zigbit 2.4ghz wireless modules atzb-24-a2/b0 · atzb-x0-256-4-0-cn [zigbit 900mhz wireless modules]...
TRANSCRIPT
ZIGBIT 900MHZ WIRELESS MODULES
ATZB-X0-256-4-0-CN
DATASHEET
Features
• Compact size (38.5 x 20.0mm) • High RX sensitivity (-103dBm) • Outperforming link budget (up to +112dB) • Up to +9.0dBm output power • Very low power consumption:
• 8.7mA in RX mode (1) • 34.8mA in TX mode (1) • 0.6µA in sleep mode (2)
• Ample memory resources (256KB In-System, Self-Programmable Flash memory, 4KB EEPROM, 16KB SRAM)
• Wide range of interfaces (both analog and digital) • 4-wire SPI, TWI • ISP, JTAG • Two analog comparator input • UART, USART • Timer, PWM • Four ADC lines • External Clock Input, Internal Clock Output • Up to 32 lines configurable as GPIO
• Preassigned Atmel® MAC address that can be used on end product • Capability to use MAC address into the internal EEPROM • IEEE® 802.15.4 compliant Transceiver • 900MHz ISM band • Serial bootloader • High Performance Low Power Atmel AVR® XMEGA® 8- and 32-bit Microcontroller • Rapid design-in with built-in Chip Antenna • RF Test point using MS-147 RF connector • Small physical footprint and low profile for optimum fit in very small application
boards • Mesh networking capability • Easy-to-use low cost development kit • Single source of support for HW and SW • Worldwide license-free operation
Notes: 1. MCU is in active state with 3V Supply, CPU clock @ 16MHz, RX RPC enabled (for RX current), PHY_TX_PWR=0x0 (for TX current), All digital outputs pulled high.
2. Controller Sleep Mode: SLEEP_MODE_PWR_DOWN.
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Table of Contents
1. Introduction ........................................................................................ 3 1.1 Summary ........................................................................................................... 3 1.2 Applications ....................................................................................................... 3 1.3 Abbreviations and Acronyms ............................................................................ 3 1.4 Related Documents ........................................................................................... 4
2. ZigBit Module Overview ..................................................................... 5 2.1 Overview ........................................................................................................... 5
3. Specifications ..................................................................................... 7 3.1 Electrical Characteristics ................................................................................... 7
3.1.1 Absolute Maximum Ratings ................................................................ 7 3.1.2 Power Supply ...................................................................................... 7 3.1.3 RF Characteristics .............................................................................. 8 3.1.4 ATxmega256A3U Microcontroller Characteristics .............................. 9 3.1.5 Module Interfaces Characteristics ....................................................... 9
3.2 Physical/environmental Characteristics and Outline ......................................... 9 3.3 Pin Configuration ............................................................................................. 10 3.4 Antenna Orientation Recommendation ........................................................... 11 3.5 Mounting Information ...................................................................................... 11 3.6 Soldering Profile .............................................................................................. 14 3.7 Antenna Reference Designs ........................................................................... 14
4. Schematics ...................................................................................... 15 4.1 Handling Instructions ....................................................................................... 20 4.2 General Recommendations ............................................................................ 20
5. Persistence Memory ........................................................................ 21
6. Ordering Information ........................................................................ 22
7. Agency Certifications ....................................................................... 23 7.1 United States (FCC) ........................................................................................ 23 7.2 European Union (ETSI) ................................................................................... 23 7.3 Industry Canada (IC) Compliance Statements ................................................ 24
8. Revision History ............................................................................... 25
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1. Introduction
1.1 Summary ATZB-X0-256-4-0-CN ZigBit® is an ultra-compact and low-power 900MHz IEEE 802.15.4/ZigBee® OEM module from Atmel. Based on the innovative mixed-signal hardware platform from Atmel, this module uses the ATxmega256A3U [1] Microcontroller and AT86RF212B [5] 700/800/900MHz ISM band Transceiver. The radio transceiver provides high data rates from 20kb/s up to 1Mb/s, frame handling, outstanding receiver sensitivity and high transmit output power enabling a very robust wireless communication. The module is designed for wireless sensing, monitoring, control, data acquisition applications, to name a few. This ZigBit module eliminates the need for costly and time-consuming RF development, and shortens time-to-market for wireless applications.
The module has an MS-147 RF connector that can be used as an RF test port. The built-in chip antenna is designed and tuned for the ZigBit design to enable quick integration of the ZigBit into any application.
1.2 Applications The ZigBit module is compatible with robust IEEE 802.15.4/ZigBee stack that supports a self-healing, self-organizing mesh network, while optimizing network traffic and minimizing power consumption.
For detailed software support information, visit http://www.atmel.com/products/wireless.
The applications include, but are not limited to:
• Building automation and monitoring • Lighting controls • Wireless smoke- and CO-detectors • Structural integrity monitoring
• HVAC monitoring and control
• Inventory management
• Environmental monitoring
• Security
• Water metering
• Industrial monitoring • Machinery condition and performance monitoring • Monitoring of plant system parameters such as temperature, pressure, flow, tank level, humidity,
vibration, etc.
• Automated meter reading (AMR)
1.3 Abbreviations and Acronyms ADC Analog-to-Digital Converter API Application Programming Interface DC Direct Current DTR Data Terminal Ready EEPROM Electrically Erasable Programmable Read-Only Memory ESD Electrostatic Discharge GPIO General Purpose Input/output HAF High Frequency HVAC Heating, Ventilating, and Air Conditioning
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HW Hardware I2C Inter-Integrated Circuit IEEE Institute of Electrical and Electronics Engineers IRQ Interrupt Request ISM Industrial, Scientific and Medical radio band JTAG Digital interface for debugging of embedded device, also known as IEEE 1149.1 standard
interface MAC Medium Access Control layer MCU Microcontroller Unit. In this document it also means the processor, which is the core of a ZigBit
module NRE Network layer OEM Original Equipment Manufacturer OTA Over-The-Air upgrade PA Power Amplifier PCB Printed Circuit Board PER Package Error Ratio RAM Random Access Memory RF Radio Frequency RPC Reduced Power Consumption RTS/CTS Request to Send/ Clear to Send RX Receiver SMA Surface Mount Assembly SoC System on Chip SPI Serial Peripheral Interface SW Software TTM Time-To-Market TX Transmitter UART Universal Asynchronous Receiver/Transmitter USART Universal Synchronous/Asynchronous Receiver/Transmitter USB Universal Serial Bus ZigBee, ZigBee PRO Wireless networking standards targeted at low-power applications 802.15.4 The IEEE 802.15.4-2003 standard applicable to low-rate wireless Personal Area Network
1.4 Related Documents [1] ATXMEGA256A3U Datasheet in http://www.atmel.com/devices/ATXMEGA256A3U.aspx?tab=documents.
[2] MS-147 Series Interface RF Connector with Switch, 3.9mm High, DC to 6GHz http://www.hirose.co.jp/cataloge_hp/e35801505.pdf.
[3] IEEE Std 802.15.4-2003 IEEE Standard for Information technology - Part 15.4 Wireless Medium Access Control (MAC) and Physical Layer (PHY) Specifications for Low-Rate Wireless Personal Area Networks (LR-WPANs).
[4] ZigBee Specification. ZigBee Document 053474r17, October 19, 2007.
[5] AT86RF212B Datasheet in http://www.atmel.com/devices/AT86RF212B.aspx?tab=documents.
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2. ZigBit Module Overview
2.1 Overview The ATZB-X0-256-4-0-CN ZigBit is a compact, low-power, high sensitivity IEEE 802.15.4/ZigBee OEM module. Based on a solid combination of the latest Atmel MCU Wireless hardware platform, 900MHz ISM band transceiver and Atmel Studio Wireless Composer - the ZigBit offers an unmatched combination of superior radio performance, ultra-low power consumption and exceptional ease of integration.
Figure 2-1. ATZB-X0-256-4-0-CN User Interface Diagram
This ZigBit module contains the Atmel ATxmegaA256A3U Microcontroller and AT86RF212B 900MHz ISM band Transceiver for ZigBee and IEEE 802.15.4 [3]. The module features 256KB In-System Self-Programmable flash memory, 16KB SRAM and 4KB EEPROM.
The compact all-in-one board design of MCU and Radio Transceiver with very minimal components on the RF path to Antenna dramatically improves the ZigBit’s compact size, range performance on signal transmission and increases its sensitivity. This ensures stable connectivity within a larger coverage area, and helps develop applications on smaller footprint. The MS-147 connector [2] can be used as an RF Test port.
ZigBit Module contains a complete RF/MCU design with all the necessary passive components included. The module can be easily mounted on a simple 2-layer PCB with a minimum of required external connection. The ZigBit Module Evaluation kit containing the ZigBit Extension board for the Atmel Xplained PRO HW Evaluation platform can be used to develop FW using the Atmel Studio and evaluate using the Wireless Composer. Compared to a custom RF/MCU solution, a module-based solution offers considerable savings in development time and NRE cost per unit during the HW/FW design, prototyping, and mass production phases of product development.
All ZigBits are preloaded with a Bootloader when they are sold as Modules, either in Single units or T&R.
Depending on end-user design requirements, the ZigBit can operate as a self-contained sensor node, where it would function as a single MCU, or it can be paired with a host processor driving the module over a serial interface.
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The MAC stack running on the host processor can then control data transmission and manages module peripherals. Thus very minimal firmware customization is required for successful module design-in. Third-party sensors can then be connected directly to the module, thus expanding the existing set of peripheral interfaces.
Every ZigBit Module come pre loaded with Atmel assigned 64-bit MAC address stored in the signature bytes of the device. This unique IEEE MAC address can be used as the MAC address of the end product, so there is no need to buy a MAC address separately for the product using the ZigBit.
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3. Specifications
3.1 Electrical Characteristics
3.1.1 Absolute Maximum Ratings
Table 3-1. Absolute Maximum Ratings (1)(2)
Parameter Minimum Maximum
Voltage on any pin, except RESET with respect to ground -0.3V 3.6V (VDD max)
Input RF level +10dBm
Current into VCC pins 200mA
Notes: 1. Absolute Maximum Ratings are the values beyond which damage to the device may occur. Under no circumstances must the absolute maximum ratings given in this table be violated. Stresses beyond those listed under "Absolute Maximum Ratings" may cause permanent damage to the device. This is a stress rating only. Functional operation of the device at these or other conditions, beyond those indicated in the operational sections of this specification, is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability.
2. Attention! ZigBit is an ESD-sensitive device. Precaution should be taken when handling the device in order to prevent permanent damage.
3.1.2 Power Supply
Table 3-2. Test Conditions (unless otherwise stated), Vcc = 3V, Tamb = 25°C
Parameter Range Unit
Supply voltage, VDD 1.8 to 3.6 V
Active Current consumption: RX mode + Max sensitivity 14.5 mA
Active Current consumption: RX mode + Least sensitivity 13.9 mA
Active Current consumption: RX mode + Max sensitivity, MCU Sleep (2) 9.3 mA
Active Current consumption: RX mode + Least sensitivity, MCU Sleep (2) 8.7 mA
Active Current consumption: TX mode (1) – BUSY_TX – Transmit state 34.8 mA
Current consumption: TRX_OFF, MCU Active 6.1 mA
Current consumption: TRX_OFF, MCU Sleep (2) 740 µA
Sleep Current consumption: TRX Sleep, MCU Sleep (2) 0.6 µA
Note 1: Output TX power (when measuring consumption in TX mode) is +9dBm. Note 2:
a) All interfaces are set to the default state (see Table 3-8 Pinout Description). b) JTAG is not connected. c) CPU Clock configured when doing this measurement – 16MHz for all modes except Power save and Power down modes.
Current consumption depends on multiple factors, including but not limited to, the board design and materials, Protocol settings, network activity, EEPROM read/write operations. It also depends on MCU load and/or peripherals used by an application.
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3.1.3 RF Characteristics
Table 3-3. RF Characteristics (3)
Parameter Condition Range Unit
Frequency band – FCC and Industry Canada (2) 902 – 928 MHz
Numbers of channels (FCC and Industry Canada) 10
Channel spacing 2 MHz
Transmitter output power Adjusted in 36 steps -25 to +11 dBm
Receiver sensitivity PER = 1% -103 dBm
On-air data rate 20, up to 1000 Kbps
TX output/ RX input nominal impedance For balanced 50 Ω
Range (1) Open field, LoS, Elevated 1120 m
Notes: 1. Range measured is Line of Sight at 10ft elevation from Ground at different combinations of orientation of transmitter and receiver, with special conditions were there is minimal or no RF interference from other sources. For best case orientation of the ZigBits to achieve maximum range, refer to Section 3.4.
2. Appropriate FW (Register selection) must be used for operating this ZigBit in North America.
3. For detailed characteristics, refer to [2].
Table 3-4. TX Power Settings
PHY_TX_PWR 3:0 Register value Power register setting [dBm] Output power [dBm] (typical values at RF connector)
C0 11 8.59
C1 10 8.14
80 9 7.43
82 8 5.85
83 7 4.97
84 6 4.1
40 5 3.58
86 4 2.12
00 3 1.4
01 2 0.42
02 1 -0.93
03 0 -2.09
04 -1 -3.16
27 -2 -4.29
91 -6 -7.86
0D -10 -12.27
15 -18 -19.51
1D -25 -26.82
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3.1.4 ATxmega256A3U Microcontroller Characteristics
Table 3-5. ATxmega256A3U Characteristics
Parameter Range Unit
On-chip flash memory size 256K Bytes
On-chip RAM size 16K Bytes
On-chip EEPROM size 4K Bytes
Operation frequency 16 MHz
3.1.5 Module Interfaces Characteristics
Table 3-6. Module Interfaces Characteristics (1)
Parameters Condition Range Unit
UART maximum baud rate 115.2 Kbps
ADC conversion time (latency) (RES+2)/2+(GAIN !=0) RES (Resolution) = 8 or 12
5-8 ClkADC cycles
ADC input resistance Static load resistor of input signal 4.0 kΩ
ADC reference voltage (VREF) 1.0 to AVCC – 0.6 V
ADC input voltage 0 - AVDD V
TWI maximum clock 400 kHz
GPIO High level input voltage VCC = 2.7-3.6V 2 to VCC+0.3 V
GPIO Low level input voltage VCC = 2.7-3.6V -0.3 to 0.3 VDD V
GPIO High level output voltage VOH VCC = 3.0-3.6V 2.4 to 0.94VCC V
GPIO Low level output voltage VOL VCC = 3.0-3.6V 0.05VCC typ. Max. 0.4
V
Real-time oscillator frequency 32.768 kHz
Note 1: For detailed characteristics, refer to [1].
3.2 Physical/environmental Characteristics and Outline
Table 3-7. Physical Characteristics
Parameters Value Comments
Size 38.5 x 20.0mm
Operating temperature range -40°C to +85°C -40°C to +85°C operational
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3.3 Pin Configuration
Table 3-8. ATZB-X0-256-4-0-CN Pinout Description
Pin out Pin descriptions Function
1 AVSS Analog Ground
2 AVSS Analog Ground
3 DEVDD Digital Power input pin
4 DEVDD Digital Power input pin
5 RSET/PDI_CLOCK RESET
6 PD4/SS SPI
7 PD5/MOSI/XCK1 SPI
8 PD6/MISO/RXD1/D- SPI
9 PD7/SCK/TXD1/D+ SPI
10 PA5 GPIO / ADC / Analog COMP+
11 PA4 GPIO/ADC/Analog Comp-
12 DVSS Digital Ground
13 PD2/SYNC/ASYNC/OC0C/ UART
14 PD3/SYNC/TXD0/OC0D UART
15 PD1/SCL/INT/OC0B USART
16 PDI_DATA PWM/TC
17 PA6 GPIO/ADC
18 PA7 GPIO/ADC
19 PB3 GPIO/ADC/DAC1
20 PB2 GPIO/ADC/DAC/intwkup
21 PF1/OC0B/INT/XCK0 INT/PWM/GPIO
22 PF2/OC0C/INT/RXD0 INT/PWM/GPIO
23 PF3/OC0D/INT/TXD0 INT/PWM/GPIO
24 PB0/IAREF/INT ADC ref
25 PA0/ADC0/INT ADC/ GPIO
26 PA1/ADC1/INT ADC/ GPIO
27 PA2/ADC2/INT ADC/ GPIO
28 PA3/ADC3/INT ADC/ GPIO
29 DVSS Digital Ground
30 PB6/TCK/INT JTAG
31 PB4/TMS/INT JTAG
32 PB7/TDO/INT JTAG
33 PB5/TDI/INT JTAG
34 PE3/TXD GPIO/output counter
35 PE2/RXD Wakeup INT
36 PE1/XCK TWI/INT/GPIO
37 PE0 TWI/INT/GPIO
38 PE5/OC1B/INT GPIO/TC
39 PE4/SYNC/OC1A Master Clock out put
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Pin out Pin descriptions Function
40 PF0 GPIO/Timer
41 DVSS Digital Ground
42 DVSS Digital Ground
NOTE: TXD, RXD of UART are crossed inside ZigBit Module. External UART devices connecting to ZigBit Module should follow straight connection for UART. UART_TXD_external_device <-> UART_TXD UART_RXD_external_device <-> UART_RXD
3.4 Antenna Orientation Recommendation
The Antenna in this module is designed to provide the best possible LoS range in the direction indicated in this illustration.
3.5 Mounting Information Figure 3-1 shows the PCB layout recommended for a ZigBit module. Neither via-holes nor wires are allowed on the PCB upper layer in the area occupied by the module. As a critical requirement, RF_GND pins should be grounded via several via-holes to be located right next to the pins thus minimizing inductance and preventing both mismatch and losses.
Figure 3-1. ATZB-X0-256-4-0-CN Dimensions
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Figure 3-2. ATZB-X0-256-4-0-CN Pinout
Figure 3-3. ATZB-X0-256-4-0-CN Foot Print Dimensions
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Figure 3-4. ATZB-X0-256-4-0-CN Mounting Information (preferred placement)
Figure 3-5. ATZB-X0-256-4-0-CN Mounting Information (alternative placement)
The ZigBit’s location and orientation on the carrier board is illustrated in the above PCB Land pattern and Mounting information drawing. The Recommended placement of ZigBit on Carrier Board needs to be accurately followed to ensure performance on the end application.
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3.6 Soldering Profile The J-STD-020C-compliant soldering profile is recommended according to Table 3-9.
Table 3-9. Soldering profile (1)
Profile feature Green package
Average ramp-up rate (217°C to peak) 3°C/s max.
Preheat temperature 175°C ±25°C 180s max.
Temperature maintained above 217°C 60s to 150s
Time within 5°C of actual peak temperature 20s to 40s
Peak temperature range 260°C
Ramp-down rate 6°C/s max.
Time within 25°C to peak temperature 8 minutes
Note: 1. The package is backward compatible with PB/Sn soldering profile.
3.7 Antenna Reference Designs Multiple factors affect proper antenna match, hence, affecting the antenna pattern. The particular factors are the board material and thickness, shields, the material used for enclosure, the board neighborhood, and other components adjacent to antenna. Following guidelines need to be followed when designing the base board for the ZigBit.
General Recommendations:
• Metal enclosure should not be used. Using low profile enclosure might also affect antenna tuning.
• Placing high profile components next to antenna should be avoided
• Having holes/vias punched around the periphery of the board eliminates parasitic radiation from the board edges also distorting antenna pattern
• ZigBit module should not be placed next to consumer electronics which might interfere with ZigBit’s RF band frequency
The board design should prevent propagation of microwave field inside the board material. Electromagnetic waves of high frequency may penetrate the board thus making the edges of the board radiate, which may distort the antenna pattern. To eliminate this effect, metalized and grounded holes/vias must be placed around the board's edges.
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4. Schematics The following schematic drawings for the ATZB-X0-256-4-0-CN are in the following order: • Top level schematics
• Connector schematics
• ATxmega256A3U schematics
• AT86RF212B schematics
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Xmega_212B_Connector.SchDoc
24
2/6/2014
4:23:39 PM
ATZB-X0-256-4-0-CN
ATMEL Norway
Vestre Rosten 79
N-7075 TILLER
NORWAY
PAGE:
of
TITLE:
Document number:
Revision:5
Date:
OJS
MSK
*
PA3_
AD
C3_
INT
PB6_
TCK
_IN
T
PB7_
TDO
_IN
T
PB5_
TDI_
INT
PB4_
TMS_
INT
PB3
PB2
PA6
PA0_
AD
C0_
INT
PA1_
AD
C1_
INT
PA2_
AD
C2_
INT
PF1_
OC
0B_I
NT_
XC
K0
PA5
PA4
PA7
VCC_3V3
GND
GND
PD4_
SS
PD5_
MO
SI_X
CK
1
USB
D_P
USB
D_N
GND
VCC_3V3
GND
GND
GND
PF2_
OC
0C_I
NT_
RX
D0
PF3_
OC
0D_I
NT_
TXD
0
PD4
PD5
PD6
PD7
SPI I
NTE
RFA
CE
PA0
PA1
PA2
PA3
PA6
PA7
AR
EF
GPI
O/A
DC
PB2
PB3
GPI
O/A
DC
/DA
C
PF1
PF2
PF3
INT/
PWM
/GPI
O
PA4
PA5
GPI
O/A
DC
/AN
ALO
G C
OM
P
PB5
PB4
PB6
PB7
nRST
JTA
G
PD4_
SS
PD5_
MO
SI_X
CK
1
USB
D_N
USB
D_P
PA0_
AD
C0_
INT
PA1_
AD
C1_
INT
PA2_
AD
C2_
INT
PA3_
AD
C3_
INT
PA6
PA7
PB2
PB3
PA4
PA5
PB4_
TMS_
INT
PB5_
TDI_
INT
PB6_
TCK
_IN
T
PB7_
TDO
_IN
T
PF1_
OC
0B_I
NT_
XC
K0
PF2_
OC
0C_I
NT_
RX
D0
PF3_
OC
0D_I
NT_
TXD
0
GPIO/ADC/ANALOGCOMP
GPIO/ADC/DAC
GPIO/ADC
SPI INTERFACE
JTAG
INT/PWM/GPIO
nRST
nRST
PB0_
AR
EF_I
NT
PB0_
AR
EF_I
NT
PE4_
SYN
C_O
C1A
PE5_
OC
1B_I
NT
PDI_
DA
TA
PF0
1
2
3
4
EMI S
hiel
d
Z201
GND
1
GND
2
VDD
3
VDD
4
RSET/PDI_CLOCK
5
PD4/SS
6
PD5/MOSI/XCK1
7
PD6/MISO/RXD1/D-
8
PD7/SCK/TXD1/D+
9
PA5
10
PA4
11
GND
12
PD2/RXD0
13
PD3/TXD0
14
PD1/XCK0
15
PDI_DATA
16
PA6
17
PA7
18
PB3
19
PB2
20
PF1/OC0B/INT/XCK0
21
PF2/OC0C/INT/RXD0
22
PF3/OC0D/INT/TXD0
23
PB0/IAREF/INT
24
PA0/ADC0/INT
25
PA1/ADC1/INT
26
PA2/ADC2/INT
27
PA3/ADC3/INT
28
PB6/TCK/INT
30
PB4/TMS/INT
31
PB7/TDO/INT
32
PB5/TDI/INT
33
PE3
34
PE2/ASYNC
35
PE1/SCL
36
PE0/SDA
37
PE5/OC1B/INT
38
GND
41
GND
29
PE4/SYNC/OC1A
39
GND
42
PF0
40
ATZ
B-X
-0-2
56-4
-0-C
N
Z200
PE2
PE1
PE3
PE0
TWI
PE1_
SCL
PE2_
ASY
NC
PE3_
GPI
O
TWI
PE0_
SDA
PD2
PD1
PD3
UA
RT/
USA
RT
PD1_
XC
K0
PD2_
RX
D0
PD3_
TXD
0
UART/USART
PE4_
SYN
C_O
C1A
PE5_
OC
1B_I
NT
PF0
PDI_
DA
TA
PF0
PDI
PE4
PE5
PDI/G
PIO
PDI/GPIO
PD1_
XC
K0
PD2_
RX
D0
PD3_
TXD
0
PE0_
SDA
PE1_
SCL
PE2_
ASY
NC
PE3_
GPI
O
PIZ20001
PIZ20002
PIZ20003
PIZ20004
PIZ20005
PIZ20006
PIZ20007
PIZ20008
PIZ20009
PIZ200010
PIZ200011
PIZ200012
PIZ200013
PIZ200014
PIZ200015
PIZ200016
PIZ200017
PIZ200018
PIZ200019
PIZ200020
PIZ200021
PIZ200022
PIZ200023
PIZ200024
PIZ200025
PIZ200026
PIZ200027
PIZ200028
PIZ200029
PIZ200030
PIZ200031
PIZ200032
PIZ200033
PIZ200034
PIZ200035
PIZ200036
PIZ200037
PIZ200038
PIZ200039
PIZ200040
PIZ200041
PIZ200042
COZ200
PIZ20101PIZ20102
PIZ20103PIZ20104
COZ201
PIZ20001
PIZ20002
PIZ200012
PIZ200029
PIZ200041
PIZ200042
PIZ20101PIZ20102
PIZ20103PIZ20104
PIZ20005
NLnRST
POJTAG
PIZ200025NLPA00ADC00INT
POGPIO0ADC
PIZ200026NLPA10ADC10INT
POGPIO0ADC
PIZ200027NLPA20ADC20INT
POGPIO0ADC
PIZ200028NLPA30ADC30INT
POGPIO0ADC
PIZ200011
NLPA4
POGPIO0ADC0ANALOGCOMP
PIZ200010
NLPA5
POGPIO0ADC0ANALOGCOMP
PIZ200017
NLPA6
POGPIO0ADC
PIZ200018
NLPA7
POGPIO0ADC
PIZ200024NLPB00AREF0INT
POGPIO0ADC
PIZ200020
NLPB2
POGPIO0ADC0DAC
PIZ200019
NLPB3
POGPIO0ADC0DAC
PIZ200031NLPB40TMS0INT
POJTAG
PIZ200033NLPB50TDI0INT
POJTAG
PIZ200030NLPB60TCK0INT
POJTAG
PIZ200032NLPB70TDO0INT
POJTAG
PIZ200015
NLPD
10XC
K0
POUART0USART
PIZ200013
NLPD
20RX
D0
POUART0USART
PIZ200014
NLPD
30TX
D0
POUART0USART
PIZ20006
NLPD40SS
POSPI INTERFACE
PIZ20007
NLPD
50MO
SI0X
CK1
POSPI INTERFACE
PIZ200016
NLPD
I0DA
TA
POPDI0GPIO
PIZ200037NL
PE00
SDA
POTWI
PIZ200036NLPE10SCL
POTWI
PIZ200035NLPE20ASYNC
POTWI
PIZ200034NLPE30GPIO
POTWI
PIZ200039NL
PE40
SYNC
0OC1
A
POPDI0GPIO
PIZ200038NLPE50OC1B0INT
POPDI0GPIO
PIZ200040
NLPF0
POPDI0GPIO
PIZ200021
NLPF
10OC
0B0I
NT0X
CK0
POINT0PWM0GPIO
PIZ200022NL
PF20
OC0C
0INT
0RXD
0
POINT0PWM0GPIO
PIZ200023NL
PF30
OC0D
0INT
0TXD
0
POINT0PWM0GPIO
PIZ20008
NLUSBD0N
POSPI INTERFACE
PIZ20009
NLUSBD0P
POSPI INTERFACE
PIZ20003
PIZ20004
POGPIO0ADC
POGP
IO0A
DC0A
REF
POGPIO0ADC0PA0
POGPIO0ADC0PA1
POGPIO0ADC0PA2
POGPIO0ADC0PA3
POGPIO0ADC0PA6
POGPIO0ADC0PA7
POGPIO0ADC0ANALOGCOMP
POGP
IO0A
DC0A
NALO
GCOM
P0PA
4PO
GPIO
0ADC
0ANA
LOGC
OMP0
PA5
POGPIO0ADC0DAC
POGP
IO0A
DC0D
AC0P
B2PO
GPIO
0ADC
0DAC
0PB3
POINT0PWM0GPIO
POIN
T0PW
M0GP
IO0P
F1PO
INT0
PWM0
GPIO
0PF2
POIN
T0PW
M0GP
IO0P
F3
POJTAG
POJTAG0NRST
POJTAG0PB4
POJTAG0PB5
POJTAG0PB6
POJTAG0PB7
POPDI0GPIO
POPDI0GPIO0PDI
POPDI0GPIO0PE4
POPDI0GPIO0PE5
POPDI0GPIO0PF0
POSPI INTERFACE
POSP
I IN
TERF
ACE0
PD4
POSP
I IN
TERF
ACE0
PD5
POSP
I IN
TERF
ACE0
PD6
POSP
I IN
TERF
ACE0
PD7
POTWI
POTWI0PE0
POTWI0PE1
POTWI0PE2
POTWI0PE3
POUART0USART
POUART0USART0PD1
POUART0USART0PD2
POUART0USART0PD3
11
22
33
44
55
66
77
88
DD
CC
BB
AA
A08-1567
Xmega_212B_MCU.SchDoc
34
2/6/2014
4:23:39 PM
ATZB-X0-256-4-0-CN
ATMEL India
RMZ Millenia
MGR Road
Chennai
PAGE:
of
TITLE:
Document number:
Revision:5
Date:
OJS
MSK
*
VCC_3V3
GND
GND
GND
VCC_3V3
VCC_3V3
nRST
PC0_
TRX
_nR
ST
VCC_3V3
VCC_3V3
nRST
GND
GND
GND
VCC_3V3
VCC_3V3
CLKM
iPC
B R
ule
iPC
B R
ulePE
4_SY
NC
_OC
1A
PA5
PA4
PB3
PB2
PA6
PA7
PA3_
AD
C3_
INT
PA0_ADC0_INTPA1_ADC1_INTPA2_ADC2_INT
PB6_
TCK
_IN
TPB
7_TD
O_I
NT
PB5_
TDI_
INT
PB4_
TMS_
INT
PD4_SSPD5_MOSI_XCK1
PE5_
OC
1B_I
NT
PF1_
OC
0B_I
NT_
XC
K0
PF2_
OC
0C_I
NT_
RX
D0
PF3_OC0D_INT_TXD0
PC1_TRX_DIG2PC2_TRX_IRQPC3_TRX_SLP_TRPC4_TRX_SPI_SS
PC7_TRX_SPI_SCK
PC5_TRX_SPI_MOSIPC6_TRX_SPI_MISO
TOSC1
TOSC2
TRX
_nSE
L
TRX
_SC
K
TRX
_MO
SI
TRX
_MIS
O
TRX
_nR
ST
TRX
_IR
Q
TRX
_DIG
2
SLP_
TR
CLK
M
TRX
_I/F
PC4_
TRX
_SPI
_SS
PC7_
TRX
_SPI
_SC
K
TRX_I/F
PC5_
TRX
_SPI
_MO
SI
PC6_
TRX
_SPI
_MIS
O
PC1_
TRX
_DIG
2
PC2_
TRX
_IR
Q
PC3_
TRX
_SLP
_TR
PC0_
TRX
_nR
ST
TOSC1
TOSC2
100K
R20
0
USB
D_P
USBD_N
FC-1
35 3
2.76
8 kH
zX
C20
0
AN_VCC_3V3
VCC_3V3
BLM
15B
B22
1SN
1
L200
GND
GND
GND
GND
VCC_3V3
GND
GND_RF
BLM
15B
B22
1SN
1
L201
GND
100n C202
100n C203
100n C204
100n C205
+
4.7uF/10V C201
GND
100n
C20
8
GND
100n C206
GND
VCC_3V3
PA7(ADCA7/ACA7)
5
PB0(ADCB0/ACB0/AREFB)
6
PB1(ADCB1/ACB1)
7
PB2(ADCB2/ACB2/DACB0)
8
PB3(ADCB3/ACB3/DACB1)
9
PB4(ADCB4/ACB4/TMS)
10
PC4(SS/OC1A/OC0CLS)20
PC5(XCK1/MOSI/OC1B/OC0CHS)21
PC6(RXD1/MISO/OC0DLS)22
PC7(TXD1/SCK/OC0DHS)23
PD1(XCK0/OC0B)27
PD0(OC0A)26
PD3(TXD0/OC0D)29
PD4(SS/OC1A)30
PD5(MOSI/XCK1/OC1B)31
PD6(MISO/RXD1/D-)32
(D+/TXD1/SCK)PD7
33
GND24
VCC25
(OC0A)PF0
46
(OC0B/XCK0)PF1
47
(OC0C/RXD0)PF2
48
(OC0D/TXD0)PF349
(OC0A)PF450
PF551
PF654
PF755
VCC
45
GND
44
(ACA2/ADCA2)PA264
(ACA1/ADCA1)PA163
(AREFA/ACA0/ADCA0)PA062
AVCC61
GND60
(XTAL1)PR159
(XTAL2)PR058
PDI_CLK/RESET57
PA3(ADCA3/ACA3)
1
PA4(ADCA4/ACA4)
2
PA5(ADCA5/ACA5)
3
PA6(ADCA6/ACA6)
4
PB5(ADCB5/ACB5/TDI)
11
PB6(ADCB6/ACB6/TCK)
12
PB7(ADCB7/ACB7/TDO)
13
GND
14
VCC
15
PC0(SDA/OC0A/OC0ALS)
16
PC1(SCL/XCK0/OC0B/OC0AHS)17
PC2(RXD0/OC0C/OC0BLS)18
PC3(TXD0/OC0D/OC0BHS)19
GND
34
VCC
35
PD2(RXD0/OC0C)28
(OC0A/SDA)PE0
36
(OC0B/XCK0/SCL)PE1
37
(OC0C/RXD0)PE2
38
(OC0D/TXD0)PE3
39
(OC1A)PE4
40
(OC1B)PE5
41
PE6
42
PE7
43
VCC53
GND52
PDI_DATA56
PAD_GND65
ATx
meg
a256
A3U
-MH
U20
0GND
PF1
PF2
PF3
INT/
PWM
/GPI
O
PB5
PB4
PB6
PB7
nRST
JTA
G
PB4_
TMS_
INT
PB5_
TDI_
INT
PB6_
TCK
_IN
T
PB7_
TDO
_IN
T
PF1_
OC
0B_I
NT_
XC
K0
PF2_
OC
0C_I
NT_
RX
D0
PF3_
OC
0D_I
NT_
TXD
0
JTAG
INT/PWM/GPIO
PD4
PD5
PD6
PD7
SPI I
NTE
RFA
CE
PA0
PA1
PA2
PA3
PA6
PA7
AR
EF
GPI
O/A
DC
PB2
PB3
GPI
O/A
DC
/DA
C
PA4
PA5
GPI
O/A
DC
/AN
ALO
G C
OM
P
PD4_
SS
PD5_
MO
SI_X
CK
1
USB
D_N
USB
D_P
PA0_
AD
C0_
INT
PA1_
AD
C1_
INT
PA2_
AD
C2_
INT
PA3_
AD
C3_
INT
PA6
PA7
PB2
PB3
PA4
PA5
GPIO/ADC/ANALOGCOMP
GPIO/ADC/DAC
GPIO/ADC
SPI INTERFACE
nRST
PB0_
AR
EF_I
NT
PB0_
AR
EF_I
NT
PF0
PDI_DATA
CLKM
PE2
PE1
PE3
PE0
TWI
PE1_
SCL
PE2_
ASY
NC
PE3_
GPI
O
TWI
PE0_
SDA
PD2
PD1
PD3
UA
RT/
USA
RT
PD1_
XC
K0
PD2_
RX
D0
PD3_
TXD
0
UART/USART
PE4_
SYN
C_O
C1A
PE5_
OC
1B_I
NT
PF0
PDI_
DA
TA
PF0
PDI
PE4
PE5
PDI/G
PIO
PDI/GPIO
PE0_
SDA
PE1_
SCL
PE2_
ASY
NC
PE3_
GPI
O
PD1_XCK0PD2_RXD0PD3_TXD0
10 p
FC
200
10 p
FC
207
Plac
e xt
al c
ircui
t clo
ser
to M
CU
. Iso
late
from
di
gita
l sig
nals
.
Plac
e de
-cou
plin
g cl
oser
to
MC
UPl
ace
4.7u
F cl
oser
to
Vcc
inpu
t for
mod
ule
PIC20001
PIC20002
COC200
PIC20101 PIC20102COC201
PIC20201PIC20202 COC202PIC20301PIC20302 COC203
PIC20401PIC20402 COC204PIC20501PIC20502 COC205
PIC20601PIC20602 COC206
PIC20701
PIC20702
COC207
PIC20801PIC20802COC208
PIL20001
PIL20002
COL200
PIL20101
PIL20102CO
L201
PIR20001
PIR20002
COR200
PIU20001
PIU20002
PIU20003
PIU20004
PIU20005
PIU20006
PIU20007
PIU20008
PIU20009
PIU200010
PIU200011
PIU200012
PIU200013
PIU200014
PIU200015
PIU200016
PIU200017PIU200018PIU200019PIU200020
PIU200021PIU200022PIU200023PIU200024
PIU200025PIU200026PIU200027PIU200028
PIU200029PIU200030PIU200031PIU200032
PIU200033
PIU200034
PIU200035
PIU200036
PIU200037
PIU200038
PIU200039
PIU200040
PIU200041
PIU200042
PIU200043
PIU200044
PIU200045
PIU200046
PIU200047
PIU200048
PIU200049PIU200050PIU200051PIU200052PIU200053PIU200054PIU200055PIU200056PIU200057PIU200058PIU200059PIU200060PIU200061PIU200062PIU200063PIU200064PIU200065
COU200
PIXC20001 PIXC20002COXC200
PIL20001
PIU200059 POTRX0I0F
PIC20002
PIC20102PIC20201
PIC20301PIC20401
PIC20501PIC20601
PIC20702
PIC20801PIL20101
PIU200014
PIU200024
PIU200034
PIU200044
PIU200052PIU200060
PIU200065
PIL20102
PIU200058PIU200055PIU200054
PIU200051PIU200050
PIU200026
PIU20007
PIR20001
PIU200057NLnRST
POJTAG
PIU200062NLPA00ADC00INT
POGPIO0ADC
PIU200063NLPA10ADC10INT
POGPIO0ADC
PIU200064NLPA20ADC20INT
POGPIO0ADC
PIU20001
NLPA30ADC30INT
POGPIO0ADC
PIU20002
NLPA4
POGPIO0ADC0ANALOGCOMP
PIU20003
NLPA5
POGPIO0ADC0ANALOGCOMP
PIU20004
NLPA6
POGPIO0ADC
PIU20005
NLPA7
POGPIO0ADC
PIU20006
NLPB00AREF0INT
POGPIO0ADC
PIU20008
NLPB2
POGPIO0ADC0DAC
PIU20009
NLPB3
POGPIO0ADC0DAC
PIU200010
NLPB40TMS0INT
POJTAG
PIU200011
NLPB50TDI0INT
POJTAG
PIU200012
NLPB60TCK0INT
POJTAG
PIU200013
NLPB70TDO0INT
POJTAG
PIU200016
NLPC00TRX0nRST
POTRX0I0F
PIU200017 NLPC10TRX0DIG2
POTRX0I0F
PIU200018 NLPC20TRX0IRQ
POTRX0I0F
PIU200019 NLPC30TRX0SLP0TR
POTRX0I0F
PIU200020 NLPC40TRX0SPI0SS
POTRX0I0F
PIU200021 NLPC50TRX0SPI0MOSI POTRX0I0F
PIU200022 NLPC60TRX0SPI0MISO POTRX0I0F
PIU200023 NLPC70TRX0SPI0SCK POTRX0I0FPIU200027 NLPD10XCK0
POUART0USART
PIU200028 NLPD20RXD0
POUART0USART
PIU200029 NLPD30TXD0
POUART0USART
PIU200030 NLPD40SS
POSPI INTERFACE
PIU200031 NLPD50MOSI0XCK1
POSPI INTERFACE
PIU200056NLPDI0DATA
POPDI0GPIO
PIU200036
NLPE
00SD
A
POTWI
PIU200037
NLPE10SCL
POTWI
PIU200038
NLPE20ASYNC
POTWI
PIU200039
NLPE30GPIO
POTWI
PIU200040
NLPE
40SY
NC0O
C1A
POPDI0GPIO
PIU200041
NLPE50OC1B0INT
POPDI0GPIO
PIU200046
NLPF0
POPDI0GPIO
PIU200047
NLPF
10OC
0B0I
NT0X
CK0
POINT0PWM0GPIO
PIU200048
NLPF
20OC
0C0I
NT0R
XD0
POINT0PWM0GPIO
PIU200049NLPF30OC0D0INT0TXD0
POINT0PWM0GPIO
PIC20701
PIU200043
PIXC20002
PIC20001
PIU200042
PIXC20001
PIU200032 NLUSBD0N
POSPI INTERFACE
PIU200033
NLUSBD0P
POSPI INTERFACE
PIC20101PIC20202
PIC20302PIC20402
PIC20502PIC20602
PIC20802PIL20002
PIR20002
PIU200015
PIU200025
PIU200035
PIU200045
PIU200053PIU200061
POGPIO0ADC
POGP
IO0A
DC0AREF
POGPIO0ADC0PA0
POGPIO0ADC0PA1
POGPIO0ADC0PA2
POGPIO0ADC0PA3
POGPIO0ADC0PA6
POGPIO0ADC0PA7
POGPIO0ADC0ANALOGCOMP
POGP
IO0A
DC0A
NALO
GCOM
P0PA
4PO
GPIO
0ADC
0ANA
LOGC
OMP0
PA5
POGPIO0ADC0DAC
POGP
IO0A
DC0D
AC0P
B2PO
GPIO
0ADC
0DAC
0PB3
POINT0PWM0GPIO
POIN
T0PW
M0GP
IO0P
F1PO
INT0
PWM0
GPIO
0PF2
POIN
T0PW
M0GP
IO0P
F3
POJTAG
POJTAG0NRST
POJTAG0PB4
POJTAG0PB5
POJTAG0PB6
POJTAG0PB7
POPDI0GPIO
POPDI0GPIO0PDI
POPDI0GPIO0PE4
POPDI0GPIO0PE5
POPDI0GPIO0PF0
POSPI INTERFACE
POSP
I IN
TERF
ACE0
PD4
POSP
I IN
TERF
ACE0
PD5
POSP
I IN
TERF
ACE0
PD6
POSP
I IN
TERF
ACE0
PD7
POTRX0I0F
POTRX0I0F0CLKM
POTRX0I0F0SLP0TR
POTR
X0I0
F0TR
X0DI
G2PO
TRX0
I0F0
TRX0
IRQ
POTR
X0I0
F0TR
X0MI
SOPO
TRX0
I0F0
TRX0
MOSI
POTR
X0I0
F0TR
X0NR
STPO
TRX0
I0F0
TRX0
NSEL
POTR
X0I0
F0TR
X0SC
K
POTWI
POTWI0PE0
POTWI0PE1
POTWI0PE2
POTWI0PE3
POUART0USART
POUART0USART0PD1
POUART0USART0PD2
POUART0USART0PD3
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4.1 Handling Instructions The ZigBit Modules are fixed with an EMI Shield to ensure compliance to Emission and Immunity rules. This shield is galvanic and NOT air tight. So cleaning of the module with IPA / other similar agents is not advised. Humidity protection coating (conformal) will cause deviated RF behavior and coating material being trapped inside EMI Shield. So this should be avoided. For products requiring conformal coating, it is advised to suitably mask the ZigBit before applying the coating to rest of the ZigBit carrier board. To protect ZigBit from humidity, the housing of the product should ensure suitable Ingress Protection standards are complied with.
The MS-147 connector should never be exposed to Varnish / similar conformal coating material which will affect electrical connection on the surfaces of connector.
The in-built chip antenna has been tuned for the particular design.
4.2 General Recommendations • Metal enclosure should not be used. Using low profile enclosure might also affect antenna tuning.
• Placing high profile components next to antenna should be avoided
• Having holes/vias punched around the periphery of the board eliminates parasitic radiation from the board edges also distorting antenna pattern
• ZigBit module should not be placed next to consumer electronics which might interfere with ZigBit's RF frequency band
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5. Persistence Memory A dedicated memory space is allocated to store product specific information and called the Persistence Memory. The organization of the persistence memory is as follows:
Table 5-1. Persistence Memory
Data Size
Structure Revision 2 bytes
MAC address(1) 8 bytes
Board information overall 49 bytes
Board information – PCBA Name 30 bytes
Board information – PCBA Serial number 10 bytes
Board information – PCBA Atmel Part Number 8 bytes
Board information – PCBA Revision 1 byte
Reserved 3 bytes
XTAL Calibration Value 1 byte
Reserved 7 bytes
Reserved 4 bytes
CRC 1 byte
In ATZB-X0-256-4-0-CN, the persistence memory is stored in User Signature Row of ATxmega256A3U Microcontroller starting from address 0x0000. This section is not erased by chip erase and requires a dedicated erase command.
The user signature row is a separate memory section that is fully accessible (read and write) from application software and external programmers. See section “Read User Signature Row / Production Signature Row” under section “NVM Flash Commands” in XMEGA AU manual [1] for details in reading the user signature data from application software.
Note: 1. The MAC address stored inside the MCU is a uniquely assigned ID for each ZigBit and owned by Atmel. User of the ZigBit application can use this unique MAC ID to address the ZigBit in end-applications. The MAC ID can be read from the ZigBit using the Performance Analyzer Application that is supplied through Atmel Studio Gallery Extension.
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6. Ordering Information
Table 6-1. Ordering Information
Part number Description ATZB-X0-256-4-0-CN 900 MHz IEEE802.15.4/ZigBee OEM module based on ATXMEGA256A3U MCU and
AT86RF212B Transceiver with MS-147 test connector and chip antenna, Single unit ATZB-X0-256-4-0-CNR 900 MHz IEEE802.15.4/ZigBee OEM module based on ATXMEGA256A3U MCU and
AT86RF212B Transceiver with MS-147 test connector and chip antenna, Tape & Reel
Note: Tape & Reel quantity: 200.
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7. Agency Certifications
7.1 United States (FCC) This equipment complies with Part 15 of the FCC rules and regulations. To fulfill FCC Certification requirements, an OEM manufacturer must comply with the following regulations:
1. The ATZB-X0-256-4-0-CN modular transmitter must be labeled with its own FCC ID number, and, if the FCC ID is not visible when the module is installed inside another device, then the outside of the device into which the module is installed must also display a label referring to the enclosed module. This exterior label can use wording such as the following:
IMPORTANT: Contains FCC ID: VW4A091745. This equipment complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation (FCC 15.19).
The internal antenna used for this mobile transmitter must provide a separation distance of at least 20cm from all persons and must not be collocated or operating in conjunction with any other antenna or transmitter.
Installers must be provided with antenna installation instructions and transmitter operating conditions for satisfying RF exposure compliance. This device is approved as a mobile device with respect to RF exposure compliance, and may only be marketed to OEM installers. Use in portable exposure conditions (FCC 2.1093) requires separate equipment authorization.
IMPORTANT: Modifications not expressly approved by this company could void the user's authority to operate this equipment (FCC section 15.21).
IMPORTANT: This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instruction manual, may cause harmful interference to radio communications. Operation of this equipment in a residential area is likely to cause harmful interference in which case the user will be required to correct the interference at his own expense (FCC section 15.105).
7.2 European Union (ETSI) The ATZB-X0-256-3-0-C Module has been certified for use in European Union countries. If these modules are incorporated into a product, the manufacturer must ensure compliance of the final product to the European harmonized EMC and lowvoltage/safety standards. A Declaration of Conformity must be issued for each of these standards and kept on file as described in Annex II of the R&TTE Directive.
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Furthermore, the manufacturer must maintain a copy of the modules' documentation and ensure the final product does not exceed the specified power ratings, antenna specifications, and/or installation requirements as specified in the user manual. If any of these specifications are exceeded in the final product, a submission must be made to a notified body for compliance testing to all required standards.
IMPORTANT: The 'CE' marking must be affixed to a visible location on the OEM product. The CE mark shall consist of the initials "CE" taking the following form:
The CE marking must have a height of at least 5mm except where this is not possible on account of the nature of the apparatus.
The CE marking must be affixed visibly, legibly, and indelibly.
More detailed information about CE marking requirements you can find at "DIRECTIVE 1999/5/EC OF THE EUROPEAN PARLIAMENT AND OF THE COUNCIL" on 9 March 1999 at section 12.
7.3 Industry Canada (IC) Compliance Statements This device complies with Industry Canada licence-exempt RSS standard(s). Operation is subject to the following two conditions: (1) this device may not cause interference, and (2) this device must accept any interference, including interference that may cause undesired operation of the device. Le présent appareil est conforme aux CNR d'Industrie Canada applicables aux appareils radio exempts de licence. L'exploitation est autorisée aux deux conditions suivantes: (1) l'appareil ne doit pas produire de brouillage, et (2) l'utilisateur de l'appareil doit accepter tout brouillage radioélectrique subi, même si le brouillage est susceptible d'en compromettre le fonctionnement. This equipment complies with radio frequency exposure limits set forth by Industry Canada for an uncontrolled environment. This equipment should be installed and operated with minimum distance 20cm between the device and the user or bystanders. Cet équipement est conforme aux limites d'exposition aux radiofréquences définies par Industrie Canada pour un environnement non contrôlé. Cet équipement doit être installé et utilisé avec un minimum de 20cm de distance entre le dispositif et l'utilisateur ou des tiers. CAUTION: Any changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment. The OEM integrator is still responsible for testing their end-product for any additional compliance requirements required with this module installed (for example, digital device emissions, PC peripheral requirements, etc.). This Module is labelled with its own IC ID. If the IC ID Certification Number is not visible while installed inside another device, then the device should display the label on it referring the enclosed module. In that case, the final end product must be labelled in a visible area with the following: “Contains Transmitter Module IC: 11019A-091745” OR “Contains IC: 11019A-091745” Ce module est étiqueté avec son propre ID IC. Si le numéro de certification IC ID n'est pas visible lorsqu'il est installé à l'intérieur d'un autre appareil, l'appareil doit afficher l'étiquette sur le module de référence ci-joint. Dans ce cas, le produit final doit être étiqueté dans un endroit visible par le texte suivant: “Contains Transmitter Module IC: 11019A-091745” OR “Contains IC: 11019A-091745”
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8. Revision History Doc. Rev. Date Comments
42268A 04/2014 Initial document release
Atmel Corporation 1600 Technology Drive San Jose, CA 95110 USA Tel: (+1)(408) 441-0311 Fax: (+1)(408) 487-2600 www.atmel.com
Atmel Asia Limited Unit 01-5 & 16, 19F BEA Tower, Millennium City 5 418 Kwun Tong Road Kwun Tong, Kowloon HONG KONG Tel: (+852) 2245-6100 Fax: (+852) 2722-1369
Atmel Munich GmbH Business Campus Parkring 4 D-85748 Garching b. Munich GERMANY Tel: (+49) 89-31970-0 Fax: (+49) 89-3194621
Atmel Japan G.K. 16F Shin-Osaki Kangyo Building 1-6-4 Osaki, Shinagawa-ku Tokyo 141-0032 JAPAN Tel: (+81)(3) 6417-0300 Fax: (+81)(3) 6417-0370
© 2014 Atmel Corporation. All rights reserved. / Rev.: 42268A−WIRELESS−04/2014
Atmel®, Atmel logo and combinations thereof, AVR®, BitCloud®, Enabling Unlimited Possibilities®, ZigBit®, XMEGA®, and others are registered trademarks or trademarks of Atmel Corporation or its subsidiaries. Other terms and product names may be trademarks of others.
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