MPR-MIB Users Manual Revision B, June 2006 PN: 7430-0021-07
© 2002-2006 Crossbow Technology, Inc. All rights reserved. Information in this document is subject to change without notice. Crossbow, MoteWorks, MICA, TrueMesh and XMesh are registered trademarks of Crossbow Technology, Inc. Other product and trade names are trademarks or registered trademarks of their respective holders.
MPR/MIB User’s Manual Table of Contents 1 Introduction.............................................................................................................................1 2 MPR2400 (MICAz).................................................................................................................2 3 4 5 2.1 Product Summary .......................................................................................................... 2 2.
MPR/MIB User’s Manual 12.3 13 MICA2DOT Expansion Connector.......................................................................... 34 MIB300 / MIB500 Interface Boards.................................................................................36 13.1 Programming the Mote ............................................................................................ 36 13.2 RS-232 Interface ......................................................................................................
MPR/MIB User’s Manual About This Document The following annotations have been used to provide additional information. ; NOTE Note provides additional information about the topic. ; EXAMPLE Examples are given throughout the manual to help the reader understand the terminology. 3 IMPORTANT This symbol defines items that have significant meaning to the user 0 WARNING The user should pay particular attention to this symbol.
MPR/MIB User’s Manual 1 Introduction This User’s Manual describes the hardware features of the Mote Processor Radio (MPR) platforms and Mote Interface Boards (MIB) for network base stations and programming interfaces. It is intended for understanding and leveraging Crossbow’s Smart Dust hardware design in real-world sensor network, smart RFID, and ubiquitous computing applications. Table 1-1 below lists the models in this Manual. Table 1-1. This User’s Manual covers these MPR and MIB models.
MPR/MIB User’s Manual 2 MPR2400 (MICAz) 2.1 Product Summary The MICAz is the latest generation of Motes from Crossbow Technology. The MPR2400 (2400 MHz to 2483.5 MHz band) uses the Chipcon CC2420, IEEE 802.15.4 compliant, ZigBee ready radio frequency transceiver integrated with an Atmega128L micro-controller. The same MICA2, 51 pin I/O connector, and serial flash memory is used; all MICA2 application software and sensor boards are compatible with the MPR2400. Figure 2-1.
MPR/MIB User’s Manual Figure 2-1. Block diagram of the MICA2 and listing of Chapters that discuss the components in greater detail. 2.2.1 51-pin Expansion Connector Doc. # 7430-0021-07 Rev.
MPR/MIB User’s Manual 2.2.2 Page 4 CC2420 Radio Doc. # 7430-0021-07 Rev.
MPR/MIB User’s Manual 2.2.3 Battery, ADC1 Doc. # 7430-0021-07 Rev.
MPR/MIB User’s Manual 3 MPR400/MPR410/MPR420 (MICA2) 3.1 Product Summary The MICA2 Motes come in three models according to their RF frequency band: the MPR400 (915 MHz), MPR410 (433 MHz), and MPR420 (315 MHz). The Motes use the Chipcon CC1000, FSK modulated radio. All models utilize a powerful Atmega128L micro-controller and a frequency tunable radio with extended range. The MPR4x0 and MPR5x0 radios are compatible and can communicate with each other.
MPR/MIB User’s Manual 3.2.1 Battery, Power, and ADC1 R6 ADC7 TP3 10K BT1 V+ V- 1 BAT_MON 3 18.2K 2 2 1 U2 R7 BATTERY_2AA LM4041-1.2 VCC R2 R1 D1 0 OHM BAT54C 0 OHM 1 SW2 VSNS R3 2 3 0 OHM R4 SPDT 0 OHM R5 1K J4 C2 .1uF C1 .1uF 1 1 2 2 CONN VSNSR R8 BOARD OPTIONS ADC[0..7] ADC1 R1 R2 R4 R8 RT1 INSTALL NOT INSTALLED NOT INSTALLED NOT INSTALLED NOT INSTALLED 10K RT1 10.0K THERM_PWR 3.2.2 CC1000 RADIO CONTROL AVCC PCLK PDATA PALE VCC RADIO DATA C5 0.
MPR/MIB User’s Manual 3.2.3 51-pin Expansion Connector: Location J21 PW[0..7] PIN UART_RXD0 UART_TXD0 VSNSR J21 BAT_MON LED3 LED2 LED1 RD WR ALE PW7 USART1_CLK PROG_MOSI PROG_MISO SPI_SCK USART1_RXD USART1_TXD I2C_CLK I2C_DATA PWM0 PWM1A AC+ AC- 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 PLUG INT3 INT2 INT1 INT0 HIROSE T[0..
MPR/MIB User’s Manual 3.2.5 ATMega128L VSNSR VCC R15 C21 470 C22 .1uF R16 10K C23 .1uF RSTN 64 62 20 .
MPR/MIB User’s Manual 3.2.6 Flash Memory, Serial ID, LEDs, USART VCC + C24 10uF 10V C25 .01uF C26 .01uF C27 .01uF C28 .01uF C29 .01uF C30 .01uF VCC VCC R19 USART1_RXD C31 1000pF C32 1000pF C33 1000pF C34 1000pF R22 1M UART_TXD0 1M R23 FLASH_CS VCC USART1_TXD USART1_CLK FLASH_CS U5 1 2 3 4 4.
MPR/MIB User’s Manual 4 MPR500/MPR510/MPR520 (MICA2DOT) 4.1 Product Summary The MICA2DOT is a Mote designed for applications where physical size is important. Like the MICA2, these are available in three models according to the frequency of the RF transceiver: the MPR500 (915 MHz), MPR510 (433 MHz), and MPR520 (315 MHz). The Motes use the Chipcon CC1000 FSK-modulated radio. All models utilize a powerful ATMega128L microcontroller and a frequency tunable radio with extended range.
MPR/MIB User’s Manual a = 0.00130705 b = 0.000214381 c = 0.000000093 R1 = 10 kΩ ADC_FS = 1023 ADC = output value from the Mote’s ADC measurement. 4.3 Block Diagram and Schematics for the MPR500/510/520 MICA2DOT Antenna 19 peripheral pins Logger Flash ATMega128L µcontroller Analog I/O Digital I/O Freq. Tunable Radio Feature Battery / Ext. Power Radio Antenna Data Flash Logger Atmega128 Expansion Connector Chapter 6 7 8 9 10 11 25 mm Figure 4-2.
MPR/MIB User’s Manual 4.3.1 MICA2DOT CC1000 Radio Side L3 C10 AVCC SPI_SCK VCCA AVCC 23 24 25 26 27 DCLK PCLK PDATA PALE 10 11 13 L8 DIO DCLK PCLK PDATA PALE 21 C12 VCC SPI_MISO AVCC AVCC AVCC AVCC U3 CC1000 1 5 9 15 R13 10K RF_IN RF_OUT CHP_OUT RSSI L1 L2 R_BIAS XOSC1 XOSC2 L4 3 C13 4 12 28 POT_PWR 18 17 TP17 TP18 L9 ADC0 R18 82.5K C16 .001uF C17 4.7pF R17 27.4K R35 10K C18 C19 Y1 1 X1 2 X2 14.
MPR/MIB User’s Manual 4.3.2 MIC2DOT ATMega128L, ADC Interfaces, Battery VCCA C22 R21 .1uF 470 R22 C23 10K VCCA .
MPR/MIB User’s Manual 4.3.3 Data Flash Logger/Serial ID, On-board Thermistor, LED VCCA R36 ADC1 VCCA 10K D5 RT1 10.0K + SD103AW C24 10uF 10V C25 .01uF C26 .01uF PW7 PW6 VCCA VCCA R26 FLASH_SO 1M R29 C31 1000pF UART_TXD0 R30 C32 1000pF 1M SERIAL_ID 4.7K VCCA D2 LED1 2 R31 1 470 RED SERIAL_ID U7 1 2 3 4 SI SCK RST CS GNDVCC VCCA FLASH_SI FLASH_CLK 6 VCCA SO WP 8 FLASH_SO 5 R25 100K 7 AT45DB041 RSTN Doc. # 7430-0021-07 Rev.
MPR/MIB User’s Manual 5 MPR300/MPR310 (MICA) ; NOTE: The MICA Mote has been discontinued by Crossbow since December 2003. The MICA Mote was the second generation Mote module used in many ground breaking research and development efforts. The MPR300/310 includes a powerful Atmel ATMega128L. It used an amplitude shift keying radio—the TR1000—by RF Monolithics, Inc. 5.1 Schematic Schematics for the MPR300/310 Mote can be found at: http://www.tinyos.net/scoop/special/hardware Page 16 Doc.
MPR/MIB User’s Manual 6 MPR1000 (MICA3) The MPR1000 is a 1 watt high power mote with Frequency Hopping feature that enables it to transmit over a very high range. 6.1 Block Diagram Power Supply: Input power regulator which accepts 3.6 to 4.5VDC. MCU: it includes ATMega128 processor and its’ peripherals. Flash Memory: 4Kbit flash memory for storing firmware. Radio: it is purposed for transmitting and receiving at 902MHz to 928MHz band using Frequency Hopping modulation.
MPR/MIB User’s Manual 6.3 Regulatory Compliance This device has been designed, constructed, and tested for compliance with FCC Rules that regulate intentional and unintentional radiators. The user is not permitted to make any modifications to this equipment without express approval from Crossbow Technology Inc. Doing so will void the user’s authority to operate this equipment. This device complies with Part 15 of the FCC Rules.
MPR/MIB User’s Manual 7 Power 7.1 Battery Power All motes are designed for battery power. The MICA2 and MICAz form factors are designed to match up with two AA batteries; however any battery combination (AAA, C, D, etc., cells) can be used provided that the output is between 2.7 VDC to 3.6 VDC.
MPR/MIB User’s Manual Table 7-3. Estimate of battery life operation for a Mote. SYSTEM SPECIFICATIONS Currents Example Duty Cycle Processor Current (full operation) 8 mA 1 Current sleep 8 µA 99 Current in receive 8 mA 0.75 Current transmit 12 mA 0.25 Current sleep 2 µA 99 Write 15 mA 0 Read 4 mA 0 Sleep 2 µA 100 Sensor Board Current (full operation) 5 mA 1 Current sleep 5 µA 99 Radio Logger Memory Computed mA-hr used each hour Processor 0.0879 Radio 0.
MPR/MIB User’s Manual 2. The 2-pin Molex connector. Molex part number 53261-0290, Digi-Key part number WM1753-ND. (See Figure 7-4 below.) Figure 7-4. Photo of using the Molex connector to attach the AA battery pack. Photo courtesy of Nick Sitar, UC Berkeley, 2004. 7.3 MICAz Battery Voltage Monitor The MICAz has an accurate internal voltage reference that can be used to measure battery voltage (Vbatt).
MPR/MIB User’s Manual calibrate the battery voltage a precision external voltage reference is required. The MICA2 uses an LM4041 (Mfg: National Semiconductor) 1.223 V reference (Vref) attached to ADC channel 7. ; NOTE: ADC channel 7 is also used for JTAG debugging on the Atmega128 processor. MICA2s and MICA2DOTs ship with the JTAG fuse enabled. When this fuse is enabled the input impedance of channel 7 is lowered which affects the voltage reference measurement.
MPR/MIB User’s Manual 8 Radios 8.1 8.1.1 MICA2 and MICA2DOT Radio Considerations The radio on the MICA2 and MICA2DOT is capable of multiple channel operation, within the intended band of operation. The MPR420/MPR520 can span up to 4 channels of operation in the 315 MHz band, the MPR410/MPR510 can span up to 4 channels of operation in the 433 MHz band (433.05–434.79 MHz). The MPR400/MPR500 can operate in two frequency regions: 868– 870 MHz (up to 4 channels) and 902–928 MHz (up to 54 channels).
MPR/MIB User’s Manual Table 8-1. Chipcon® CC1000 Ouput Power (PA_POW) Settings and Typical Current Consumption. From Smart RF® CC1000 Preliminary Datasheet (rev. 2.1), 2002-04-19, p. 29 of 48. Pout (dBm) PA_POW (hex) 433/315 MHz Current Consumption, typ.
MPR/MIB User’s Manual VRSSI = Vbatt × ADC _ Counts 1024 RSSI (dBm ) = −51.3 × VRSSI − 49.2 for 433 and 315 MHz Motes RSSI ( dBm) = −50.0 × VRSSI − 45.5 for 915 MHz Motes Figure 8-2. Graph showing VRSSI versus the received signal strength indicator (dBm). From the ChipCon’s SmartRF® CC1000 PRELIMINARY Datasheet (rev. 2.1), p. 30. 2002. Care should be taken to provide an antenna that provides proper coverage for the environment expected.
MPR/MIB User’s Manual Power Register (code) MICAz TX RF Power (dBm) 31 27 23 19 15 11 7 3 0 -1 -3 -5 -7 -10 -15 -25 3 IMPORTANT For MPR2400J, the power is constant at 0dBm and any questions be directed to Crossbow, Japan. http://www.xbow.com/jp/index.html The RF received signal strength indication (RSSI) is read directly from the CC2420 Radio. In TinyOS the RSSI is automatically returned in the TOSMsg->strength field with every radio packet received.
MPR/MIB User’s Manual 3. INT2 GPIO Line MICA I/O signal INT2 (Port E, pin 6 on ATMega128 or 51-pin Hirose connector pin 4) is used internally to the MICAz for the CC2420 Radio Receiver FIFO Ready interrupt. Use of INT2 for any other purpose must be done with care. Specifically, the Port configuration (input, active low) must be restored following use in other software modules. ; NOTE: Programmers should be cautioned that the MICAz receiver radio stack (CC2420RadioM.
MPR/MIB User’s Manual 9 Antennas 9.1 Radio/Antenna Considerations Care should be taken to provide an antenna that provides proper coverage for the environment expected. Range and performance are strongly affected by choice of antenna and antenna placement within the environment. In addition, care must be taken to ensure compliance with FCC article 15 regulations for intentional radiators.
MPR/MIB User’s Manual 9.2 Connectors for the MICA2 and MICAz and Whip Antennas The MICA2 and MICAz have an MMCX connector for attaching an external antenna. These mating connectors can be purchased from Digi-Key. There are two manufacturers—Johnson Components and Hirose Electric Ltd. The mating connectors come in straight and right angle. They also support two different standard varieties of Coaxial cable—RG178 /U and RG 316/U. There are also other vendors who sell MMCX to SMA conversion cables.
MPR/MIB User’s Manual 10 Flash Data Logger and Serial ID Chip All Motes feature a 4-Mbit serial flash (Atmel AT45DB041) for storing data, measurements, and other user-defined information. It is connected to one of the USART on the ATMega128L. This chip is supported in TinyOS which uses this chip as micro file system. The serial flash device supports over 100,000 measurement readings. This chip is also used for over-the-air reprogramming services available in TinyOS.
MPR/MIB User’s Manual 11 Atmega128 Fuses The ATMega128L processor on the Motes has many programmable fuses to control various parameters. Refer to Atmel’s technical information for the ATMega128L for a complete discussion of the fuses (http://www.atmel.com/dyn/resources/prod_documents/2467s.pdf). There are two fuses that TinyOS users should be aware of as setting these fuses incorrectly will cause the unit to not operate correctly. 11.1.
MPR/MIB User’s Manual 12 Sensor Boards & Expansion Connectors Crossbow supplies a variety of sensor and data acquisition boards for the Motes. This Chapter describes the connectors and the functions of the pins for the MICAz, MICA2, MICA, and MICA2DOT. Information for customized sensor board design is available on the Crossbow web site. 12.1 Sensor Board Compatibility Table 12-1. Sensor board compatibility.
MPR/MIB User’s Manual 12.2.1 MICAz and MICA2 Sensor Interface. Table 12-2. MICAz Sensor Interface.
MPR/MIB User’s Manual 8g 9 g 10 g 11 LED3 Green LED 34 PW5 GPIO/PWM LED2 Yellow LED 35 LED1 RD Red LED GPIO 36 PW6 GPIO/PWM g ADC7 GPIO/ADC CH7, JTAG g ADC6 GPIO/ADC CH6, JTAG g 37 12 WR GPIO 38 ADC5 GPIO/ACD CH5, JTAG 13 ALE GPIO 39g ADC4 GPIO/ADC CH4, JTAG 14 PW7 GPIO 40 ADC3 GPIO/ADC CH3 15 USART_CLK USART Clock 41 ADC2 GPIO/ADC CH2 16 gg PROG_MOSI Programmer Pin 42 ADC1 GPIO/ADC CH1 17 gg PROG_MISO Programmer Pin 43 ADC0 GPIO/ADC CH0 18 gg
MPR/MIB User’s Manual Loc. 19 Loc. 1 y Loc. 2 x Loc. x y Pin Name Description 1 -0.290 0.315 TP1 GND Ground 2 -0.370 0.230 TP2 ADC7 ADC Channel 7 3 -0.420 0.120 TP3 ADC6 ADC Channel 6 4 -0.430 0.000 TP4 ADC5 ADC Channel 5 5 -0.420 -0.120 TP5 ADC4 ADC Channel 4 6 -0.335 -0.275 TP13 ADC3 ADC Channel 3 7 -0.225 -0.375 TP14 ADC2 ADC Channel 2 8 -0.120 -0.420 TP10 UART_RX UART Receive 9 0.000 -0.430 TP9 UART_TX UART Transmit 10 0.120 -0.
MPR/MIB User’s Manual 13 MIB300 / MIB500 Interface Boards ; NOTE: The MIB300 and MIB500 have been discontinued by Crossbow. The MIB500 has been replaced by the MIB510. 0 WARNING: When programming a MICA2 with the MIB500, turn off the battery switch. For a MICA2DOT, remove the battery before inserting into the MIB500. The MICA2s and MICA2DOTs do not have switching diodes to switch between external and battery power. 13.
MPR/MIB User’s Manual 14 MIB510 Serial Interface Boards ; NOTE: The MIB510 will only work with ATMega128 processors used on the MICA2 and MICA2DOT. It will work for older Mica units that have the ATMega128 processor but not earlier processors such as the ATMega103. 14.1 Product Summary The MIB510 interface board is a multi-purpose interface board used with the MICAz, MICA2, MICA, and MICA2DOT family of products. The board is supplied with all MOTE-KITs.
MPR/MIB User’s Manual http://www.tinyos.net/download.html. The commands for downloading build (compiled) code depend on the Mote platform you are programming. Instructions can also be found in the Getting Started Guide. 0 WARNING: Under Cygwin the ISP may not get control of the serial port if the Mote is continually sending packets over the serial TX line at a high rate. If this happens, the UISP will hang. This can be fixed by: 1. Type Ctrl C in the Cygwin window and try again. 2.
MPR/MIB User’s Manual 14.4.5 Schematics PW[0..7] UART_RXD0 UART_TXD0 VSNSR J2 BAT_MON LED3 LED2 LED1 RD WR ALE PW7 USART1_CLK PROG_MOSI PROG_MISO SPI_SCK USART1_RXD USART1_TXD I2C_CLK I2C_DATA PWM0 PWM1A AC+ AC- 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 PLUG INT3 INT2 INT1 INT0 HIROSE INT[0..3] 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 UART_RXD0 UART_TXD0 PW0 PW1 PW2 PW3 PW4 PW5 PW6 ADC7 ADC6 ADC5 ADC4 ADC3 ADC2 ADC1 ADC0 ADC[0..
MPR/MIB User’s Manual PIN 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 Page 40 NAME GND VSNSR INT3 INT2 INT1 INT0 BAT_MON LED3 LED2 LED1 RD WR ALE PW7 USART1_CLK PROG_MOSI PROG_MISO SPI_SCK USART1_RXD USART1_TXD I2C_CLK I2C_DATA PWM0 PWM1A AC+ AC- PIN NAME 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 UART_RXD0 UART_TXD0 PW0 PW1 PW2 PW3 PW4 PW5 PW6 ADC7 ADC6 ADC5 ADC4 ADC3 ADC2 ADC1 ADC0 THERM_PWR THRU1 THRU2 THRU3 RSTN PWM1B VCC GND DESCRIPTION G
MPR/MIB User’s Manual 14.4.6 RS-232, MICA2DOT, and Ext. Power Interface. J4 TP5 13 25 12 24 11 23 10 22 9 21 8 20 7 19 6 18 5 17 4 16 3 15 2 14 1 TP6 J6 5 9 4 8 3 7 2 6 1 RS232_RX RS232_TX DB9-F-RA VCC J5 LPT1_MISO 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 LPT1_RST LPT1_MOSI LPT1_SCK ADC[0..
MPR/MIB User’s Manual 15 MIB520 USB Interface Board The MIB520 provides USB connectivity to the MICA family of Motes for communication and in-system programming. It supplies power to the devices through USB bus. MIB520CB has a male connector while MIB520CA has female connector. MICAx-series connector USB Serial Port (A-type female) Power OK LED (green) Reset Switch (SW1) ISP LED (red) Mote JTAG connector (unmounted) Figure 15-1a. Photo of top view of an MIB520CA.
MPR/MIB User’s Manual 15.3 MIB520 Use 15.3.1 Install FTDI USB Virtual COM Port Drivers MIB520 uses FTDI FT2232C to use USB port as virtual COM port. Hence you need to install FT2232C VCP drivers. • When you plug a MIB520 into your PC for the first time, the Windows detects and reports it as a new hardware. Please select “Install from a list or specific location (Advanced)” and browse to “MIB520 Drivers” folder of the TinyOS Support Tools CDROM.
MPR/MIB User’s Manual VIN TP7 VIN TP7 J51 J51 USB-A A-USB-A-LP/SMT 1 2 3 4 DM DP 5 6 5 6 1 2 3 4 TP6 DM TP6 TP5 DP TP5 MIB520CA MIB520CB Table 15-3. Pin Outs for a USB Connection Pin No. Name Description 1 VBUS Powered Supply Pin 2 USBDM USB Data Signal Minus 3 USBDP USB Data Signal Plus 4 GND Ground Supply Pin 15.8 51-Pin Mote Connector Interface PW[0..7] UART_TXD0 UART_RXD0 VSNSR INT[0..
MPR/MIB User’s Manual PIN 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 NAME GND VSNSR INT3 INT2 INT1 INT0 BAT_MON LED3 LED2 LED1 RD WR ALE PW7 USART1_CLK PROG_MOSI PROG_MISO SPI_SCK USART1_RXD USART1_TXD I2C_CLK I2C_DATA PWM0 PWM1A AC+ AC- DESCRIPTION PIN NAME GROUND SENSOR SUPPLY GPIO GPIO GPIO GPIO BATTERY VOLTAGE MONITOR ENABLE LED3 LED2 LED1 GPIO GPIO GPIO POWER CONTROL 7 USART1 CLOCK SERIAL PROGRAM MOSI SERIAL PROGRAM MISO SPI SERIAL CLOCK USART1 RX DATA USART1 TX DATA I2C
MPR/MIB User’s Manual 16 16.1 MIB600 Ethernet Interface Board Introduction The MIB600 provides Ethernet (10/100 Base-T) connectivity to MICA2 family Motes for communication and in-system programming. Its two standard configurations are (a) an Ethernet Gateway for a Mote network and (b) a Mote network programming and out-band diagnostic channel. The MIB600CA device contains, on a 4.5” × 2.
MPR/MIB User’s Manual 16.2.1 Physical For other than temporary installations, the MIB600 should be installed in a ground isolated enclosure. 16.2.2 MICA Mote Connection MICAz and MICA2 Motes connect to the MIB600 directly via the standard mote 51-pin HIROSE connector at J1. Two mounting holes are provided for securing the MICA2 Mote when installed at J1.
MPR/MIB User’s Manual Table 16-2. Pin Outs for a LAN Connection 16.3 16.3.1 Pin No. Strand Color Name 1 White and orange TX+ 2 Orange TX- 3 White and green RX+ 4 Blue 0V POE 5 White and blue 0V POE 6 Green RX- 7 Brown and white -48V POE 8 Brown -48V POE Host Software UISP UISP version 20030820tinyos or newer is required. This version is included in the TinyOS 1.1.0 September 2003 release package.
MPR/MIB User’s Manual Serial Server RESET. Pressing the S1 switch on the server sub-module (U15) manually resets the Ethernet serial server. ;NOTE The MIB600 and attached Mote are not reset. The serial server can also be reset via Telnet at Port 9999. ISP LED. During in-system programming of a Mote the ISP LED (D3) is ON. Mote LEDs. Three LEDs (red, green, yellow) correspond to the attached Mote’s indicators. 16.4.
MPR/MIB User’s Manual Table 16-5. Controls, Indicators, and Connector Summary. ID NAME DESCRIPTION CONTROLS SW1 SW2 RESET MIB600 Manual RESET pushbutton. Resets MIB600 ISP controller and attached MOTE. POWER SELECT 5V POE Serial Server Reset Selects External 5VDC power source at J7 Selects Power Over Ethernet provided at RJ45/J10 Reset Serial Server.
MPR/MIB User’s Manual 17 Appendix A: 10/100 Base-T Cabling tandards Category 5(e) (UTP) color coding table Doc. # 7430-0021-07 Rev.
MPR/MIB User’s Manual 18 Appendix B. Warranty and Support Information 18.1 Customer Service As a Crossbow Technology customer you have access to product support services, which include: • Single-point return service • Web-based support service • Same day troubleshooting assistance • Worldwide Crossbow representation • Onsite and factory training available • Preventative maintenance and repair programs • Installation assistance available 18.
MPR/MIB User’s Manual 18.3.2 Identification and Protection If the equipment is to be shipped to Crossbow for service or repair, please attach a tag TO THE EQUIPMENT, as well as the shipping container(s), identifying the owner. Also indicate the service or repair required, the problems encountered and other information considered valuable to the service facility such as the list of information provided to request the RMA number.
Crossbow Technology, Inc. 4145 N. First Street San Jose, CA 95134 Phone: 408.965.3300 Fax: 408.324.