JABIL CIRCUIT ZIM-B ZIGBEE RADIO MODULE User Manual ZIM B manualx
Jabil Circuit Inc ZIGBEE RADIO MODULE ZIM B manualx
Users Manual
ZIM 2.4GHz ZigBee Module - Smart Energy 2.0 Compliant DESCRIPTION The ZIM module provides a high performance and cost effective RF transceiver solution for 2.4 GHz IEEE 802.15.4, ZigBee, and Zigbee PRO wireless networks with Smart-Energy 2.0 requirements. The ZIM module combines the Freescale™ MC13224V transceiver platform with a QE128 microprocessor and includes an on-board 100mW Power Amplifier. Ideal for remote sensing, AMR/AMI, home and building automation, industrial control, and security applications, ZIM-B combines extensive processing capability with high output power and low power consumption. The processing power of the MC13224V enables the ZIM-B to provide a level of integration unprecedented in a ZigBee module. The 32-bit ARM7TDMI processor and expansive on-chip memory enable designers to eliminate the peripheral host processors often required by 8- and 16-bit transceiver solutions. This high level of integration reduces component count, lower power consumption and overall system costs. FEATURES • • • • • • • • • • • • • • • • Smart-Energy 2.0 “ready” Powerful 32-bit ARM7TDMI based microprocessor Extensive on-board memory resources Up to 100mW output power (+20dBm) Miniature footprint: 1.2” x 1.5” (30.5 mm x 38.1 mm) Integrated PCB trace antenna Optional external antenna 16 RF channels Over 4000 feet of range (Outdoor LOS) AES 128-bit encryption Low power consumption FCC and IC certifications pending RoHS compliant Security SW Development Kits for Home Automation, Smart Energy and other application profiles “Connector-less” host-board interface APPLICATIONS • Automated Meter Reading • Industrial Controls • Food processing controls • Traffic Management • Sensor Networks • Asset Management • Barcode reader • Patient Monitoring • Glucose monitor • In meter applications • Thermostats • In-home display units • Home & Building Automation ORDERING INFORMATION Part Number : ZIM-B/C-WWW-XX-YYYY-ZZ • • • • • Host Interface : B = Land Grid Array, C = Castellation WWW : 001 = MC13224V, 002 = MC13224V + QE128, 003 = MC13224V + QE96, 004 = MC13224V + QE64 With power amp installed, XX = ER. With no power amp, XX = 00. With MMCX connector installed, YYYY=EXTA. With inverted-F antenna, YYYY=INTA. ZZ = Optional Designators TBD (e.g. Home Automation part? SE1.0? SE2.x?) Example : 100 mW Output power, Land Grid Array, PCB Trace Antenna, with QE128 (Smart-Energy 2.0) = ZIM-B-002-ER-INTA ZIM ZIM BLOCK DIAGRAM 32.768 kHz Antenna QE128 UART MC13224V RF Front End WAKE/RESET Co-Processor SEP 2.0 (RFMD PA LPF, Switch) ZigBee SOC CLK TRIM 24 MHz LGA I/O Host Board Interface ZIM MICROPROCESSOR The primary component of the ZIM module is Freescale’s third generation ZigBee platform. It incorporates a complete, low power, 2.4GHz radio frequency transceiver, 32-bit ARM7TDMI-based microprocessor, hardware acceleration for both IEEE 802.15.4 MAC and AES security plus a full suite of processor peripherals. The MC13224V architecture offers superior processing power for ZigBee applications. The core operates up to 26 MHz. An 80 kByte ROM is utilized for the low level IEEE 802.15.4 MAC and Physical layer commands. This off loads the Flash memory, leaving more space for the end user application. The MC13224V supports 128 kBytes of Flash memory. The program code is mirrored in 96 kBytes of RAM for faster execution by the processor core. A full set of peripherals and Direct Memory Access (DMA) capability for transceiver packet data are also included. In addition, the MC13224V provides extensive power savings options. options, including low current sleep modes allowing for maximum operating life when battery-powered. ANTENNA ZIM modules include an integrated PCB trace antenna. An optional MMCX connector can be specified, enabling connection to a 50-ohm external antenna of the user’s choice. See Ordering Information on page 1. The PCB antenna employs an F-Antenna topology that is compact and supports an omni-directional radiation pattern. To maximize antenna efficiency, an adequate ground plane must be provided on the host PCB. Correctly positioned, the ground plane on the host board under the module will contribute significantly to antenna performance. The position of the module on the host board and overall design of the product enclosure contribute to antenna performance. Poor design affects radiation patterns and can result in reflection, diffraction, and/or scattering of the transmitted signal. Here are some design guidelines to help ensure antenna performance: • • • • • Never place the ground plane or route copper traces directly underneath the antenna portion of the module. Never place the antenna close to metallic objects. In the overall design, ensure that wiring and other components are not placed near the antenna. Do not place the antenna in a metallic or metallized plastic enclosure. Keep plastic enclosures 1cm or more from the antenna in any direction. ZIM MODES OF OPERATION ZIM power management is controlled through the Freescale MC13224V’s Clock and Reset Module (CRM). The CRM is a dedicated module to handle clock, reset, and power management functions including control of the power regulators. All these functions have direct impact on attaining the lowest power. The ZIM module supports three modes of operation: Active, Doze and Hibernation. The latter two modes are the low-power sleep modes. Active Mode In this mode all functions / features are operating normally. Doze Mode Doze mode provides significant reduction in power consumption while still maintaining a high degree of sleep timing accuracy. In Doze mode, the reference oscillator of the processor continues to operate normally. Hibernation Mode Hibernation mode provides the greatest reduction in power consumption however the sleep timing accuracy is not as precise as in Doze mode. The CRM manages the recovery from the low-power modes, similar to power-up from reset, providing regulator and clock management. The module can be awoken from the low-power modes in 3 ways, wake-up can occur: • • • On external interrupts through any of the 4 Keyboard Interface inputs From internal interrupts On the Real Time (wake-up) timer interrupt For more detail information on modes of operation refer to Freescale’s MC13224V datasheet available at Freescale’s website (www.freescale.com) ZIM HOST-BOARD A host-board for evaluation purposes is available for configuring and testing the ZIM module. This host board has a USB interface for connection to a PC whereby SMAC commands can be sent via HyperTerminal. INTERFACE The ZIM module has all major pins routed to the host-board interface, this includes, but is not limited, to the pins for JTAG, serial communication, A/D, etc. HOST PROTOCOL INTERFACE COMMANDS Jabil provides the Host Serial and RF Protocols document which details the protocols and commands between the Host processor (i.e. an external microprocessor, a PC, etc.) and the ZIM module. An example of the commands, but not limited to, included in the host protocol interface are as follows: • Query Version (MAC version, SMAC version, etc) • Set RF Channel • Set RF Power • Transmit Packet Error Test For more detail refer to Jabil ZIM Test SMAC Application User’s Guide ZIM_Test_SMAC_AUG ZIM To meet FCC compliance, the end-user must provide a regulated 3.3 VDC + 1% voltage source to Vcc. ZIM ZIM ZIM I/O PIN ASSIGNMENTS MC13224 Pin Pin Name Description Number Name ZIM_ADC0 ADC0 ADC analog input Channel 0/GPIO30 ZIM_ADC1 ADC1 ADC analog input Channel 0/GPIO31 ZIM_ADC2 ADC2 ADC analog input Channel 0/GPIO32 ZIM_ADC3 ADC3 ADC analog input Channel 0/GPIO33 ZIM_ADC4 ADC4 ADC analog input Channel 0/GPIO34 ZIM_ADC5 ADC5 ADC analog input Channel 0/GPIO35 ZIM_ADC6 ADC6 ADC analog input Channel 0/GPIO36 ZIM_ADC7 ADC7_RTCK ADC analog input Channel 0/ReTurn ClocK/GPIO37 ZIM_TDO TDO/GPIO49 JTAG debug port serial data output 10 ZIM_TDI 10 TDI/GPIO48 JTAG debug port serial data input 11 ZIM_TCK 11 TCK/GPIO47 JTAG debug port clock input 12 ZIM_TMS 12 TMS/GPIO46 JTAG debug port test mode select input 13 ZIM_UART2_RTS 13 UART2_RTS UART2 RTS control input/GPIO21 14 ZIM_UART2_CTS 14 UART2_CTS UART2 CTS control output/GPIO20 15 ZIM_UART2_RX 15 UART2_RX UART2 RX receive data input/GPIO19 16 ZIM_UART2_TX 16 UART2_TX UART2 TX transmit data output/GPIO18 17 ZIM_UART1_RTS 17 UART1_RTS UART1 RTS control input/GPIO17 18 ZIM_UART1_CTS 18 UART1_CTS UART1 CTS control output/GPIO16 19 ZIM_UART1_RX 19 UART1_RX UART1 RX receive data input/GPIO15 20 ZIM_UART1_TX 20 UART1_TX UART1 TX transmit data output/GPIO14 21 ZIM_I2C_SDA 21 I2C_SDA I2C bus signal SDA/GPIO13 22 ZIM_I2C_SCL 22 I2C_SCL I2C bus signal SCL/GPIO12 23 ZIM_TMR3 23 TMR3 Counter output or input clock/GPIO11 24 ZIM_TMR2 24 TMR2 Counter output or input clock/GPIO10 25 ZIM_TMR1 25 TMR1 Counter output or input clock/GPIO9 26 ZIM_TMR0 26 TMR0 Counter output or input clock/GPIO8 27 ZIM_SPI_SCK 27 SPI_SCK SPI port Clock/GPIO7 28 ZIM_SPI_MO 28 SPI_MOSI SPI port master out/GPIO6 29 ZIM_SPI_MI 29 SPI_MISO SPI port master in/GPIO5 ZIM 30 ZIM_SPI_SS 30 SPI_SS SPI port slave select/GPIO4 31 ZIM_SSI_BITCK 31 SSI_BITCK SSI TX/RX clock/GPIO3 32 ZIM_SSI_FSYN 32 SSI_FSYN SSI frame sync for data/GPIO2 33 ZIM_SSI_RX 33 SSI_RX SSI RX data input/GPIO1 34 ZIM_SSI_TX 34 SSI_TX SSI TX data output/GPIO0 35 ZIM_KBI7 35 KBI_7 Keyboard interface bit 7/GPIO29 36 ZIM_KBI6 36 KBI_6 Keyboard interface bit 6/GPIO28 37 ZIM_KBI5 37 KBI_5 Keyboard interface bit 5/GPIO27 38 ZIM_KBI4 38 KBI_4 Keyboard interface bit 4/GPIO26 39 ZIM_KBI3 39 KBI_3 Keyboard interface bit 3/GPIO25 40 ZIM_KBI2 40 KBI_2 Keyboard interface bit 2/GPIO24 41 ZIM_KBI1 41 KBI_1 Keyboard interface bit 1/GPIO23 42 ZIM_KBI0_HSTWK 42 KBI_0_HST_WK 43 ZIM_RESET 51 RESETB 44 ZIM_ADC2_REFL 61 ADC2_REFL Low ref voltage for ADC2/GPIO39 45 ZIM_ADC1_REFL 62 ADC1_REFL Low ref voltage for ADC1/GPIO41 46 ZIM_ADC1_REFH 63 ADC1_REFH High ref voltage for ADC1/GPIO40 47 ZIM_ADC2_REFH 64 ADC2_REFH High ref voltage for ADC2/GPIO38 48 ZIM_GND 48 VSS 49 ZIM_GPIO52 102 MDO01 50 ZIM_GND 50 VSS 51 ZIM_GPIO54 111 MDO03 52 ZIM_GND 52 VSS 53 ZIM_GPIO56 120 MDO05 GPIO56 54 ZIM_GPIO57 130 MDO06 GPIO57 55 ZIM_GPIO58 129 MDO07 GPIO58 56 ZIM_GPIO59 114 MSEO0_B GPIO59 57 ZIM_GND 57 VSS Connect to Ground 58 ZIM_GND 58 VSS Connect to Ground 59 ZIM_GPIO62 123 EVTO_B GPIO62 60 ZIM_GPIO63 132 EVTI_B GPIO63 61 ZIM_WAKE_QE 131 MCKO GPIO50 Keyboard interface bit 0/Host Wake Up output/GPIO22 Active low, asynchronous reset Connect to Ground GPIO52 Connect to Ground GPIO54 Connect to Ground ZIM 62 QE_BDM_BKGD NA NA NA 63 ZIM_VCC 44 BK_FB Power Input to module 64 ZIM_VCC 45 VBATT Power Input to module 65 ZIM_VCC NA NA Power Input to module 66 ZIM_VCC NA NA Power Input to module 67- 86 ZIM_GND 75-79, 84-88, 93-97, 104-106, 115 VSS Connect to ground 10 ZIM ZIM I/O PIN LOCATIONS 11 ZIM SPECIAL RESTRICTIONS / LIMITATIONS In order to meet certification requirements, RF power, packet length, and DC supply voltage shall adhere to the following restrictions. RF Power The ZIM module is limited to +20dBm (power register setting = 0x0C) for channels 13 – 23. In order to comply with emissions requirements, however, the ZIM module must operate at reduced power settings for channels 11-12 and 24-26. The firmware provided with the modules limits users to power level of +10dBm (power register setting = 0x09) for channels 11, 12, 24, & 25 and a power level of +6dBm (power register setting = 0x07) for channel 26. Packet Length The firmware also limits the maximum data payload to 106 bytes for any transmitted packet. DC Supply To ensure FCC compliance, the end-user must provide a regulated 3.3 VDC + 1% voltage source to Vcc. 12 ZIM AGENCY CERTIFICATIONS FCC Compliance Statement (Part 15.19) Section 7.15 of RSS-GEN This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: 1. This device may not cause harmful interference. 2. This device must accept any interference received, including interference that may cause undesired operation. Warning (Part 15.21) Changes or modifications not expressly approved by the responsible party could void the user’s authority to operate the equipment. This device may only be used with approved antennas that are shipped with the unit and installed per installation instructions. The use of any other antennas will invalidate the unit’s FCC Part 15 certification. This device has been designed to operate with the on-board inverted-F antenna. The use of an external antenna will require authorization. Contact the responsible party for details. To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (e.i.r.p.) is not more than that permitted for successful communication. Operating the device with the supplied antenna will ensure that this requirement is met. 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. 20 cm Separation Distance To comply with FCC/IC RF exposure limits for general population / uncontrolled exposure, the antenna(s) used for this transmitter must be installed to provide a separation distance of at least 20 cm from all persons and must not be co-located or operating in conjunction with any other antenna or transmitter. OEM Responsibility to the FCC Rules and Regulations The ZIM Module has been certified per FCC Part 15 rules for integration into products without further testing or certification. To fulfill the FCC certification requirements, the OEM using the ZIM Module must ensure that the information provided on the ZIM Label is placed on the outside of the final product. The ZIM Module is labeled with its own FCC ID Number and Industry Canada Certification Number. If these approval numbers are 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: “Contains Transmitter Module FCC ID: K4U-ZIM-B IC: 2146A-ZIM-B or “Contains FCC ID: K4U-ZIM-B IC: 2146A-ZIM-B. The OEM using the ZIM Module must only use the approved antenna, (PCB Trace Antenna) that has been certified with this module. The OEM using the ZIM Module must test their final product configuration to comply with Unintentional Radiator Limits before declaring FCC compliance per Part 15 of the FCC rules. IC Certification — Industry Canada Statement The term "IC" before the certification / registration number only signifies that the Industry Canada technical specifications were met. Section 14 of RSS-210 The installer of this radio equipment must ensure that the antenna is located or pointed such that it does not emit RF field in excess of Health Canada limits for the general population. Consult Safety Code 6, obtainable from Health Canada's website: http://www.hc-sc.gc.ca/ewh-semt/pubs/radiation/99ehd-dhm237/index-eng.php 13 ZIM REFERENCES & REVISION HISTORY Reference Documents Jabil ZIM Test SMAC Application User’s Guide ZIM_Test_SMAC_AUG FreeScale MC13224V Datasheet Freescale Semiconductor MC1322x Reference Manual MC1322xRM Freescale Semiconductor BeeKit™ Quick Start Guide BKWCTKQUG Freescale Semiconductor BeeKit™ User Guide BKWCTKUG Freescale Semiconductor Software Driver Reference Manual 22XDRVRRM Freescale Semiconductor MC1322x Simple Media Access Controller (SMAC) Reference Manual 22xSMACRM Freescale Semiconductor Simple Media Access Controller (SMAC) User’s Guide SMACRM IAR J-Link and IAR J-Trace user Guide J-Link_J-TraceARM-1 ARM® IAR Embedded Workbench® IDE User Guide UARM-13 Revision History Previous Versions Changes to Current Version Disclaimer • The information in this document is current as of April 2010. The information is subject to change without notice. • No part of this document may be copied or reproduced in any form or by any means without the prior written consent of Jabil. Jabil assumes no responsibility for any errors that may appear in this document. • Jabil does not assume any liability for infringement of patents, copyrights or other intellectual property rights of third parties by or arising from the use of Jabil-designed products listed in this document or any other liability arising from the use of such products. No license, express, implied or otherwise, is granted under any patents, copyrights or other intellectual property rights of Jabil or others. • Descriptions of circuits, software and other related information in this document are provided for illustrative purposes in semiconductor product operation and application examples. The incorporation of these circuits, software and information in the design of a customer’s equipment shall be done under the full responsibility of the customer. Jabil assumes no responsibility for any losses incurred by customers or third parties arising from the use of these circuits, software and information. • While Jabil endeavors to enhance the quality, reliability and safety of Jabil-designed products, customers agree and acknowledge that the possibility of defects thereof cannot be eliminated entirely. To minimize risks of damage to property or injury (including death) to persons arising from defects in Jabil-designed products, customers must incorporate sufficient safety measures in their design, such as redundancy, fire-containment and anti-failure features. 14
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