Microchip Technology AVRRZUSBSTICK AVR RZUSBSTICK User Manual avr2016D
Atmel Norway AS AVR RZUSBSTICK avr2016D
User Manual
AVR2016: RZRAVEN Hardware User's Guide
Features
• Development kit for the AT86RF230 radio transceiver and AVR® microcontroller.
• CE, ETSI and FCC approved.
• LCD module (AVRRAVEN):
- AT86RF230 radio transceiver with high gain PCB antenna.
- Dual AVR microcontrollers.
- Dynamic Speaker and microphone.
- Atmel Serial Dataflash®.
- User IO section:
• USART
• GPIO
• Relay Driver
- Powered by battery or external supply:
• 5V to 12V external supply.
• USB module (RZUSBSTICK):
- AT86RF230 radio transceiver with miniature PCB antenna.
- AVR microcontroller with integrated Full Speed USB interface.
- External memory interface.
1 Introduction
The RZRAVEN is a development kit for the AT86RF230 radio transceiver and the
AVR microcontroller. It serves as a versatile and professional platform for
developing and debugging a wide range of RF applications; spanning from: simple
point-to-point communication through full blown sensor networks with numerous
nodes running complex communication stacks. On top of this, the kit provides a
nice human interface, which spans from PC connectivity, through LCD and audio
input and output.
Figure 1-1. The RZRAVEN Kit Modules
8-bit
Microcontrollers
Application Note
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2 General
The RZRAVEN kit is built from one RZUSBSTICK module and two AVRRAVEN
modules. See Figure 2-1 to Figure 2-4 for further details.
The complete schematics and Gerber files are available from the compressed archive
accompanying this application note.
Figure 2-1 Assembly drawing AVRRAVEN - front view.
Figure 2-2 Assembly drawing AVRRAVEN - back view.
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Figure 2-3 Assembly drawing RZUSBSTICK - front view.
Figure 2-4 Assembly drawing RZUSBSTICK - back view
3 The AVRRAVEN Module
Figure 3-1 AVRRAVEN overview
The AVRRAVEN hardware is based on 2 microcontroller and one radio transceiver
chip. The ATmega3290P handles the sensors and the user interface and the
ATmega1284P handles the AT86RF230 radio transceiver and the RF protocol stacks.
The MCUs and the radio communicate via serial interfaces.
For hardware details please refer to Appendix A for the complete AVRRAVEN
schematics.
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3.1 AVR Microcontrollers
Two AVR microcontrollers are found on the AVRRAVEN module. An ATmega1284P
is connected to the AT86RF230 radio transceiver, and an ATmega3290P is driving
the LCD. Both these devices are selected from the AVR picoPower family, something
that ensures minimal power consumption and operation down to 1.8 Volts. Universal
Synchronous and Asynchronous serial Receiver and Transmitter (USART) is used as
an inter processor communication bus.
3.2 Atmel Radio Transceiver
The AT86RF230 is a 2.4GHz radio transceiver that is tailored for a wide range of
wireless applications. Low power consumption and market leading RF performance
makes it an excellent choice for virtually any type of networking device. Support for
IEEE 802.15.4
TM
(Automatic acknowledge of packets, address filtering and automatic
channel access) type of applications is available through an enhanced layer of
functionality on top of the basic radio transceiver.
3.3 Antenna description
The antenna on the AVRRAVEN is a 100 loop antenna with a net peak gain of
about 5dB.
3.4 LCD
The LCD found on the AVRRAVEN module is a full custom 160-segment display
tailored for the RZRAVEN kit (See Figure 3-2 for a quick reference). It contains a 7
segments text area; four segment number area and numerous handy symbols. In
particular pay attention to the bird looking symbol. It is symbolizing the two black
scouting ravens of Norse god Odin; Hugin (Thought) and Munin (Memory). The saga
says that they flew around the world and reported news back to Odin at night.
Underneath the raven segment’s “eye” there is a red LED capable of soft-blinking;
this may be used to indicate the AVRRAVEN’s search for “news” on the air interface.
A full segment map can be found in Appendix C and in the schematics folder in the
compressed archive file accompanying this application note. The LCD is driven
directly from the connected ATmega3290P.
Figure 3-2 AVRRAVEN - LCD Segments
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3.5 Speaker
An 8 speaker is provided. The ATmega3290P controls all audio. The signal source
is the TIMER1’s PWM output and the signal is shaped via a low-pass filter and
amplified by a Class-D amplifier. Pulling PORTE7 low activates the active filter and
providing a PWM signal on PORTB5 activates the amplifier.
3.6 Microphone
The AVRRAVEN’s microphone is connected to the ATmega3290P ADC channel 0.
The signal is amplified and low-pass filtered. Pulling PORTE7 low activates the
microphone circuit.
3.7 Serial Dataflash®
A 16-Mbits Atmel Serial Dataflash (AT45DB161D) is connected to the
ATmega3290P’s Serial Peripheral Interface (SPI). This storage is used for safe
firmware images, sounds and general-purpose parameters. See the firmware
documentation for an overview of occupied sectors, and those available to the end
user. Even with a couple of safe firmware images for the two microcontrollers there is
plenty space left for the end user. Please note that the serial Dataflash will operate
properly when the voltage is above 2.5 Volts while the rest of the design will operate
down to 1.8Volts
3.8 Serial EEPROM
A 2-Kbits Atmel Serial EEPROM (AT24C02B) is connected to the ATmega1284P’s
two-wire interface (TWI). This storage is write protected by hardware and can only be
read. The storage contains important configuration and calibration data that should
not be unintentionally overwritten. Information such as a unique EUI 64-bit address
can be found her-in. A rich set of access functions and the parameter map is given in
the RZRAVEN firmware documentation.
3.9 Real Time Clock
Separate 32768 Hz clock crystals are connected to the ATmega3290P’s and the
ATmega1284P’s asynchronous timer interfaces. This allows an application to
implement a real time clock (RTC) to keep track of time when sleep modes are used
to reduce the power consumption. This is especially important for battery-operated
nodes.
3.10 NTC
A NTC is connected to the ATmega3290P’s Analog to Digital Converter (ADC)
channel 4. This NTC can be used to measure the temperature in the surroundings of
the AVRRAVEN. The NTC can be found below the joystick, close to J401. The JTAG
interface must be disabled when using the temperature sensor. When running the
AVRRAVEN from an external power source the onboard voltage regulator may heat
the temperature sensor giving faulty reading. To avoid this the sensor NTC may be
soldered off and relocated using short wires. If a higher level of accuracy is required
the users may also calibrate the sensor by adjusting the temperature lookup table in
firmware.
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3.11 Power Supply
The AVRRAVEN can be powered either from batteries or an external 5 to 12 Volts
DC source. The power source is selected by the position of the jumper located
immediately to the right of the LCD (See the figure below for a reference). Polarity
protection is provided when using an external power source.
The AVRRAVEN has been designed to run from two 1.5V LR44 battery cells.
An onboard voltage regulator makes it possible to run power the AVRRAVEN from a
5 to 12 Volts DC source. The external voltage is applied to the two leftmost pins in the
user IO area (J401). The ATmega3290P’s ADC channel 2 is connected to a voltage
divider and the external voltage supply interface. This way it is possible for the
application to monitor the external operating voltage.
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3.12 Interfaces
The AVRRAVEN module has multiple interfaces that can be used for serial
communication, interaction with external sensors and control units such as relays and
of course programming and debugging.
Figure 3-3 AVRRAVEN User Interfaces
Table 3-1. Interfaces available on J401
Pin number Function Comment
1 Ext. power supply, 5-12V input External power input
2 Ext. power supply 0V Connected to internal 0V
3 Relay coil positive Relay driver circuit positive
4 Relay coil negative Relay driver circuit negative
5 Voltage measure input, 0-Vcc*5 Analog input via 47k/10k voltage divider
6 Voltage measure input, 0-Vcc Analog input directly to ADC input.
7 Vcc Connected to the VCC net directly
8 User IO #1
9 User IO #2
10 User IO #3
11 User IO #4
Digital I/O, may interface an LED or a
switch directly. On-board 470 series
resistors and 10k pull-ups are provided.
Pin change interrupts, TWI and USI is
also available on these pins.
12 Common Connected to internal 0V
Care should be taken when connecting to the AVRRAVEN’s interfaces, since there is
no protection circuitry provided. Damage to the MCUs or other circuits may be the
result of ESD spark, short circuits, polarity or over-voltage faults.
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3.12.1 Programming Interface
Both the ATmega3290P and ATmega1284P can be programmed using either the
JTAG or ISP interface. JTAG programming can be facilitated by connecting a JTAG
ICE mkII to the 50-mil pin header J301 (ATmega3290P) and J204 (ATmega1284P). A
total of 5 50-mil pin headers and one 50-mil to 100-mil converter are supplied with the
RZRAVEN kit.
ISP programming can be performed by connecting an ISP enabled AVR programming
tool to the pin header J302 (ATmega3290P) and J205 (ATmega1284P). AVR tools
like STK500, AVRISP mkII and JTAGICE mkII can be used for this.
The AVRRAVEN does not come with these headers mounted. So it is up to the user
populating these. Wires could also be soldered in instead of the dual row headers.
3.12.2 Relay Interface
A relay interface (Relay Positive and Negative) is available through J401. This
interface can be used with the AVRRAVEN running from external power. A switching
transistor is connected to PB6 on the ATmega3290P so that sufficient current can be
provided to the relay being driven. An external power source must be used if the relay
option is required. The AVRRAVEN must then be supplied with the rated voltage of
the relay.
3.13 Voltage Measurement Interface
Two of the pins in header J401 can be used for external voltage measurements,
however only one at the time. The possible voltage ranges are 0 to VCC or via a
voltage divider giving an approximate range of 0 to five times VCC. A simple voltage
divider is implemented to scale the measurement voltage. A diode bridge is also used
to prevent reverse polarity and to protect the ATmega3290P’s ADC channel 3.
3.13.1 GPIO
Both the ATmega3290P and ATmega1284P are high pin count devices, and a
number of these are not used. These pins are available through the user IO headers;
J401, J201, J202 and J203. See Table 3-2 and Table 3-3 for further details.
Be aware that these pins do not have level converters and should thus not be
connected directly to an application board running on a different voltage level than the
AVRRAVEN.
Table 3-2. ATmega3290P User IO
ATmega3290P Port Pin PCB Connection Comment
PE3 J401 –8 Via 470 series resistor
and10k pull-up
PE4 J401-9 Via 470 series resistor
and10k pull-up
PE5 J401-10 Via 470 series resistor
and10k pull-up
PE6 J401-11 Via 470 series resistor
and10k pull-up
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Table 3-3. ATmega1284P User IO
ATmega1284P Port Pin PCB Connection Comment
PC0 J201-1 TWI SCL.
Connected to serial EEPROM
PC1 J201-2 TWI SDA.
Connected to serial EEPROM
PC2 J201-3 JTAG TCK.
PC3 J201-4 JTAG TMS.
PC4 J201-5 JTAG TDO.
PC5 J201-6 JTAG TDI.
N.C. J201-7 Populate R204 to connect to
PC6. RTC Xtal XC202 must
then be removed.
N.C. J201-8 Populate R205 to connect to
PC6. RTC Xtal XC202 must
then be removed.
PD0 J202-1 RXD0 Inter processor
communication.
PD1 J202-2 TXD0 Inter processor
communication.
PD2 J202-3 DIO or RXD1.
PD3 J202-4 DIO or TXD1.
PD4 J202-5 DIO.
PD5 J202-6 DIO.
PB2 J202-7 DIO. NB: NOT PD6!
PD7 J202-8 DIO.
PA0 J203-1 DIO or ADC Channel 0.
PA1 J203-2 DIO or ADC Channel 1.
PA2 J203-3 DIO or ADC Channel 2.
PA3 J203-4 DIO or ADC Channel 3.
PA4 J203-5 DIO or ADC Channel 4.
PA5 J203-6 DIO or ADC Channel 5.
PA6 J203-7 DIO or ADC Channel 6.
PA7 J203-8 DIO or ADC Channel 7.
Additional interfaces PCB Connection Comment
External power J201-10
J202-10
J203-10
Connected to J401-1
0V J201-9
J202-9
J203-9
Connected to J401-2
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4 The AVR RZUSBSTICK Module
Figure 4-1 RZUSBSTICK overview
The AVR RZUSBSTICK hardware is based a USB microcontroller and a radio
transceiver chip. The AT90USB1287 microcontroller handles the USB interface, the
AT86RF230 radio transceiver and the RF protocol stacks.
For hardware details please refer to Appendix D for the complete AVR RZUSBSTICK
schematics.
4.1 AVR Microcontroller
The AT90USB1287 is a device in the family of AVRs with a low and full speed USB
macro with device, host and On-the-go (OTG) capabilities.
4.2 Atmel Radio Transceiver
The AT86RF230 is a 2.4GHz radio transceiver that is tailored for a wide range of
wireless applications. Low power consumption and market leading RF performance
makes it an excellent choice for virtually any type of networking device. Support for
IEEE 802.15.4 (Automatic acknowledge of packets, address filtering and automatic
channel access) type of applications is available through an enhanced layer of
functionality on top of the basic radio transceiver.
4.3 Antenna description
The antenna on the RZUSBSTICK is a folded dipole antenna with a net peak gain of
0dB
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4.4 Interfaces
Figure 4-2 RZUSBSTICK Interfaces - front.
Figure 4-3 RZUSBSTICK Interfaces - back
4.4.1 External Memory Interface
When necessary the AT90USB1287’s 8k Bytes of internal SRAM can be extended
through the AVR external memory interface. The suggested external SRAM is 32k
Bytes and is available from address 0x8000 to 0xFFFF giving a total of 40k Bytes
when assembled.
Suggested latch and RAM:
• 74AHC573PW.
• BS62UV256TCP-10
.
4.4.2 Serial Interface
The USART on the AT90USB1287 is routed to J4 on the RZRAVEN’s backside. J4 is
implemented as three large pads (RX-TX-GND) where the user can solder in wires
and route the signal to his or her preference. The RX-TX signals are TTL level, so an
external level converter must be connected if RS232 levels are necessary.
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4.4.3 Programming Interface
A JTAG interface is provided for the AT90USB1287 microcontroller. The interface is
available through a 50-mil spaced 10-pin dual row header. The RZRAVEN does not
come with the header mounted. So it is up to the user populating it. Wires could also
be soldered in instead of the dual row headers. A total of 5 50-mil pin headers and
one 50-mil to 100-mil converter are supplied with the RZRAVEN kit.
4.4.4 LEDs
4 LEDs is assembled on the board:
Table 4-1. AT90USB1287 LEDs
LED AT90USB1297 Port Pin Comment
Blue (D1) PORTD7 Turn LED on by pulling port pin high
Red (D2) PORTD5 Turn LED on by pulling port pin low
Green (D3) PORTE7 Turn LED on by pulling port pin low
Orange (D4) PORTE6 Turn LED on by pulling port pin low
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5 Appendix A: AVRRAVEN Schematics
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6 Appendix B: AVRRAVEN Bill of materials
Table 6-1. AVRRAVEN BOM
Qty
Designator Description Manufacturer Part #
5 C205, C206,
C207, C220,
C221
Ceramic capacitor, SMD
0402, NP0, 50V, +/-
0.25pF
1.2p
2 C201, C204 Ceramic capacitor, SMD
0402, NP0, 50V, +/-5% 12p
3 C413, C414,
C415 Ceramic capacitor, SMD
0402, NP0, 50V, +/-10% 100p
1 C404 Ceramic capacitor, SMD
0402, X7R, 25V, +/-10% 4.7n
14 C208, C301,
C405, C407,
C408, C409,
C410, C411,
C412, C416,
C417, C420,
C421, C503
Ceramic capacitor, SMD
0402, X7R, 25V, +/-10% 10n
2 C502, C504 Ceramic capacitor, SMD
0805, Y5V, 10V, -20/+80
%
4.7u
12 C211, C212,
C213, C214,
C215, C303,
C304, C305,
C306, C307,
C418, C501
Ceramic capacitor, SMD
0402, X7R, 16V, +/-10% Kemet C0402C104K4RACTU
10 C202, C203,
C209, C210,
C302, C401,
C402, C403,
C406, C505
Ceramic capacitor, SMD
0402, X5R, 6.3V, +/-10% Kemet C0402C105K9PAC
4 R201, R208,
R209, R415 Thick film resistor, SMD
0402, 1/16W, 1% 0R
7 R203, R306,
R425, R427,
R428, R430,
R434
Thick film resistor, SMD
0402, 1/16W, 1% 470R
5 R303, R401,
R404, R405,
R417
Thick film resistor, SMD
0402, 1/16W, 1% 1k
1 R502 Thick film resistor, SMD
0402, 1/16W, 1% 1.5k
7 R304, R411,
R412, R413,
R414, R432,
R435
Thick film resistor, SMD
0402, 1/16W, 1% 3k
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Qty
Designator Description Manufacturer Part #
1 R410 Thick film resistor, SMD
0402, 1/16W, 1% 3.3k
17 R202, R206,
R210, R211,
R212, R301,
R302, R307,
R402, R406,
R407, R408,
R421, R422,
R423, R424,
R503
Thick film resistor, SMD
0402, 1/16W, 1% 10k
1 R305 Thick film resistor, SMD
0402, 1/16W, 1% 47k
10 R308, R309,
R310, R409,
R416, R419,
R426, R429,
R501, R504
Thick film resistor, SMD
0402, 1/16W, 1% 100k
3 R403, R418,
R420 Thick film resistor, SMD
0402, 1/16W, 1% 470k
1 R431 NTC Thermistor
100kOhm Murata NCP18WF104J03RB
2 L401, L402 SMD RF inductor 0805 Murata BLM21PG300SN1D
2 L201, L501 SMD RF inductor 0805. Murata BLM21AG102SN1D
2 L202, L203 RF Inductor, 2.7nH,
0,17ohm, 300mA, 0402 Johanson
Technology L-07C2N7SV6T
3 D401, D403,
D408 Dual schottky diode, ST BAT54SWFILM
1 D501 Dual Schottky diode, Philips 1PS70SB15
1 D404 Bidirectional Transient
suppression diode, 600W
ST SM6T12CA
1 Q501 General purpose SMD
BJT dual NPN-PNP Philips BC847BPN
1 U303 16-megabit 2.7-3.6 volt
DataFlash ATMEL AT45DB161D-SU
1 U201 2.4GHz ZigBee/802.15.4
tranceiver ATMEL AT86RF230-ZU
1 U203 2kbit Serial (TWI)
EEPROM, AT24C02B,
1.8-5V
ATMEL AT24C02B-TSU-T
1 U501 LDO 3.3V 150mA SOT23-
5 (cer. cap) Texas Instruments
LP2985A-33DBV
1 U402 LMV934MT 1V8 Quad National
Semiconductor LMV934MT
1 U204 AVR 8-bit RISC MCU ATMEL ATmega1284PV-10MU
1 U301 AVR 8-bit RISC MCU ATMEL ATmega3290PV-10AU
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Qty
Designator Description Manufacturer Part #
1 U403
TS2007 3W class D audio
amp. ST TS2007IQT
2 XC202, XC301 32.768kHz SMD crystal,
85SMX style Rakon Ltd LF XTAL016207
1 SP401 PC board speaker, SMD
mount Veco Vansonic 20CS08KQ-150ND
1 XC201 16MHz uXtal GSX-323,
2.0 x 2.5 mm SMD 10ppm
Golledge GSX-323/111BF 16.0MHz
1 U401 Citizen 4.2x4.2mm SMD
electmic Citizen CHM-04C-03
1 SW301 ALPS 4-directional switch
with center push function ALPS SKRHABE010
1 PCB101 AVRRAVEN PCB A08-0402
2 J501, J502 LR44 battery clip, SMD Keystone Corp. 2996TR
1 J503 1x3 pin header, 2 mm
pitch, THM SAMTEC TMM-103-01-L-S
1 JS501 Jumper cap for 2.00mm
pinheader SAMTEC 2SN-BK-G
2 BT501, BT502 LR44 coin-cell battery
1 D301 LED, Red, SMD 0603 Lumex SML-LX0603SRW-TR
1 U302 AVRRAVEN LCD Orient Display 0710091B
7 Appendix C: AVRRAVEN LCD
Figure 7-1 AVRRAVEN Segments
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Table 7-1. LCD Segment description and mapping
Bit
Registers 7 6 5 4 3 2 1 0 COM
SEG39 SEG38
SEG37 SEG36 SEG35 SEG34
SEG33
SEG32
LCDDR19
8A 8B 9A 9B 10A 10B 11A 11B
SEG31 SEG30
SEG29 SEG28 SEG27 SEG26
SEG25
SEG24
LCDDR18
PAN ID RX R1 B1 7C SPK 7M 7D
SEG23 SEG22
SEG21 SEG20 SEG19 SEG18
SEG17
SEG16
LCDDR17
6C TONE 6M 6D 5C BELL 5M 5D
SEG15 SEG14
SEG13 SEG12 SEG11 SEG10
SEG9 SEG8
LCDDR16
4C °C 4M 4D 3C °F 3M 3D
SEG7 SEG6 SEG5 SEG4 SEG3 SEG2 SEG1 SEG0
LCDDR15
2C PM 2M 2D 1C AM 1M 1D
COM3
SEG39 SEG38
SEG37 SEG36 SEG35 SEG34
SEG33
SEG32
LCDDR14
8F 8G 9F 9G 10F 10G 11F 11G
SEG31 SEG30
SEG29 SEG28 SEG27 SEG26
SEG25
SEG24
LCDDR13
IP SUN TX B4 7H 7N 7L 7E
SEG23 SEG22
SEG21 SEG20 SEG19 SEG18
SEG17
SEG16
LCDDR12
6H 6N 6L 6E 5H 5N 5L 5E
SEG15 SEG14
SEG13 SEG12 SEG11 SEG10
SEG9 SEG8
LCDDR11
4H 4N 4L 4E 3H 3N 3L 3E
SEG7 SEG6 SEG5 SEG4 SEG3 SEG2 SEG1 SEG0
LCDDR1
2H 2N 2L 2E 1H 1N 1L 1E
COM2
SEG39 SEG38
SEG37 SEG36 SEG35 SEG34
SEG33
SEG32
LCDDR9
8E 8C 9E 9C 10E 10C 11E 11C
SEG31 SEG30
SEG29 SEG28 SEG27 SEG26
SEG25
SEG24
LCDDR8
MINUS E1 Z-LINK B3 7B 7K 7J 7G
SEG23 SEG22
SEG21 SEG20 SEG19 SEG18
SEG17
SEG16
LCDDR7
6B 6K 6J 6G 5B 5K 5J 5G
SEG15 SEG14
SEG13 SEG12 SEG11 SEG10
SEG9 SEG8
LCDDR6
4B 4K 4J 4G 3B 3K 3J 3G
SEG7 SEG6 SEG5 SEG4 SEG3 SEG2 SEG1 SEG0
LCDDR5
2B 2K 2J 2G 1B 1K 1J 1G
COM1
SEG39 SEG38
SEG37 SEG36 SEG35 SEG34
SEG33
SEG32
LCDDR4
8D COLON
9D POINT 10D E3 11D E2
SEG31 SEG30
SEG29 SEG28 SEG27 SEG26
SEG25
SEG24
LCDDR3
RAVEN+AVR
MOON
Z_ZIGBEE
B2 MIC 7A 7I 7F
SEG23 SEG22
SEG21 SEG20 SEG19 SEG18
SEG17
SEG16
LCDDR2
ATT! 6A 6I 6F KEY 5A 5I 5F
SEG15 SEG14
SEG13 SEG12 SEG11 SEG10
SEG9 SEG8
LCDDR1
R5 4A 4I 4F R4 3A 3I 3F
SEG7 SEG6 SEG5 SEG4 SEG3 SEG2 SEG1 SEG0
LCDDR0
R3 2A 2I 2F R2 1A 1I 1F
COM0
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8 Appendix D: RZUSBSTICK Schematics
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9 Appendix E: RZUSBSTICK Bill of materials
Table 9-1. RZUSBSTICK BOM
Qt
Designator Description Manufacturer Part #
1 C18 Ceramic capacitor, SMD
0402, NP0, 50V, +/-.25pF
1.5p
2 C11, C12 Ceramic capacitor, SMD
0402, NP0, 50V, +/-5% 12p
2 C22, C23 Ceramic capacitor, SMD
0402, NP0, 50V, +/-5% 18p
2 C5, C6 Ceramic capacitor, SMD
0402, NP0, 50V, +/-5% 22p
2 C2, C8 Ceramic capacitor, SMD
0402, X7R, 25V, +/-10% 10n
1 C4 Ceramic capacitor, SMD
0402, X7R, 16V, +/-10% Kemet C0402C104K4RACTU
12
C1,C10,C13,C16,
C17,C21,C24, C25,
C26, C3, C7, C9 Ceramic capacitor, SMD
0402, X5R, 6.3V, +/-10% Kemet C0402C105K9PAC
2 R15, R16 Thick film resistor, SMD
0402, 1/16W, 1% 0R
2 R3, R8 Thick film resistor, SMD
0402, 1/16W, 1% 22R
5 R1,R10,R5,R6,R7 Thick film resistor, SMD
0402, 1/16W, 1% 470R
6 R12, R13, R14, R2,
R4, R9 Thick film resistor, SMD
0402, 1/16W, 1% 10k
1 L1 SMD RF inductor 0805. Murata BLM21AG102SN1D
1 Q1 General purpose NPN. Philips BC847W
1 U5 Transient Suppressor, TI SN65220YZBR
1 U1 AVR 8-
bit RISC MCU with
USB, QFN64 package ATMEL AT90USB1287-16MU
1 U2 2.4GHz ZigBee/802.15.4
tranceiver ATMEL AT86RF230-ZU
1 U3 2kbit Serial (TWI)
EEPROM, AT24C02B, ATMEL AT24C02B-TSU-T
1 U4 LDO 3.3V 150mA TI LP2985A-33DBV
1 XC1 16MHz uXtal GSX-323, Golledge GSX-323/111BF 16.0MHz
1 XC2 8.0MHz Xtal GSX-752 Golledge GSX-752B/551EF 8MHz
1 PCB1 RZUSBStick PCB ATMEL A08-0384
1 J2 USB type A plug, SMD SAMTEC USB-AM-S-F-B-SM1-R
1 D2 LED, Red, Everlight EL17-21USRC
1 D3 LED, Green, Everlight EL17-21SYGC
1 D4 LED, Yellow, Everlight EL17-21UYC/A2
1 D1 LED, Blue, Everlight EL17-21UBC
24
AVR2016
8117D-AVR-04/08
10 Appendix F: Federal Communications Commission (FCC) Statement
10.1 FCC Statements
10.1.1 Equipment usage
This equipment is for use by developers for evaluation purposes only and must not be
incorporated into any other device or system.
10.1.2 Compliance Statement (Part 15.19)
These devices comply with Part 15 of the FCC Rules. Operation is subject to the
following two conditions:
1. These devices may not cause harmful interference, and
2. These devices must accept any interference received,
including interference that may cause undesired operation.
10.1.3 Warning (Part 15.21)
Changes or modifications not expressly approved by Atmel Norway could void the
user’s authority to operate the equipment.
10.1.4 Compliance Statement (Part 15.105(b) )
This equipment has been tested and found to comply with the limits for a Class B
digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to
provide reasonable protection against harmful interference in a residential installation.
This equipment generates, uses and can radiate radio frequency energy and, if not
installed and used in accordance with the instructions, may cause harmful
interference to radio communications. However, there is no guarantee that
interference will not occur in a particular installation. If this equipment does cause
harmful interference to radio or television reception, which can be determined by
turning the equipment off and on, the user is encouraged to try to correct the
interference by one or more of the following measures:
- Reorient or relocate the receiving antenna.
- Increase the separation between the equipment and receiver.
- Connect the equipment into an outlet on a circuit different from that to which the
receiver is connected.
- Consult the dealer or an experienced radio/TV technician for help.
10.1.5 FCC IDs
The AVRRAVEN has FCCID: VW4AVRRAVEN
The RZUSBSTICK has FCCID: VW4AVRRZUSBSTICK
AVR2016
25
8117D-AVR-04/08
11 Table of Contents
Features............................................................................................... 1
1 Introduction ...................................................................................... 1
2 General ............................................................................................. 2
3 The AVRRAVEN Module.................................................................. 3
3.1 AVR Microcontrollers........................................................................................... 4
3.2 Atmel Radio Transceiver ..................................................................................... 4
3.3 Antenna description............................................................................................. 4
3.4 LCD ..................................................................................................................... 4
3.5 Speaker ............................................................................................................... 5
3.6 Microphone.......................................................................................................... 5
3.7 Serial Dataflash® ................................................................................................ 5
3.8 Serial EEPROM................................................................................................... 5
3.9 Real Time Clock .................................................................................................. 5
3.10 NTC ................................................................................................................... 5
3.11 Power Supply .................................................................................................... 6
3.12 Interfaces........................................................................................................... 7
3.12.1 Programming Interface............................................................................................ 8
3.12.2 Relay Interface ........................................................................................................ 8
3.13 Voltage Measurement Interface ........................................................................ 8
3.13.1 GPIO ....................................................................................................................... 8
4 The AVR RZUSBSTICK Module .................................................... 10
4.1 AVR Microcontroller .......................................................................................... 10
4.2 Atmel Radio Transceiver ................................................................................... 10
4.3 Antenna description........................................................................................... 10
4.4 Interfaces...........................................................................................................11
4.4.1 External Memory Interface ...................................................................................... 11
4.4.2 Serial Interface ........................................................................................................ 11
4.4.3 Programming Interface............................................................................................ 12
4.4.4 LEDs........................................................................................................................ 12
5 Appendix A: AVRRAVEN Schematics.......................................... 13
6 Appendix B: AVRRAVEN Bill of materials ................................... 18
7 Appendix C: AVRRAVEN LCD ...................................................... 20
8 Appendix D: RZUSBSTICK Schematics ....................................... 22
9 Appendix E: RZUSBSTICK Bill of materials ................................ 23
10 Appendix F: Federal Communications Commission (FCC)
Statement........................................................................................... 24
26
AVR2016
8117D-AVR-04/08
10.1 FCC Statements.............................................................................................. 24
10.1.1 Equipment usage .................................................................................................. 24
10.1.2 Compliance Statement (Part 15.19) ...................................................................... 24
10.1.3 Warning (Part 15.21) ............................................................................................. 24
10.1.4 Compliance Statement (Part 15.105(b) )............................................................... 24
10.1.5 FCC IDs................................................................................................................. 24
11 Table of Contents......................................................................... 25
Disclaimer.......................................................................................... 27
8117D-AVR-04/08
Disclaimer
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