003), which is a highly flexible and powerful open on-chip debug standard for 32-bit

microcontrollers. It supports the following features:

•Nexus compliant debug solution

•OCD supports any CPU speed

•Six program counter hardware breakpoints

•Two data breakpoints

•Breakpoints can be configured as watchpoints

•Hardware breakpoints can be combined to give break on ranges

•Unlimited number of user program breakpoints (using BREAK)

•Real-time program counter branch tracing, data trace, process trace (supported only by debuggers

with parallel trace capture port)

For more information regarding the AVR UC3 OCD system, consult the AVR32UC Technical Reference

Manuals, located on www.atmel.com/uc3.

4.3.2. JTAG Physical Interface

The JTAG interface consists of a 4-wire Test Access Port (TAP) controller that is compliant with the IEEE®

1149.1 standard. The IEEE standard was developed to provide an industry-standard way to efficiently test

circuit board connectivity (Boundary Scan). Atmel AVR and SAM devices have extended this functionality

to include full Programming and On-chip Debugging support.

Figure 4-5. JTAG Interface Basics

Vcc

TMS

TDI

TDO

TCK

programmer /

debugger

Atmel

target

device

4.3.2.1. AVR JTAG Pinout

When designing an application PCB which includes an Atmel AVR with the JTAG interface, it is

recommended to use the pinout as shown in Figure 4-6 AVR JTAG Header Pinout. Both 100-mil and 50-

mil variants of this pinout are supported, depending on the cabling and adapters included with the

particular kit.

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Figure 4-6. AVR JTAG Header Pinout

GND

VCC

/RESET

(TRST)

GND

TCK

TDO

TMS

TDI

1 2

AVR JTAG

(NC)

Table 4-5. AVR JTAG Pin Description

Name Pin Description

TCK 1 Test Clock (clock signal from the Atmel-ICE into the target device).

TMS 5 Test Mode Select (control signal from the Atmel-ICE into the target device).

TDI 9 Test Data In (data transmitted from the Atmel-ICE into the target device).

TDO 3 Test Data Out (data transmitted from the target device into the Atmel-ICE).

nTRST 8 Test Reset (optional, only on some AVR devices). Used to reset the JTAG TAP

controller.

nSRST 6 Reset (optional). Used to reset the target device. Connecting this pin is

recommended since it allows the Atmel-ICE to hold the target device in a reset

state, which can be essential to debugging in certain scenarios.

VTG 4 Target voltage reference. The Atmel-ICE samples the target voltage on this pin in

order to power the level converters correctly. The Atmel-ICE draws less than 3mA

from this pin in debugWIRE mode and less than 1mA in other modes.

GND 2, 10 Ground. Both must be connected to ensure that the Atmel-ICE and the target

device share the same ground reference.

Tip: Remember to include a decoupling capacitor between pin 4 and GND.

4.3.2.2. JTAG Daisy Chaining

The JTAG interface allows for several devices to be connected to a single interface in a daisy chain

configuration. The target devices must all be powered by the same supply voltage, share a common

ground node, and must be connected as shown in the figure below.

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Figure 4-7. JTAG Daisy Chain

TMS

TDI

TDO

TCK

target

device

target

device

target

device

programmer /

debugger

When connecting devices in a daisy chain, the following points must be considered:

•All devices must share a common ground, connected to GND on the Atmel-ICE probe

•All devices must be operating on the same target voltage. VTG on the Atmel-ICE must be

connected to this voltage.

•TMS and TCK are connected in parallel; TDI and TDO are connected in a serial chain.

•nSRST on the Atmel-ICE probe must be connected to RESET on the devices if any of the devices

in the chain disables its JTAG port

•"Devices before" refers to the number of JTAG devices that the TDI signal has to pass through in

the daisy chain before reaching the target device. Similarly "devices after" is the number of devices

that the signal has to pass through after the target device before reaching the Atmel-ICE TDO pin.

•"Instruction bits "before" and "after" refers to the total sum of all JTAG devices' instruction register

lengths, which are connected before and after the target device in the daisy chain

•The total IR length (instruction bits before + Atmel target device IR length + instruction bits after) is

limited to a maximum of 256 bits. The number of devices in the chain is limited to 15 before and 15

after.

Tip:

Daisy chaining example: TDI → ATmega1280 → ATxmega128A1 → ATUC3A0512 → TDO.

In order to connect to the Atmel AVR XMEGA® device, the daisy chain settings are:

•Devices before: 1

•Devices after: 1

•Instruction bits before: 4 (8-bit AVR devices have 4 IR bits)

•Instruction bits after: 5 (32-bit AVR devices have 5 IR bits)

Table 4-6. IR Lengths of Atmel MCUs

Device type IR length

AVR 8-bit 4 bits

AVR 32-bit 5 bits

SAM 4 bits

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4.3.3. Connecting to a JTAG Target

The Atmel-ICE is equipped with two 50-mil 10-pin JTAG connectors. Both connectors are directly

electrically connected, but conform to two different pinouts; the AVR JTAG header and the ARM Cortex

Debug header. The connector should be selected based on the pinout of the target board, and not the

target MCU type - for example a SAM device mounted in an AVR STK600 stack should use the AVR

header.

The recommended pinout for the 10-pin AVR JTAG connector is shown in Figure 4-6 AVR JTAG Header

Pinout.

The recommended pinout for the 10-pin ARM Cortex Debug connector is shown in Figure 4-2 SAM JTAG

Header Pinout.

Direct connection to a standard 10-pin 50-mil header

Use the 50-mil 10-pin flat cable (included in some kits) to connect directly to a board supporting this

header type. Use the AVR connector port on the Atmel-ICE for headers with the AVR pinout, and the SAM

connector port for headers complying with the ARM Cortex Debug header pinout.

The pinouts for both 10-pin connector ports are shown below.

Connection to a standard 10-pin 100-mil header

Use a standard 50-mil to 100-mil adapter to connect to 100-mil headers. An adapter board (included in

some kits) can be used for this purpose, or alternatively the JTAGICE3 adapter can be used for AVR

targets.

Important:

The JTAGICE3 100-mil adapter cannot be used with the SAM connector port, since pins 2 and

10 (AVR GND) on the adapter are connected.

Connection to a custom 100-mil header

If your target board does not have a compliant 10-pin JTAG header in 50- or 100-mil, you can map to a

custom pinout using the 10-pin "mini-squid" cable (included in some kits), which gives access to ten

individual 100-mil sockets.

Connection to a 20-pin 100-mil header

Use the adapter board (included in some kits) to connect to targets with a 20-pin 100-mil header.

Table 4-7. Atmel-ICE JTAG Pin Description

Name AVR

port

SAM

port

Description

TCK 1 4 Test Clock (clock signal from the Atmel-ICE into the target device).

TMS 5 2 Test Mode Select (control signal from the Atmel-ICE into the target device).

TDI 9 8 Test Data In (data transmitted from the Atmel-ICE into the target device).

TDO 3 6 Test Data Out (data transmitted from the target device into the Atmel-ICE).

nTRST 8 - Test Reset (optional, only on some AVR devices). Used to reset the JTAG

TAP controller.

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Name AVR

port

SAM

port

Description

nSRST 6 10 Reset (optional). Used to reset the target device. Connecting this pin is

recommended since it allows the Atmel-ICE to hold the target device in a

reset state, which can be essential to debugging in certain scenarios.

VTG 4 1 Target voltage reference. The Atmel-ICE samples the target voltage on this

pin in order to power the level converters correctly. The Atmel-ICE draws

less than 3mA from this pin in debugWIRE mode and less than 1mA in

other modes.

GND 2, 10 3, 5, 9 Ground. All must be connected to ensure that the Atmel-ICE and the target

device share the same ground reference.

4.3.4. aWire Physical Interface

The aWire interface makes use the RESET wire of the AVR device to allow programming and debugging

functions. A special enable sequence is transmitted by the Atmel-ICE, which disables the default RESET

functionality of the pin.

When designing an application PCB which includes an Atmel AVR with the aWire interface, it is

recommended to use the pinout as shown in Figure 4-8 aWire Header Pinout. Both 100-mil and 50-mil

variants of this pinout are supported, depending on the cabling and adapters included with the particular

kit.

Figure 4-8. aWire Header Pinout

(RESET_N) DATA VCC

GND

1 2

aWire

(NC)

Tip:

Since aWire is a half-duplex interface, a pull-up resistor on the RESET line in the order of 47kΩ

is recommended to avoid false start-bit detection when changing direction.

The aWire interface can be used as both a programming and debugging interface. All features of the

OCD system available through the 10-pin JTAG interface can also be accessed using aWire.

4.3.5. Connecting to an aWire Target

The aWire interface requires only one data line in addition to VCC and GND. On the target this line is the

nRESET line, although the debugger uses the JTAG TDO line as the data line.

The recommended pinout for the 6-pin aWire connector is shown in Figure 4-8 aWire Header Pinout.

Connection to a 6-pin 100-mil aWire header

Use the 6-pin 100-mil tap on the flat cable (included in some kits) to connect to a standard 100-mil aWire

header.

Connection to a 6-pin 50-mil aWire header

Use the adapter board (included in some kits) to connect to a standard 50-mil aWire header.

Connection to a custom 100-mil header

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The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR connector port and

the target board. Three connections are required, as described in the table below.

Table 4-8. Atmel-ICE aWire Pin Mapping

Atmel-ICE AVR port pins Target pins Mini-squid pin aWire pinout

Pin 1 (TCK) 1

Pin 2 (GND) GND 2 6

Pin 3 (TDO) DATA 3 1

Pin 4 (VTG) VTG 4 2

Pin 5 (TMS) 5

Pin 6 (nSRST) 6

Pin 7 (Not connected) 7

Pin 8 (nTRST) 8

Pin 9 (TDI) 9

Pin 10 (GND) 0

4.3.6. Special Considerations

JTAG interface

On some Atmel AVR UC3 devices the JTAG port is not enabled by default. When using these devices it is

essential to connect the RESET line so that the Atmel-ICE can enable the JTAG interface.

aWire interface

The baud rate of aWire communications depends upon the frequency of the system clock, since data

must be synchronized between these two domains. The Atmel-ICE will automatically detect that the

system clock has been lowered, and re-calibrate its baud rate accordingly. The automatic calibration only

works down to a system clock frequency of 8kHz. Switching to a lower system clock during a debug

session may cause contact with the target to be lost.

If required, the aWire baud rate can be restricted by setting the aWire clock parameter. Automatic

detection will still work, but a ceiling value will be imposed on the results.

Any stabilizing capacitor connected to the RESET pin must be disconnected when using aWire since it

will interfere with correct operation of the interface. A weak external pullup (10kΩ or higher) on this line is

recommended.

Shutdown sleep mode

Some AVR UC3 devices have an internal regulator that can be used in 3.3V supply mode with 1.8V

regulated I/O lines. This means that the internal regulator powers both the core and most of the I/O. Only

Atmel AVR ONE! debugger supports debugging while using sleep modes where this regulator is shut off.

4.3.7. EVTI / EVTO Usage

The EVTI and EVTO pins are not accessible on the Atmel-ICE. However, they can still be used in

conjunction with other external equipment.

EVTI can be used for the following purposes:

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•The target can be forced to stop execution in response to an external event. If the Event In Control

(EIC) bits in the DC register are written to 0b01, high-to-low transition on the EVTI pin will generate

a breakpoint condition. EVTI must remain low for one CPU clock cycle to guarantee that a

breakpoint is triggered. The External Breakpoint bit (EXB) in DS is set when this occurs.

•Generating trace synchronization messages. Not used by the Atmel-ICE.

EVTO can be used for the following purposes:

•Indicating that the CPU has entered debug mode. Setting the EOS bits in DC to 0b01 causes the

EVTO pin to be pulled low for one CPU clock cycle when the target device enters debug mode.

This signal can be used as a trigger source for an external oscilloscope.

•Indicating that the CPU has reached a breakpoint or watchpoint. By setting the EOC bit in a

corresponding Breakpoint/Watchpoint Control Register, the breakpoint or watchpoint status is

indicated on the EVTO pin. The EOS bits in DC must be set to 0xb10 to enable this feature. The

EVTO pin can then be connected to an external oscilloscope in order to examine watchpoint timing.

•Generating trace timing signals. Not used by the Atmel-ICE.

4.4. tinyAVR, megaAVR, and XMEGA Devices

AVR devices feature various programming and debugging interfaces. Check the device datasheet for

supported interfaces of that device.

•Some tinyAVR® devices have a TPI interface. TPI can be used for programming the device only,

and these devices do not have on-chip debug capability at all.

•Some tinyAVR devices and some megaAVR devices have the debugWIRE interface which

connects to an on-chip debug system known as tinyOCD. All devices with debugWIRE also have

the SPI interface for in-system programming.

•Some megaAVR devices have a JTAG interface for programming and debugging, with an on-chip

debug system also known as megaOCD. All devices with JTAG also feature the SPI interface as an

alternative interface for in-system programming.

•All AVR XMEGA devices have the PDI interface for programming and debugging. Some AVR

XMEGA devices also have a JTAG interface with identical functionality.

Table 4-9. Programming and Debugging Interfaces Summary

TPI SPI debugWIRE JTAG PDI aWire SWD

tinyAVR Some

devices

Some

devices

Some

devices

megaAVR All devices Some

devices

Some

devices

AVR

XMEGA

Some

devices

All devices

AVR UC All devices Some

devices

SAM Some

devices

All devices

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4.4.1. JTAG Physical Interface

The JTAG interface consists of a 4-wire Test Access Port (TAP) controller that is compliant with the IEEE®

1149.1 standard. The IEEE standard was developed to provide an industry-standard way to efficiently test

circuit board connectivity (Boundary Scan). Atmel AVR and SAM devices have extended this functionality

to include full Programming and On-chip Debugging support.

Figure 4-9. JTAG Interface Basics

Vcc

TMS

TDI

TDO

TCK

programmer /

debugger

Atmel

target

device

4.4.2. Connecting to a JTAG Target

The Atmel-ICE is equipped with two 50-mil 10-pin JTAG connectors. Both connectors are directly

electrically connected, but conform to two different pinouts; the AVR JTAG header and the ARM Cortex

Debug header. The connector should be selected based on the pinout of the target board, and not the

target MCU type - for example a SAM device mounted in an AVR STK600 stack should use the AVR

header.

The recommended pinout for the 10-pin AVR JTAG connector is shown in Figure 4-6 AVR JTAG Header

Pinout.

The recommended pinout for the 10-pin ARM Cortex Debug connector is shown in Figure 4-2 SAM JTAG

Header Pinout.

Direct connection to a standard 10-pin 50-mil header

Use the 50-mil 10-pin flat cable (included in some kits) to connect directly to a board supporting this

header type. Use the AVR connector port on the Atmel-ICE for headers with the AVR pinout, and the SAM

connector port for headers complying with the ARM Cortex Debug header pinout.

The pinouts for both 10-pin connector ports are shown below.

Connection to a standard 10-pin 100-mil header

Use a standard 50-mil to 100-mil adapter to connect to 100-mil headers. An adapter board (included in

some kits) can be used for this purpose, or alternatively the JTAGICE3 adapter can be used for AVR

targets.

Important:

The JTAGICE3 100-mil adapter cannot be used with the SAM connector port, since pins 2 and

10 (AVR GND) on the adapter are connected.

Connection to a custom 100-mil header

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If your target board does not have a compliant 10-pin JTAG header in 50- or 100-mil, you can map to a

custom pinout using the 10-pin "mini-squid" cable (included in some kits), which gives access to ten

individual 100-mil sockets.

Connection to a 20-pin 100-mil header

Use the adapter board (included in some kits) to connect to targets with a 20-pin 100-mil header.

Table 4-10. Atmel-ICE JTAG Pin Description

Name AVR

port

SAM

port

Description

TCK 1 4 Test Clock (clock signal from the Atmel-ICE into the target device).

TMS 5 2 Test Mode Select (control signal from the Atmel-ICE into the target device).

TDI 9 8 Test Data In (data transmitted from the Atmel-ICE into the target device).

TDO 3 6 Test Data Out (data transmitted from the target device into the Atmel-ICE).

nTRST 8 - Test Reset (optional, only on some AVR devices). Used to reset the JTAG

TAP controller.

nSRST 6 10 Reset (optional). Used to reset the target device. Connecting this pin is

recommended since it allows the Atmel-ICE to hold the target device in a

reset state, which can be essential to debugging in certain scenarios.

VTG 4 1 Target voltage reference. The Atmel-ICE samples the target voltage on this

pin in order to power the level converters correctly. The Atmel-ICE draws

less than 3mA from this pin in debugWIRE mode and less than 1mA in

other modes.

GND 2, 10 3, 5, 9 Ground. All must be connected to ensure that the Atmel-ICE and the target

device share the same ground reference.

4.4.3. SPI Physical Interface

In-System Programming uses the target Atmel AVR’s internal SPI (Serial Peripheral Interface) to

download code into the flash and EEPROM memories. It is not a debugging interface. When designing an

application PCB, which includes an AVR with the SPI interface, the pinout shown in Figure 4-10 SPI

Header Pinout should be used.

Figure 4-10. SPI Header Pinout

PDO/MISO

SCK

/RESET

VCC

PDI/MOSI

GND

1 2

SPI

4.4.4. Connecting to an SPI Target

The recommended pinout for the 6-pin SPI connector is shown in Figure 4-10 SPI Header Pinout.

Connection to a 6-pin 100-mil SPI header

Use the 6-pin 100-mil tap on the flat cable (included in some kits) to connect to a standard 100-mil SPI

header.

Connection to a 6-pin 50-mil SPI header

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Use the adapter board (included in some kits) to connect to a standard 50-mil SPI header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR connector port and

the target board. Six connections are required, as described in the table below.

Important:

The SPI interface is effectively disabled when the debugWIRE enable fuse (DWEN) is

programmed, even if SPIEN fuse is also programmed. To re-enable the SPI interface, the

'disable debugWIRE' command must be issued while in a debugWIRE debugging session.

Disabling debugWIRE in this manner requires that the SPIEN fuse is already programmed. If

Atmel Studio fails to disable debugWIRE, it is probable because the SPIEN fuse is NOT

programmed. If this is the case, it is necessary to use a high-voltage programming interface to

program the SPIEN fuse.

Info:

The SPI interface is often referred to as "ISP", since it was the first In System Programming

interface on Atmel AVR products. Other interfaces are now available for In System

Programming.

Table 4-11. Atmel-ICE SPI Pin Mapping

Atmel-ICE AVR port pins Target pins Mini-squid pin SPI pinout

Pin 1 (TCK) SCK 1 3

Pin 2 (GND) GND 2 6

Pin 3 (TDO) MISO 3 1

Pin 4 (VTG) VTG 4 2

Pin 5 (TMS) 5

Pin 6 (nSRST) /RESET 6 5

Pin 7 (not connected) 7

Pin 8 (nTRST) 8

Pin 9 (TDI) MOSI 9 4

Pin 10 (GND) 0

4.4.5. PDI Physical Interface

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

on-chip debugging of a device. PDI Physical is a 2-pin interface providing a bi-directional half-duplex

synchronous communication with the target device.

When designing an application PCB which includes an Atmel AVR with the PDI interface, the pinout

shown in Figure 4-11 PDI Header Pinout should be used. One of the 6-pin adapters provided with the

Atmel-ICE kit can then be used to connect the Atmel-ICE probe to the application PCB.

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Figure 4-11. PDI Header Pinout

PDI_DATA

PDI_CLK

VCC

GND

1 2

PDI

(NC)

4.4.6. Connecting to a PDI Target

The recommended pinout for the 6-pin PDI connector is shown in Figure 4-11 PDI Header Pinout.

Connection to a 6-pin 100-mil PDI header

Use the 6-pin 100-mil tap on the flat cable (included in some kits) to connect to a standard 100-mil PDI

header.

Connection to a 6-pin 50-mil PDI header

Use the adapter board (included in some kits) to connect to a standard 50-mil PDI header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR connector port and

the target board. Four connections are required, as described in the table below.

Important:

The pinout required is different from the JTAGICE mkII JTAG probe, where PDI_DATA is

connected to pin 9. The Atmel-ICE is compatible with the pinout used by the Atmel-ICE,

JTAGICE3, AVR ONE!, and AVR Dragon™ products.

Table 4-12. Atmel-ICE PDI Pin Mapping

Atmel-ICE AVR port pin Target pins Mini-squid pin Atmel STK600 PDI pinout

Pin 1 (TCK) 1

Pin 2 (GND) GND 2 6

Pin 3 (TDO) PDI_DATA 3 1

Pin 4 (VTG) VTG 4 2

Pin 5 (TMS) 5

Pin 6 (nSRST) PDI_CLK 6 5

Pin 7 (not connected) 7

Pin 8 (nTRST) 8

Pin 9 (TDI) 9

Pin 10 (GND) 0

4.4.7. TPI Physical Interface

TPI is a programming-only interface for some AVR ATtiny devices. It is not a debugging interface, and

these devices do not have OCD capability. When designing an application PCB which includes an AVR

with the TPI interface, the pinout shown in Figure 4-12 TPI Header Pinout should be used.

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Figure 4-12. TPI Header Pinout

TPIDATA

TPICLK

/RESET

VCC

GND

1 2

TPI

(NC)

4.4.8. Connecting to a TPI Target

The recommended pinout for the 6-pin TPI connector is shown in Figure 4-12 TPI Header Pinout.

Connection to a 6-pin 100-mil TPI header

Use the 6-pin 100-mil tap on the flat cable (included in some kits) to connect to a standard 100-mil TPI

header.

Connection to a 6-pin 50-mil TPI header

Use the adapter board (included in some kits) to connect to a standard 50-mil TPI header.

Connection to a custom 100-mil header

The 10-pin mini-squid cable should be used to connect between the Atmel-ICE AVR connector port and

the target board. Six connections are required, as described in Table 4-13 Atmel-ICE TPI Pin Mapping.

Table 4-13. Atmel-ICE TPI Pin Mapping

Atmel-ICE AVR port pins Target pins Mini-squid pin TPI pinout

Pin 1 (TCK) CLOCK 1 3

Pin 2 (GND) GND 2 6

Pin 3 (TDO) DATA 3 1

Pin 4 (VTG) VTG 4 2

Pin 5 (TMS) 5

Pin 6 (nSRST) /RESET 6 5

Pin 7 (not connected) 7

Pin 8 (nTRST) 8

Pin 9 (TDI) 9

Pin 10 (GND) 0

4.4.9. Advanced Debugging (AVR JTAG /debugWIRE devices)

I/O Peripherals

Most I/O peripherals will continue to run even though the program execution is stopped by a breakpoint.

Example: If a breakpoint is reached during a UART transmission, the transmission will be completed and

corresponding bits set. The TXC (transmit complete) flag will be set and be available on the next single

step of the code even though it normally would happen later in an actual device.

All I/O modules will continue to run in stopped mode with the following two exceptions:

•Timer/Counters (configurable using the software front-end)

•Watchdog Timer (always stopped to prevent resets during debugging)

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Single Stepping I/O access

Since the I/O continues to run in stopped mode, care should be taken to avoid certain timing issues. For

example, the code:

OUT PORTB, 0xAA

IN TEMP, PINB

When running this code normally, the TEMP register would not read back 0xAA because the data would

not yet have been latched physically to the pin by the time it is sampled by the IN operation. A NOP

instruction must be placed between the OUT and the IN instruction to ensure that the correct value is

present in the PIN register.

However, when single stepping this function through the OCD, this code will always give 0xAA in the PIN

Single stepping and timing

Certain registers need to be read or written within a given number of cycles after enabling a control

signal. Since the I/O clock and peripherals continue to run at full speed in stopped mode, single stepping

through such code will not meet the timing requirements. Between two single steps, the I/O clock may

have run millions of cycles. To successfully read or write registers with such timing requirements, the

whole read or write sequence should be performed as an atomic operation running the device at full

speed. This can be done by using a macro or a function call to execute the code, or use the run-to-cursor

function in the debugging environment.

Accessing 16-bit registers

The Atmel AVR peripherals typically contain several 16-bit registers that can be accessed via the 8-bit

data bus (e.g.: TCNTn of a 16-bit timer). The 16-bit register must be byte accessed using two read or

write operations. Breaking in the middle of a 16-bit access or single stepping through this situation may

result in erroneous values.

Restricted I/O register access

Certain registers cannot be read without affecting their contents. Such registers include those which

contain flags which are cleared by reading, or buffered data registers (e.g.: UDR). The software front-end

will prevent reading these registers when in stopped mode to preserve the intended non-intrusive nature

of OCD debugging. In addition, some registers cannot safely be written without side-effects occurring -

these registers are read-only. For example:

•Flag registers, where a flag is cleared by writing '1' to any bit. These registers are read-only.

•UDR and SPDR registers cannot be read without affecting the state of the module. These registers

are not accessible.

4.4.10. megaAVR Special Considerations

Software breakpoints

Since it contains an early version of the OCD module, ATmega128[A] does not support the use of the

BREAK instruction for software breakpoints.

JTAG clock

The target clock frequency must be accurately specified in the software front-end before starting a debug

session. For synchronization reasons, the JTAG TCK signal must be less than one fourth of the target

clock frequency for reliable debugging. When programming via the JTAG interface, the TCK frequency is

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limited by the maximum frequency rating of the target device, and not the actual clock frequency being

used.

When using the internal RC oscillator, be aware that the frequency may vary from device to device and is

affected by temperature and VCC changes. Be conservative when specifying the target clock frequency.

JTAGEN and OCDEN fuses

The JTAG interface is enabled using the JTAGEN fuse, which is programmed by default. This allows

access to the JTAG programming interface. Through this mechanism, the OCDEN fuse can be

programmed (by default OCDEN is un-programmed). This allows access to the OCD in order to facilitate

debugging the device. The software front-end will always ensure that the OCDEN fuse is left un-

programmed when terminating a session, thereby restricting unnecessary power consumption by the

OCD module. If the JTAGEN fuse is unintentionally disabled, it can only be re-enabled using SPI or High

Voltage programming methods.

If the JTAGEN fuse is programmed, the JTAG interface can still be disabled in firmware by setting the

JTD bit. This will render code un-debuggable, and should not be done when attempting a debug session.

If such code is already executing on the Atmel AVR device when starting a debug session, the Atmel-ICE

will assert the RESET line while connecting. If this line is wired correctly, it will force the target AVR device

into reset, thereby allowing a JTAG connection.

If the JTAG interface is enabled, the JTAG pins cannot be used for alternative pin functions. They will

remain dedicated JTAG pins until either the JTAG interface is disabled by setting the JTD bit from the

program code, or by clearing the JTAGEN fuse through a programming interface.

Tip:

Be sure to check the "use external reset" checkbox in both the programming dialog and debug

options dialog in order to allow the Atmel-ICE to assert the RESET line and re-enable the JTAG

interface on devices which are running code which disables the JTAG interface by setting the

JTD bit.

IDR/OCDR events

The IDR (In-out Data Register) is also known as the OCDR (On Chip Debug Register), and is used

extensively by the debugger to read and write information to the MCU when in stopped mode during a

debug session. When the application program in run mode writes a byte of data to the OCDR register of

the AVR device being debugged, the Atmel-ICE reads this value out and displays it in the message

window of the software front-end. The OCDR register is polled every 50ms, so writing to it at a higher

frequency will NOT yield reliable results. When the AVR device loses power while it is being debugged,

spurious OCDR events may be reported. This happens because the Atmel-ICE may still poll the device

as the target voltage drops below the AVR’s minimum operating voltage.

4.4.11. AVR XMEGA Special Considerations

OCD and clocking

When the MCU enters stopped mode, the OCD clock is used as MCU clock. The OCD clock is either the

JTAG TCK if the JTAG interface is being used, or the PDI_CLK if the PDI interface is being used.

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I/O modules in stopped mode

In contrast to earlier Atmel megaAVR devices, in XMEGA the I/O modules are stopped in stop mode. This

means that USART transmissions will be interrupted, timers (and PWM) will be stopped.

Hardware breakpoints

There are four hardware breakpoint comparators - two address comparators and two value comparators.

They have certain restrictions:

•All breakpoints must be of the same type (program or data)

•All data breakpoints must be in the same memory area (I/O, SRAM, or XRAM)

•There can only be one breakpoint if address range is used

Here are the different combinations that can be set:

•Two single data or program address breakpoints

•One data or program address range breakpoint

•Two single data address breakpoints with single value compare

•One data breakpoint with address range, value range, or both

Atmel Studio will tell you if the breakpoint can't be set, and why. Data breakpoints have priority over

program breakpoints, if software breakpoints are available.

External reset and PDI physical

The PDI physical interface uses the reset line as clock. While debugging, the reset pullup should be 10k

or more or be removed. Any reset capacitors should be removed. Other external reset sources should be

disconnected.

Debugging with sleep for ATxmegaA1 rev H and earlier

A bug existed on early versions of ATxmegaA1 devices that prevented the OCD from being enabled while

the device was in certain sleep modes. There are two workarounds to re-enable OCD:

•Go into the Atmel-ICE. Options in the Tools menu and enable "Always activate external reset when

reprogramming device".

•Perform a chip erase

The sleep modes that trigger this bug are:

•Power-down

•Power-save

•Standby

•Extended standby

4.4.12. debugWIRE Special Considerations

The debugWIRE communication pin (dW) is physically located on the same pin as the external reset

(RESET). An external reset source is therefore not supported when the debugWIRE interface is enabled.

The debugWIRE Enable fuse (DWEN) must be set on the target device in order for the debugWIRE

interface to function. This fuse is by default un-programmed when the Atmel AVR device is shipped from

the factory. The debugWIRE interface itself cannot be used to set this fuse. In order to set the DWEN

fuse, the SPI mode must be used. The software front-end handles this automatically provided that the

necessary SPI pins are connected. It can also be set using SPI programming from the Atmel Studio

programming dialog.

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Either: Attempt to start a debug session on the debugWIRE part. If the debugWIRE interface is not

enabled, Atmel Studio will offer to retry, or attempt to enable debugWIRE using SPI

programming. If you have the full SPI header connected, debugWIRE will be enabled, and you

will be asked to toggle power on the target. This is required for the fuse changes to be effective.

Or: Open the programming dialog in SPI mode, and verify that the signature matches the correct

device. Check the DWEN fuse to enable debugWIRE.

Important:

It is important to leave the SPIEN fuse programmed, the RSTDISBL fuse un-programmed! Not

doing this will render the device stuck in debugWIRE mode, and High Voltage programming will

be required to revert the DWEN setting.

To disable the debugWIRE interface, use High Voltage programming to un-program the DWEN fuse.

Alternately, use the debugWIRE interface itself to temporarily disable itself, which will allow SPI

programming to take place, provided that the SPIEN fuse is set.

Important:

If the SPIEN fuse was NOT left programmed, Atmel Studio will not be able to complete this

operation, and High Voltage programming must be used.

During a debug session, select the 'Disable debugWIRE and Close' menu option from the 'Debug' menu.

DebugWIRE will be temporarily disabled, and Atmel Studio will use SPI programming to un-program the

DWEN fuse.

Having the DWEN fuse programmed enables some parts of the clock system to be running in all sleep

modes. This will increase the power consumption of the AVR while in sleep modes. The DWEN Fuse

should therefore always be disabled when debugWIRE is not used.

When designing a target application PCB where debugWIRE will be used, the following considerations

must be made for correct operation:

•Pull-up resistors on the dW/(RESET) line must not be smaller (stronger) than 10kΩ. The pull-up

resistor is not required for debugWIRE functionality, since the debugger tool provides this.

•Any stabilizing capacitor connected to the RESET pin must be disconnected when using

debugWIRE, since they will interfere with correct operation of the interface

•All external reset sources or other active drivers on the RESET line must be disconnected, since

they may interfere with the correct operation of the interface

Never program the lock-bits on the target device. The debugWIRE interface requires that lock-bits are

cleared in order to function correctly.

4.4.13. debugWIRE Software Breakpoints

The debugWIRE OCD is drastically scaled down when compared to the Atmel megaAVR (JTAG) OCD.

This means that it does not have any program counter breakpoint comparators available to the user for

debugging purposes. One such comparator does exist for purposes of run-to-cursor and single-stepping

operations, but additional user breakpoints are not supported in hardware.

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Instead, the debugger must make use of the AVR BREAK instruction. This instruction can be placed in

FLASH, and when it is loaded for execution it will cause the AVR CPU to enter stopped mode. To support

breakpoints during debugging, the debugger must insert a BREAK instruction into FLASH at the point at

which the users requests a breakpoint. The original instruction must be cached for later replacement.

When single stepping over a BREAK instruction, the debugger has to execute the original cached

instruction in order to preserve program behavior. In extreme cases, the BREAK has to be removed from

FLASH and replaced later. All these scenarios can cause apparent delays when single stepping from

breakpoints, which will be exacerbated when the target clock frequency is very low.

It is thus recommended to observe the following guidelines, where possible:

•Always run the target at as high a frequency as possible during debugging. The debugWIRE

physical interface is clocked from the target clock.

•Try to minimize on the number of breakpoint additions and removals, as each one require a FLASH

page to be replaced on the target

•Try to add or remove a small number of breakpoints at a time, to minimize the number of FLASH

page write operations

•If possible, avoid placing breakpoints on double-word instructions

4.4.14. Understanding debugWIRE and the DWEN Fuse

When enabled, the debugWIRE interface takes control of the device's /RESET pin, which makes it

mutually exclusive to the SPI interface, which also needs this pin. When enabling and disabling the

debugWIRE module, follow one of these two approaches:

•Let Atmel Studio take care of things (recommended)

•Set and clear DWEN manually (exercise caution, advanced users only!)

Important: When manipulating DWEN manually, it is important that the SPIEN fuse remains

set to avoid having to use High-Voltage programming.

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Figure 4-13. Understanding debugWIRE and the DWEN fuse

Atmel Studio

start debug session

Power toggle

(latches debugWIRE state)

Studio "Disable debugWIRE and close"

(disables debugWIRE module temporarily

and then clears DWEN fuse using SPI)

atprogram dwdisable

(atprogram disables

debugWIRE module temporarily)

Clear DWEN fuse

using SPI

Set DWEN fuse

using SPI

Intermediate state 1:

Fuse DWEN set

Fuse SPIEN set* (NB!)

Module debugWIRE disabled until power toggle

You can: Toggle power

DWEN

SPIEN

Default state:

Fuse DWEN cleared

Fuse SPIEN set

Module debugWIRE disabled

You can: Access flash and fuses using SPI

DWEN

SPIEN

Debug state:

Fuse DWEN set

Fuse SPIEN set

Module debugWIRE enabled

You can: use debugWIRE

You cannot: Access fuses or flash using SPI

DWEN

SPIEN

Intermediate state 2:

Fuse DWEN set

Fuse SPIEN set

Module debugWIRE disabled

You can: Access fuses and flash using SPI

DWEN

SPIEN

Debug state (not recommended):

Fuse DWEN set

Fuse SPIEN cleared

Module debugWIRE enabled

You can: use debugWIRE

To access flash and fuses it is now necessary to

use the High-Voltage Programming interface

DWEN

SPIEN

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5. Hardware Description

5.1. LEDs

The Atmel-ICE top panel has three LEDs which indicate the status of current debug or programming

sessions.

Table 5-1. LEDs

LED Function Description

Left Target power GREEN when target power is OK. Flashing indicates a target power

error. Does not light up until a programming/debugging session

connection is started.

Middle Main power RED when main-board power is OK.

Right Status Flashing GREEN when the target is running/stepping. OFF when

target is stopped.

5.2. Rear Panel

The rear panel of the Atmel-ICE houses the Micro-B USB connector.

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5.3. Bottom Panel

The bottom panel of the Atmel-ICE has a sticker which shows the serial number and date of manufacture.

When seeking technical support, include these details.

5.4. Architecture Description

The Atmel-ICE architecture is shown in the block diagram in Figure 5-1 Atmel-ICE Block Diagram.

Figure 5-1. Atmel-ICE Block Diagram

UC3A4

MCU

USB

power

supply

level

conversion

AVR

host

Atmel

target

device

filters &

protection

SAM

buffer

5.4.1. Atmel-ICE Main Board

Power is supplied to the Atmel-ICE from the USB bus, regulated to 3.3V by a step-down switch-mode

regulator. The VTG pin is used as a reference input only, and a separate power supply feeds the variable-

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voltage side of the on-board level converters. At the heart of the Atmel-ICE main board is the Atmel AVR

UC3 microcontroller AT32UC3A4256, which runs at between 1MHz and 60MHz depending on the tasks

being processed. The microcontroller includes an on-chip USB 2.0 high-speed module, allowing high data

throughput to and from the debugger.

Communication between the Atmel-ICE and the target device is done through a bank of level converters

that shift signals between the target's operating voltage and the internal voltage level on the Atmel-ICE.

Also in the signal path are zener overvoltage protection diodes, series termination resistors, inductive

filters and ESD protection diodes. All signal channels can be operated in the range 1.62V to 5.5V,

although the Atmel-ICE hardware can not drive out a higher voltage than 5.0V. Maximum operating

frequency varies according to the target interface in use.

5.4.2. Atmel-ICE Target Connectors

The Atmel-ICE don't have an active probe. A 50-mil IDC cable is used to connect to the target application

either directly, or through the adapters included in some kits. For more information on the cabling and

adapters, see section Assembling the Atmel-ICE

5.4.3. Atmel-ICE Target Connectors Part Numbers

In order to connect the Atmel-ICE 50-mil IDC cable directly to a target board, any standard 50-mil 10-pin

header should suffice. It is advised to use keyed headers to ensure correct orientation when connecting

to the target, such as those used on the adapter board included with the kit.

The part number for this header is: FTSH-105-01-L-DV-K-A-P from SAMTEC.

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6. Software Integration

6.1. Atmel Studio

6.1.1. Software Integration in Atmel Studio

Atmel Studio is an Integrated Development Environment (IDE) for writing and debugging Atmel AVR and

Atmel SAM applications in Windows environments. Atmel Studio provides a project management tool,

source file editor, simulator, assembler and front-end for C/C++, programming, emulation and on-chip

debugging.

Atmel Studio version 6.2 or later must be used in conjunction with the Atmel-ICE.

6.1.2. Programming Options

Atmel Studio supports programming of Atmel AVR and Atmel SAM ARM devices using the Atmel-ICE.

The programming dialog can be configured to use JTAG, aWire, SPI, PDI, TPI, SWD modes, according to

the target device selected.

When configuring the clock frequency, different rules apply for different interfaces and target families:

•SPI programming makes use of the target clock. Configure the clock frequency to be lower than

one fourth the frequency at which the target device is currently running.

•JTAG programming on Atmel megaAVR devices is clocked by the programmer. This means that the

programming clock frequency is limited to the maximum operating frequency of the device itself.

(Usually 16MHz.)

•AVR XMEGA programming on both JTAG and PDI interfaces is clocked by the programmer. This

means that the programming clock frequency is limited to the maximum operating frequency of the

device itself. (Usually 32MHz).

•AVR UC3 programming on JTAG interface is clocked by the programmer. This means that the

programming clock frequency is limited to the maximum operating frequency of the device itself.

(Limited to 33MHz.)

•AVR UC3 programming on aWire interface is clocked by the programmer. The optimal frequency is

given by the SAB bus speed in the target device. The Atmel-ICE debugger will automatically tune

the aWire baud rate to meet this criteria. Although it's usually not necessary the user can limit the

maximum baud rate if needed (e.g. in noisy environments).

•SAM device programming on SWD interface is clocked by the programmer. The maximum

frequency supported by Atmel-ICE is 2MHz. The frequency should not exceed the target CPU

frequency times 10, fSWD ≤10fSYSCLK .

6.1.3. Debug Options

When debugging an Atmel AVR device using Atmel Studio, the 'Tool' tab in the project properties view

contains some important configuration options. The options which need further explanation are detailed

here.

Target Clock Frequency

Accurately setting the target clock frequency is vital to achieve reliable debugging of Atmel megaAVR

device over the JTAG interface. This setting should be less than one fourth of the lowest operating

frequency of your AVR target device in the application being debugged. See megaAVR Special

Considerations for more information.

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Debug sessions on debugWIRE target devices are clocked by the target device itself, and thus no

frequency setting is required. The Atmel-ICE will automatically select the correct baud rate for

communicating at the start of a debug session. However, if you are experiencing reliability problems

related to a noisy debug environment, some tools offer the possibility to force the debugWIRE speed to a

fraction of its "recommended" setting.

Debug sessions on AVR XMEGA target devices can be clocked at up to the maximum speed of the

device itself (usually 32MHz).

Debug sessions on AVR UC3 target devices over the JTAG interface can be clocked at up to the

maximum speed of the device itself (limited to 33MHz). However, the optimal frequency will be slightly

below the current SAB clock on the target device.

Debug sessions on UC3 target devices over the aWire interface will be automatically tuned to the optimal

baud rate by the Atmel-ICE itself. However, if you are experiencing reliability problems related to a noisy

debug environment, some tools offer the possibility to force the aWire speed below a configurable limit.

Debug sessions on SAM target devices over the SWD interface can be clocked at up to ten times the

CPU clock (but limited to 2MHz max.)

Preserve EEPROM

Select this option to avoid erasing the EEPROM during reprogramming of the target before a debug

session.

Use external reset

If your target application disables the JTAG interface, the external reset must be pulled low during

programming. Selecting this option avoids repeatedly being asked whether to use the external reset.

6.2. Command Line Utility

Atmel Studio comes with a command line utility called atprogram that can be used to program targets

using the Atmel-ICE. During the Atmel Studio installation a shortcut called Atmel Studio 7.0. Command

Prompt were created in the Atmel folder on the Start menu. By double clicking this shortcut a command

prompt will be opened and programming commands can be entered. The command line utility is installed

in the Atmel Studio installation path in the folder Atmel/Atmel Studio 7.0/atbackend/.

To get more help on the command line utility type the command:

atprogram --help

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7. Advanced Debugging Techniques

7.1. Atmel AVR UC3 Targets

7.1.1. EVTI / EVTO Usage