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SBC BL2600 C-Programmable Single-Board Computer with Ethernet User’s Manual 019–0142_M SBC BL2600 User’s Manual ©2014 Digi International® Inc. All rights reserved. Rabbit, Dynamic C, RabbitCore, RabbitNet, Digi, Digi International, Digi International Company, and the Digi and Rabbit logos are trademarks or registered trademarks of Digi International, Inc. in the United States and other countries worldwide. All other trademarks are the property of their respective owners. Information in this document is subject to change without notice and does not represent a commitment on the part of Digi International. Digi provides this document "as is," without warranty of any kind, expressed or implied, including, but not limited to, the implied warranties of fitness or merchantability for a particular purpose. Digi may make improvements and/or changes in this manual or in the product(s) and/or the program(s) described in this manual at any time. This product could include technical inaccuracies or typographical errors. Changes are periodically made to the information herein; these changes may be incorporated in new editions of the publication. The latest revision of this manual is available at www.digi.com. SBC BL2600 TABLE OF CONTENTS Chapter 1. Introduction 1 1.1 BL2600 Description..............................................................................................................................1 1.2 BL2600 Features...................................................................................................................................1 1.2.1 Connector Options ........................................................................................................................3 1.2.2 Memory and Clock Speed Options ...............................................................................................3 1.3 Development and Evaluation Tools......................................................................................................4 1.3.1 Tool Kit .........................................................................................................................................4 1.3.2 Software ........................................................................................................................................5 1.3.3 Additional Tools ...........................................................................................................................5 1.4 CE Compliance .....................................................................................................................................6 1.4.1 Design Guidelines .........................................................................................................................7 1.4.2 Interfacing the BL2600 to Other Devices .....................................................................................7 Chapter 2. Getting Started 9 2.1 Preparing the BL2600 for Development...............................................................................................9 2.2 BL2600 Connections ..........................................................................................................................10 2.2.1 Hardware Reset ...........................................................................................................................11 2.3 Installing Dynamic C ..........................................................................................................................12 2.4 Starting Dynamic C ............................................................................................................................13 2.5 PONG.C ..............................................................................................................................................14 2.6 Where Do I Go From Here? ...............................................................................................................14 Chapter 3. Subsystems 15 3.1 BL2600 Pinouts ..................................................................................................................................16 3.1.1 Connector Options ......................................................................................................................18 3.2 Digital I/O ...........................................................................................................................................19 3.2.1 Digital Inputs...............................................................................................................................19 3.2.2 PWM Outputs .............................................................................................................................20 3.2.3 High-Current Digital Outputs .....................................................................................................21 3.2.4 Configurable I/O .........................................................................................................................23 3.3 Serial Communication ........................................................................................................................25 3.3.1 RS-232 ........................................................................................................................................25 3.3.2 RS-485 ........................................................................................................................................25 3.3.3 Programming Port .......................................................................................................................27 3.3.4 Ethernet Port ...............................................................................................................................28 3.4 A/D Converter Inputs..........................................................................................................................29 3.4.1 A/D Converter Calibration..........................................................................................................30 3.5 D/A Converter Outputs .......................................................................................................................31 3.5.1 D/A Converter Calibration..........................................................................................................32 3.6 Analog Reference Voltage Circuit......................................................................................................33 3.7 Serial Programming Cable..................................................................................................................34 3.7.1 Changing Between Program Mode and Run Mode ....................................................................34 3.8 Other Hardware...................................................................................................................................35 3.8.1 Clock Doubler .............................................................................................................................35 3.8.2 Spectrum Spreader ......................................................................................................................35 User’s Manual 3.9 Memory .............................................................................................................................................. 36 3.9.1 SRAM......................................................................................................................................... 36 3.9.2 Flash Memory............................................................................................................................. 36 3.9.3 Serial Flash ................................................................................................................................. 36 3.9.4 NAND Flash............................................................................................................................... 37 Chapter 4. Software 39 4.1 Running Dynamic C........................................................................................................................... 39 4.1.1 Upgrading Dynamic C................................................................................................................ 41 4.2 Sample Programs................................................................................................................................ 42 4.2.1 General BL2600 Sample Programs ............................................................................................ 42 4.2.2 Digital I/O................................................................................................................................... 42 4.2.3 Serial Communication ................................................................................................................ 43 4.2.4 A/D Converter Inputs ................................................................................................................. 44 4.2.5 D/A Converter Outputs............................................................................................................... 45 4.2.6 Use of BL2600 with SF1000 Serial Flash Card ......................................................................... 46 4.2.7 Use of NAND Flash ................................................................................................................... 46 4.2.8 Real-Time Clock ........................................................................................................................ 47 4.2.9 TCP/IP Sample Programs........................................................................................................... 47 4.3 BL2600 Libraries ............................................................................................................................... 47 4.4 BL2600 Function Calls ...................................................................................................................... 48 4.4.1 Board Initialization..................................................................................................................... 48 4.4.2 Digital I/O................................................................................................................................... 49 4.4.3 Serial Communication ................................................................................................................ 57 4.4.4 A/D Converter Inputs ................................................................................................................. 59 4.4.5 D/A Converter Outputs............................................................................................................... 66 4.4.6 SRAM Use.................................................................................................................................. 70 4.4.7 NAND Flash Drivers.................................................................................................................. 70 Chapter 5. Using the TCP/IP Features 71 5.1 TCP/IP Connections........................................................................................................................... 71 5.2 TCP/IP Sample Programs................................................................................................................... 73 5.2.1 How to Set IP Addresses in the Sample Programs..................................................................... 73 5.2.2 How to Set Up your Computer’s IP Address for a Direct Connection ...................................... 74 5.2.3 Run the PINGME.C Demo...................................................................................................... 75 5.2.4 Running More Demo Programs With a Direct Connection ....................................................... 76 5.3 Where Do I Go From Here?............................................................................................................... 76 Appendix A. Specifications 77 A.1 Electrical and Mechanical Specifications.......................................................................................... 78 A.1.1 Exclusion Zone .......................................................................................................................... 80 A.1.2 Headers ...................................................................................................................................... 81 A.2 Conformal Coating ............................................................................................................................ 82 A.3 Jumper Configurations ...................................................................................................................... 83 A.4 Use of Rabbit 3000 Parallel Ports ..................................................................................................... 85 Appendix B. Power Supply 87 B.1 Power Supplies .................................................................................................................................. 87 B.1.1 Power for Analog Circuits ......................................................................................................... 88 B.2 Batteries and External Battery Connections...................................................................................... 88 B.2.1 Replacing the Backup Battery ................................................................................................... 88 B.3 Power to Peripheral Boards ............................................................................................................... 89 Appendix C. Demonstration Board 91 SBC BL2600 C.1 Connecting Demonstration Board......................................................................................................91 Appendix D. RabbitNet 95 D.1 General RabbitNet Description..........................................................................................................95 D.1.1 RabbitNet Connections ..............................................................................................................95 D.1.2 RabbitNet Peripheral Cards........................................................................................................96 D.2 Physical Implementation....................................................................................................................97 D.2.1 Control and Routing...................................................................................................................97 D.3 Function Calls ....................................................................................................................................98 D.3.1 Status Byte ...............................................................................................................................104 Schematics 105 Index 107 User’s Manual SBC BL2600 1. INTRODUCTION The BL2600 is a high-performance, C-programmable singleboard computer that offers built-in digital and analog I/O combined with Ethernet connectivity in a compact form factor. The BL2600 is ideal for both discrete manufacturing and processcontrol applications. A Rabbit® 3000 microprocessor operating at up to 44.2 MHz provides fast data processing with 10/100Base-T Ethernet connectivity. Serial flash options support a full directory file structures to maximize remote access control and programmability. The I/O can be expanded with RabbitNet peripheral cards. 1.1 BL2600 Description Throughout this manual, the term BL2600 refers to the complete series of BL2600 singleboard computers unless other production models are referred to specifically. The BL2600 is an advanced single-board computer that incorporates the powerful Rabbit 3000 microprocessor, flash memory, serial flash options, static RAM, digital I/O ports, A/D converter inputs, D/A converter outputs, RS-232/RS-485 serial ports, and a 10/100Base-T Ethernet port. 1.2 BL2600 Features • Rabbit® 3000 microprocessor operating at 29.4 MHz or 44.2 MHz. • Dual-entry IDC through-hole I/O header sockets allow header mounting on either side of the BL2600 board • Industry-standard friction-lock connectors for power-supply wiring harness. • 512K static RAM and 512K flash memory standard. • 36 digital I/O: 16 protected digital inputs, 4 high-current digital outputs softwareconfigurable as sinking or sourcing, and 16 I/O individually software-configurable as inputs or sinking outputs. • 12 analog channels: eight 11-bit A/D converter inputs, four 12-bit D/A converter 0–10 V or ±10 V buffered outputs. User’s Manual 1 • One RJ-45 Ethernet port compliant with IEEE 802.3 standard for 10/100Base-T Ethernet protocol. • Up to 5 serial ports: Three serial ports (2 RS-232 or 1 RS-232 with RTS/CTS, 1 RS-485 or RS-232). Two RabbitNet™ expansion ports multiplexed from one serial port. One serial port dedicated to programming/debugging. • Provision to install optional SF1000 serial flash, other memory options have provision for removable memory cards. • Battery-backed real-time clock. • Watchdog supervisor. Two BL2600 models are available. Their standard features are summarized in Table 1. Table 1. BL2600 Models Feature BL2600 BL2610 Rabbit® 3000 running at 44.2 MHz Rabbit® 3000 running at 29.4 MHz Program Execution SRAM 512K — Data SRAM 256K 512K Microprocessor Flash Memory Ethernet Port RabbitCore Module Used 512K 10/100Base-T, 3 LEDs — RCM3200 RCM3100 Additional memory and clock speed options are available, and are described in Section 1.2.2. The BL2600 consists of a main board with a RabbitCore module. Refer to the RabbitCore module manuals, available on the Web site, for more information on the RabbitCore modules, including their schematics. The BL2600 is programmed over a standard PC serial port through a programming cable supplied with the Tool Kit, and can also be programed through a USB port with an RS-232/USB converter, or over an Ethernet with the RabbitLink (both available from Rabbit). Appendix A provides detailed specifications. Visit the Web site for up-to-date information about additional add-ons and features as they become available. The Web site also has the latest revision of this user’s manual. 2 SBC BL2600 1.2.1 Connector Options In addition to the standard polarized friction-lock connectors supplied on BL2600 boards, dual-entry 0.1" IDC sockets can be used to connect to the BL2600 either from the top or the bottom. 0.1" IDC sockets can accept header pins from either top or bottom Standard polarized friction-lock terminals, 0.1" pitch 1.2.2 Memory and Clock Speed Options In addition to the two standard production models of the BL2600, the concept of pairing a RabbitCore module with the BL2600 “motherboard” allows for additional versions of the BL2600 to be offered for custom orders involving nominal lead times. These additional versions and their part numbers are listed below. Table 2. Additional BL2600 Memory, Clock Speed, and Ethernet Options Feature 101-0906 101-0907 101-0908 101-1095 101-1096 29.4 MHz 29.4 MHz 29.4 MHz 44.2 MHz 44.2 MHz — — — 512K 512K Data SRAM 512K 128K 128K 512K 512K Flash Memory (program) 512K 256K 256K 512K 512K NAND Flash Memory (mass data storage, fixed) — — — 16 Mbytes — Clock Speed Program Execution SRAM NAND Flash Memory (mass data storage, removable memory card) Ethernet Port RabbitCore Module Used up to 128 Mbytes 10/100-compatible 10Base-T interface RCM3000 RCM3010 — RCM3110 10/100Base-T RCM3365 RCM3375 Check the Web site or contact your Digi sales representative or authorized distributor for more information. User’s Manual 3 1.3 Development and Evaluation Tools 1.3.1 Tool Kit A Tool Kit contains the hardware essentials you will need to use your own BL2600 singleboard computer. The items in the Tool Kit and their use are as follows. • Getting Started instructions. • Dynamic C CD-ROM, with complete product documentation on disk. • Programming cable, used to connect your PC serial port to the BL2600. • Universal AC adapter, 12 V DC, 1 A (includes Canada/Japan/U.S., Australia/N.Z., U.K., and European style plugs). If you are using another power supply, it must provide 9 to 36 V DC at 12 W. • Stand-offs to serve as legs for the BL2600 board during development. • Demonstration Board with pushbutton switches and LEDs. The Demonstration Board can be hooked up to the BL2600 to demonstrate the I/O and the TCP/IP capabilities of the BL2600. • Wire assembly to connect Demonstration Board to BL2600. • Connector pins and parts to build your own wire assemblies: 0.1" crimp terminals; 0.156" crimp terminals; 1 × 4, 1 × 10, and 1 × 13 friction-lock connectors. • Rabbit 3000 Processor Easy Reference poster. • Registration card. 4 SBC BL2600 Figure 1. BL2600 Tool Kit 1.3.2 Software The BL2600 is programmed using version 8.51 or later of Rabbit’s Dynamic C. A compat- ible version is included on the Tool Kit CD-ROM. Digi also offers add-on Dynamic C modules for purchase containing the popular µC/OS-II real-time operating system, as well as PPP, Advanced Encryption Standard (AES), and other select libraries. In addition to the Web-based technical support included at no extra charge, a one-year telephone-based technical support module is also available for purchase. Visit our Web site at www.digi.com or contact your Digi sales representative or authorized distributor for further information. 1.3.3 Additional Tools Rabbit also has available additional programming tools and parts to help you to make your own wiring assemblies with the friction-lock connectors. • An RS-232/USB converter cable (Part No. 540-0070) is available for use with the programming cable supplied with the Tool Kit. You will need such a converter if your PC only has a USB port. • Crimp tool (Part No. 998-0013) to secure wire in crimp terminals. Visit our Web site at www.digi.com or contact your Digi sales representative or authorized distributor for further information. User’s Manual 5 1.4 CE Compliance Equipment is generally divided into two classes. CLASS A CLASS B Digital equipment meant for light industrial use Digital equipment meant for home use Less restrictive emissions requirement: less than 40 dB µV/m at 10 m (40 dB relative to 1 µV/m) or 300 µV/m More restrictive emissions requirement: 30 dB µV/m at 10 m or 100 µV/m These limits apply over the range of 30–230 MHz. The limits are 7 dB higher for frequencies above 230 MHz. Although the test range goes to 1 GHz, the emissions from Rabbitbased systems at frequencies above 300 MHz are generally well below background noise levels. The BL2600 single-board computer has been tested and was found to be in conformity with the following applicable immunity and emission standards. The BL2610 single-board computer is also CE qualified as it is a sub-version of the BL2600 single-board computer. Boards that are CE-compliant have the CE mark. NOTE: Earlier versions of the BL2600 that do not have the CE mark are not CE-compliant. Immunity The BL2600 series of single-board computers meets the following EN55024/1998 immunity standards. • EN61000-4-3 (Radiated Immunity) • EN61000-4-4 (EFT) • EN61000-4-6 (Conducted Immunity) Additional shielding or filtering may be required for a heavy industrial environment. Emissions The BL2600 series of single-board computers meets the following emission standards. • EN55022:1998 Class B • FCC Part 15 Class B Your results may vary, depending on your application, so additional shielding or filtering may be needed to maintain the Class B emission qualification. 6 SBC BL2600 1.4.1 Design Guidelines Note the following requirements for incorporating the BL2600 series of single-board computers into your application to comply with CE requirements. General • The power supply provided with the Tool Kit is for development purposes only. It is the customer’s responsibility to provide a CE-compliant power supply for the end-product application. • When connecting the BL2600 single-board computer to outdoor cables, the customer is responsible for providing CE-approved surge/lightning protection. • Rabbit recommends placing digital I/O or analog cables that are 3 m or longer in a metal conduit to assist in maintaining CE compliance and to conform to good cable design practices. • When installing or servicing the BL2600, it is the responsibility of the end-user to use proper ESD precautions to prevent ESD damage to the BL2600. Safety • All inputs and outputs to and from the BL2600 series of single-board computers must not be connected to voltages exceeding SELV levels (42.4 V AC peak, or 60 V DC). • The lithium backup battery circuit on the BL2600 single-board computer has been designed to protect the battery from hazardous conditions such as reverse charging and excessive current flows. Do not disable the safety features of the design. 1.4.2 Interfacing the BL2600 to Other Devices Since the BL2600 series of single-board computers is designed to be connected to other devices, good EMC practices should be followed to ensure compliance. CE compliance is ultimately the responsibility of the integrator. Additional information, tips, and technical assistance are available from your authorized Rabbit distributor, and are also available on our Web site at www.digi.com. User’s Manual 7 8 SBC BL2600 2. GETTING STARTED Chapter 2 explains how to connect the programming cable and power supply to the BL2600. 2.1 Preparing the BL2600 for Development Position the BL2600 as shown below in Figure 2. Attach the four standoffs supplied with the Tool Kit in the holes at the corners as shown. DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND 40 J16 RP4 GN D +K DC IN +5V JP3 JP4, AND JP4 C4 1 2 RP3 1 R5 C5 C6 15 16 33 34 J10 R9 ACT LNK R58 R59 R60 C35 C36 C37 RXE C32 U18 C30 RXC RXF U17 SPD RC M2 DS1 DS2 R71 DS3 R75 C31 34 U10 C26 R56 C24R 57 R55 R42 R37 U3 RP1 3 RP1 1 Q11 C16 R31 C21 33 R3 R4 R1 R2 RP1 0R P9 RP8 RP7 C7 C15 R11 2 C11 R11 R13 R12 R14 C12 C19 15 JP1 AND JP2 R23 C R24 18 16 2 JP2 GND DIO12 DIO08 DIO04 DIO00 DIO14 DIO10 DIO06 DIO02 GND R41 R36 DS RP1 1 DIO 0815 PULLS J3 GND DIN28 DIN24 DIN20 DIN16 DIN30 DIN26 DIN22 DIN18 +K R40 R35 1 JP1 2 DIO 0007 PULLS 39 SW1 GN D +K DC IN +5V RESET R33 R34R 22 JP3 R39 DIN 1619 PULLS JP4 R42 R38 DIN 2023 PULLS C33 R44 C4 C18 C35 +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND C12 C29 R74 J14 RabbitCore Module 485 TERM. RESISTOR 485+ JP7 2 26 1 25 +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND C34 D4 Q20 Q19 C30 R67 R70 GND J4 C79 Y4 C83 GND R27 R31 GND GND R8 U16 C72 DCIN GND/EGND C61 D3 C23 C37 C36 D2 Q18 RP1 R29 R37 R39 R40 R7 C86 GND C28 RP5 RP6 R6 U4 C71 C27 C17 C28 C27 C25 J12 Y3 R51 R49 R48 D1 Q17 RP18 C64 C67 C33 1 DCIN L2 C68 R63 R64 2 C22 J15 JP5 AGND JP4 AI3 R47 AI2 R28 AI1 R44 ND AI0 C49 AG U15 J13 19 AV3 C62 R73 BT1 J11 1 C57 L1 R69 20 AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND C59 U8 C23 R25 R35 RP17 C42 C48 7 R43 AV0 AV1 AV2 U9 R58 L1 U2 JA R72 6 AI N R32 U14 2 AIN0 AIN1 AIN2 AIN3 JP6 420 mA C53 C75 C74 5 AI N JP6 C9 C5 C1 RCM1 RCM3000 ETHERNET CORE MODULE Q1 R41 C47 C3 U1 U5 U6 R18 R30 C31 JP3 1 AI 4 AI N R26 R28 U13 R23 C14 C78 C20 R19 R27 R29 R20 R84 U4 D1 C45 C44 C43 R38 0 AI N 3 AI N R25 U8 C39 AIN N2 AIN R20 R17 R21 R22 C8 C17 R15 C13 U12 R16 J3 RP14 RP15 RP16 J9 R111 U11 R19 Q14 Q15 Q16 RP12 U7 J7 C10 R10 U1 C9 C8 R10 R14 Q8 C16 C15 C3 Q7 C32 U6 Q12 Q13 Q6 C20 C2 Q5 C24 Q10 Q4 R24 U5 J6 RABBITNET 0 Q3 C19 J5 Q2 JP5 RP2 R8 C1 Q1 Q9 J8 DIN 2431 PULLS J1 J2 +K DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 R1 R7 R9 R17 R18 J4 RABBITNET 1 TXC GND TXC TXF TXE 485 J17 RXC RXF RXE 485+ TXF TXE 485 GND Figure 2. Attach Standoffs to BL2600 Board The standoffs facilitate handling the BL2600 during development, and protect the bottom of the printed circuit board against scratches or short circuits while you are working with the BL2600. User’s Manual 9 2.2 BL2600 Connections 1. Connect the programming cable to download programs from your PC and to program and debug the BL2600. NOTE: Use only the programming cable that has a blue shrink wrap around the RS-232 level converter (Part No. 101-0542). If you are using a BL2610, which is based on the RCM3100, you will need the programming cable that has a red shrink wrap around the RS-232 level converter (Part No. 101-0513). Other programming cables are not be voltage-compatible or their connector sizes may be different. Connect the 10-pin PROG connector of the programming cable to header J3 on the BL2600’s RabbitCore module (the programming header is labeled J1 on special-edition BL2600s based on the RCM3365/RCM3375). Ensure that the colored edge lines up with pin 1 as shown. (Do not use the DIAG connector, which is used for monitoring only.) Connect the other end of the programming cable to a COM port on your PC. Make a note of the port to which you connect the cable, as Dynamic C will need to have this parameter configured. Note that COM1 on the PC is the default COM port used by Dynamic C. J2 +K DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 1 2 RP4 GND +K DCIN +5V JP3, JP4 AND JP4 RP3 C4 15 16 C5 C6 33 J10 C31 U16 C64 C67 C68 R9 C16 34 33 34 U10 L2 D1 Q17 20 1 19 C25 J12 GND RCM2 C30 C34 C35 C36 C37 RXE RXC RXF 2 26 2 1 25 1 GND J16 DCIN DCIN GND D4 Q20 +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND +HK0 GND HOUT1 +HK2 GND HOUT3 GND HOUT0 +HK1 GND HOUT2 +HK3 GND DS2 DS3 C32 GND U18 R58 R59 R60 485 TERM. RESISTOR 485+ J14 J13 J15 AGND D3 Q19 U15 C22 AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND D2 Q18 C86 SPD LNK ACT C26 C24R57 R56 R31 C21 R55 R42 R37 R41 R36 R44 R75 C33 C28 DS1 R71 R74 R73 C27 2 AI3 U17 J4 C79 Y4 R69 C83 L1 J11 AV0 AV1 AV2 AV3 AI0 AI1 AI2 R63 R64 R67 R70 C19 R8 C62 C72 R40 R35 R5 15 16 RP13 RP11 R3 R2 R4 Q11 RP10 RP9 C7 C15 R112 R11 C11 R13 C12 L1 R51 R49 R48 R14 R7 C61 R47 R44 R12 C49 R23 C18 R24 U3 JP1 AND JP2 R1 D S1 39 RP1 2 JP2 GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND RP8 RP7 1 2 1 DIO 0815 PULLS J3 SW1 JP3 R42 C48 R39 C35 C33 C29 R31 R27 JP5 R33 R34R22 C30 C37 C36 R28 R38 C23 JP3 JP4 BT1 R32 C23 U14 R43 AIN0 AIN1 AIN2 AIN3 JP6 420 mA U8 C57 R72 R30 GND/EGND C59 C71 R19 R29 R26 R28 R29 R37 R39 R40 JA Y3 R58 R18 C20 R25 R27 U4 C42 Q1 C75 U13 JP6 C14 C78 C17 R35 R41 C53 C74 AGND R21 C47 R111 R15 C13 U12 R16 R17 R20 U11 U6 U9 C9 R25 RP17 RP18 RP1 RCM1 U5 RCM3000 ETHERNET CORE MODULE C8 C45 C44 C43 R38 PROG AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 C10 R10 R6 C28 C27 C39 J1 J9 J7 J8 RP6 C18 U4 C31 C4 R17 R18 R23 U2 C17 R22 D1 RP16 RP5 C3 U1 C5 R19 R20 C24 U8 C1 R10 R14 C20 RP14 RP15 RP12 U7 J3 C32 J6 RABBITNET 0 C3 R8 R7 R9 Q8 Q14 Q15 Q16 Q12 Q13 U6 Q7 R24 U5 Q6 C12 C2 Q5 C16 C15 Q10 Q9 Q4 C9 C8 Q3 R84 U1 C1 Q2 PROG C19 Q1 J5 JP4 RP2 R1 JP5 DIO 0007 PULLS JP1 40 RESET GND +K DCIN +5V DIN 1619 PULLS DIAG To PC COM port J4 RABBITNET 1 DIN 2023 PULLS Colored edge Color shrink wrap DIN 2431 PULLS GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND J1 DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 Programming Cable JP7 TXC GND TXC TXF RXC TXF TXE RXF TXE 485 RXE J17 485+ 485 GND Figure 3. Programming Cable Connections NOTE: Some PCs now come equipped only with a USB port. It may be possible to use an RS-232/USB converter (Part No. 20-151-0178) with the programming cables mentioned above. Note that not all RS-232/USB converters work with Dynamic C. 10 SBC BL2600 2. When all other connections have been made, you can connect power to the BL2600. First, prepare the AC adapter for the country where it will be used by selecting the plug. The BL2600 Tool Kit presently includes Canada/Japan/U.S., Australia/N.Z., U.K., and European style plugs. Snap in the top of the plug assembly into the slot at the top of the AC adapter as shown in Figure 4, then press down on the spring-loaded clip below the plug assembly to allow the plug assembly to click into place. Connect the AC apapter to header J12 on the BL2600 as shown in Figure 4. You can use the crimps and the friction-lock connector included in the Tool Kit to connect the leads from the power supply, then match the friction lock tab on the friction-lock connector to the back of header J12 on the BL2600 as shown. The friction-lock connector will only fit one way. Figure 4. Power Supply Connections 3. Apply power. Plug in the AC adapter. The power LED will light up when the BL2600 is powered up correctly. CAUTION: Unplug the AC adapter while you make or otherwise work with the connections to the headers. This will protect your BL2600 from inadvertent shorts or power spikes. 2.2.1 Hardware Reset A hardware reset is done by unplugging the ACV adapter, then plugging it back in, or by pressing the RESET button located just above the RabbitCore module. User’s Manual 11 2.3 Installing Dynamic C If you have not yet installed Dynamic C version 8.51 (or a later version), do so now by inserting the Dynamic C CD from the BL2600 Tool Kit in your PC’s CD-ROM drive. The CD will auto-install unless you have disabled auto-install on your PC. If the CD does not auto-install, click Start > Run from the Windows Start button and browse for the Dynamic C setup.exe file on your CD drive. Click OK to begin the installation once you have selected the setup.exe file. The online documentation is installed along with Dynamic C, and an icon for the documentation menu is placed on the workstation’s desktop. Double-click this icon to reach the menu. If the icon is missing, create a new desktop icon that points to default.htm in the docs folder, found in the Dynamic C installation folder. The latest versions of all documents are always available for free, unregistered download from our Web sites as well. The Dynamic C User’s Manual provides detailed instructions for the installation of Dynamic C and any future upgrades. NOTE: If you have an earlier version of Dynamic C already installed, the default installation of the later version will be in a different folder, and a separate icon will appear on your desktop. Once your installation is complete, you will have up to three icons on your PC desktop. One icon is for Dynamic C, one opens the documentation menu, and the third is for the Rabbit Field Utility, a tool used to download precompiled software to a target system. If you have purchased any of the optional Dynamic C modules, install them after installing Dynamic C. The modules may be installed in any order. You must install the modules in the same directory where Dynamic C was installed. 12 SBC BL2600 2.4 Starting Dynamic C Once the BL2600 is connected to your PC and to a power source, start Dynamic C by double-clicking on the Dynamic C icon on your desktop or in your Start menu. If you are using a USB port to connect your computer to the BL2600, choose Options > Project Options and check “Use USB to Serial Converter” in “Serial Options” on the Communications tab. Click OK to save the settings. If you are using a BL2600 model running at 44.2 MHz, set the compiler to run the application in the fast program execution SRAM by selecting “Code and BIOS in Flash, Run in RAM” in the “BIOS Memory Setting” on the Compiler tab under the Options > Project Options menu. Click OK to save the settings. Dynamic C defaults to using the serial port on your PC that you specified during installation. If the port setting is correct, Dynamic C should detect the BL2600 and go through a sequence of steps to cold-boot the BL2600 and to compile the BIOS. (Some versions of Dynamic C will not do the initial BIOS compile and load until the first time you compile a program.) If you receive the message No Rabbit Processor Detected, the programming cable may be connected to the wrong COM port, a connection may be faulty, or the target system may not be powered up. First, check both ends of the programming cable to ensure that it is firmly plugged into the PC and the programming port. If there are no faults with the hardware, select a different COM port within Dynamic C. On your computer, open Control Panel > System > Hardware > Device Manager > Ports and look at the list of available COM ports. In Dynamic C, select Options > Project Options, then select one of these available COM ports on the Communications tab, then click OK. Press <Ctrl-Y> to force Dynamic C to recompile the BIOS. If Dynamic C still reports it is unable to locate the target system, repeat the above steps for another available COM port. You should receive a Bios compiled successfully message once this step is completed successfully. If Dynamic C appears to compile the BIOS successfully, but you then receive a communication error message when you compile and load a sample program, it is possible that your PC cannot handle the higher program-loading baud rate. Try changing the maximum download rate to a slower baud rate as follows. • Locate the Serial Options dialog in the Dynamic C Options > Communications menu. Select a slower Max download baud rate. Click OK to save the settings. If a program compiles and loads, but then loses target communication before you can begin debugging, it is possible that your PC cannot handle the default debugging baud rate. Try lowering the debugging baud rate as follows. • Locate the Serial Options dialog in the Dynamic C Options > Communications menu. Choose a lower debug baud rate. Click OK to save the settings. User’s Manual 13 2.5 PONG.C You are now ready to test your set-up by running a sample program. Find the file PONG.C, which is in the Dynamic C SAMPLES folder. To run the program, open it with the File menu (if it is not still open), compile it using the Compile menu, and then run it by selecting Run in the Run menu. The STDIO window will open and will display a small square bouncing around in a box. This program shows that the CPU is working. The sample program described in Section 5.2.3, “Run the PINGME.C Demo,” tests the TCP/IP portion of the board. 2.6 Where Do I Go From Here? NOTE: If you purchased your BL2600 through a distributor or Rabbit partner, contact the distributor or partner first for technical support. If there are any problems at this point: • Use the Dynamic C Help menu to get further assistance with Dynamic C. • Check the Rabbit Technical Bulletin Board and forums at www.rabbit.com/support/bb/ and at www.rabbit.com/forums/. • Use the Technical Support e-mail form at www.rabbit.com/support/questionSubmit.shtml. If the sample program ran fine, you are now ready to go on to explore other BL2600 features and develop your own applications. Chapter 3, “Subsystems,” provides a description of the BL2600’s features, Chapter 4, “Software,” describes the Dynamic C software libraries and introduces some sample programs, and Chapter 5, “Using the TCP/IP Features,” explains the TCP/IP features. 14 SBC BL2600 3. SUBSYSTEMS Chapter 3 describes the principal subsystems for the BL2600. •Digital I/O •Serial Communication •A/D Converter Inputs •D/A Converter Outputs •Analog Reference Voltage Circuit •Memory Figure 5 shows these Rabbit-based subsystems designed into the BL2600. Ethernet 32 kHz 22.1 MHz osc osc RS-232 RS-485 RabbitNet SRAM Program Flash RABBIT 3000 Battery-Backup Circuit RabbitCore Module Optional Serial or NAND Flash Card Data Register Digital Inputs Data Register Configurable I/O Data Register High-Current Outputs A/D Converter D/A Converter Figure 5. BL2600 Subsystems User’s Manual 15 3.1 BL2600 Pinouts The BL2600 pinouts are shown in Figure 6(a) and Figure 6(b). Digital Inputs GND GND DIO00 DIO01 DIO02 DIO03 DIO04 DIO05 DIO06 DIO07 DIO08 DIO09 DIO10 DIO11 DIO12 DIO13 DIO14 DIO15 GND +K Digital Inputs +K GND DIN16 DIN17 DIN18 DIN19 DIN20 DIN21 DIN22 DIN23 GND +K DIN24 DIN25 DIN26 DIN27 DIN28 DIN29 DIN30 DIN31 GND +K Configurable I/O J1 J2 R1 R8 C23 C30 C33 C35 JP3 JP4 C37 C36 R31 R27 R28 C39 R25 JP5 RabbitNet C4 C18 RP1 U5 U6 R35 R29 R37 C42 R39 R40 C45 C44 C43 R38 Y3 Q1 R41 C49 C59 C57 L1 R51 R49 R48 U8 C61 R47 R44 J8 R42 C48 C53 Battery C12 C29 C28 C27 C32 C31 C47 C62 L2 C68 R58 Ethernet C64 C67 J4 C79 Y4 R71 R74 C83 R72 R73 AGND DS1 R67 R70 C75 R63 R64 R69 R75 C86 GND GND DCIN DCIN Power Supply 0 1 2 High-Current Digital Outputs 3 GND TXC RXC TXF RXF TXE RXE 485+ 485 GND RS-485 Analog Ground +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND RS-232 CURRENT Analog Outputs GND J17 GND +HK0 HOUT0 GND +HK1 HOUT1 GND +HK2 HOUT2 GND +HK3 HOUT3 GND VOLTAGE AGND AGND AI3 AV0 AV1 AV2 AV3 AI0 AI1 AI2 AI3 AV0 AV1 AV2 AV3 AI0 AI1 AI2 J16 DS3 GND GND TxC RxC TxF RxF TxE RxE 485 485+ GND J12 J15 DS2 SPD LNK ACT C72 C71 C74 Analog Ground C17 R24 U4 D1 J7 C24 R23 C20 R20 C19 R22 C16 C15 R19 J3 J6 Analog Inputs U1 C5 R17 R18 J4 C9 C8 R10 R14 J5 AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 C3 C1 R7 R9 Figure 6(a). BL2600 Pinouts (friction-lock connectors) 16 SBC BL2600 GND DIO01 DIO03 DIO05 DIO07 DIO09 DIO11 DIO13 DIO15 GND +K DIN17 DIN19 DIN21 DIN23 DIN25 DIN27 DIN29 DIN31 GND Configurable +K Digital Inputs I/O TOP VIEW GND DIO00 DIO02 DIO04 DIO06 DIO08 DIO10 DIO12 DIO14 GND +K DIN16 DIN18 DIN20 DIN22 DIN24 DIN26 DIN28 DIN30 GND J3 R1 R8 C3 U1 C5 C23 C33 R27 R31 R35 R29 R37 C42 R39 R40 C45 C44 C43 R38 Y3 Q1 R41 R42 C48 C47 C49 C53 C61 C57 L1 R51 R49 R48 R47 R44 C59 U8 Battery C30 C37 C36 JP5 R28 C39 R25 U5 U6 J6 RP1 C35 JP3 JP4 RabbitNet C18 C29 C28 C27 C32 C31 C12 R24 U4 D1 J7 C20 R20 R23 C24 R22 C19 J3 C17 R19 J4 C16 C15 R17 R18 C4 R10 R14 J5 C9 C8 C1 R7 R9 C62 L2 C68 R58 C64 C67 C79 Y4 CURRENT R75 Analog Ground 3 High-Current Digital Outputs RS-485 2 RS-232 GND GND DCIN DCIN CURRENT VOLTAGE 1 TxC GND TxF GND TxE GND 485 GND +HK0 HOUT0 GND +HK1 HOUT1 GND +HK2 HOUT2 GND +HK3 HOUT3 GND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND 0 Power Supply Analog Outputs Analog Ground DS3 GND J14 J13 J12 DS2 RxC GND RxF GND RxE GND 485+ AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND GND +HK0 HOUT0 GND +HK1 HOUT1 GND +HK2 HOUT2 GND +HK3 HOUT3 GND C86 J11 Analog Inputs DS1 R71 R74 C83 R72 R73 VOLTAGE J4 R67 R70 R69 SPD LNK ACT R63 R64 C75 C74 C72 C71 Figure 6(b). BL2600 Pinouts (IDC sockets) NOTE: Remember that the pinouts will mirror those shown above when they are viewed from the other side of the board. User’s Manual 17 3.1.1 Connector Options Standard BL2600 models are equipped with two 1 × 20 friction-lock connector terminals (J1 and J2), two polarized 1 × 10 friction-lock connector terminals (J8 and J15) where pin 9 is removed to polarize the connector terminals, one 1 × 13 friction-lock connector terminal (J16), and one 1 × 10 friction-lock connector terminal (J17); all of these friction-lock connector terminals have a 0.1" pitch. Two 4-pin 0.156" friction-lock connector terminals at J5 and J7 are installed to supply power (DCIN and +5 V) to the RabbitNet peripheral expansion boards. The 4-pin 0.156" friction-lock connector terminal at J12 is for the main power supply connections. Table 3 lists Molex connector part numbers for the crimp terminals, housings, and polarizing keys needed to assemble female friction-lock connector assemblies for use with their male counterparts on the BL2600. Table 3. Female Friction-Lock Connector Parts Friction-Lock Connector Used with BL2600 Headers Housing Part Number Crimp Terminals 0.1" 1 × 20 J1, J2 TEC 2-770602-0 TEC 770601-1 None 0.1" 1 × 13 J16 Molex 22-01-2137 Molex 08-50-0113 Molex 15-04-9209 0.1" 1 × 10 J8, J15, J17 Molex 22-01-2107 0.156" 1 × 4 J5, J7, J12 Molex 09-50-3041 Molex 08-50-0108 Molex15-04-0219 Polarizing Keys The RJ-45 jacks at J4 and J6 labeled RabbitNet are serial I/O expansion ports for use with RabbitNet peripheral expansion boards. The RabbitNet jacks do not support Ethernet connections. The BL2600 also has 2 × 20, 2 × 13, 2 × 10, and 2 × 7 IDC sockets with a pitch of 0.1" in addition to the friction-lock connectors. Corresponding headers or ribbon cables may be plugged into these sockets from either the top or the bottom. A top view of the pinouts for these sockets is shown in Figure 6(b). 18 SBC BL2600 3.2 Digital I/O 3.2.1 Digital Inputs The BL2600 has 16 digital inputs, DIN16–DIN31, each of which is protected over a range of –36 V to +36 V. The inputs are factory-configured to be pulled up to +5 V, but they can also be pulled up to +K or DCIN, or pulled down to 0 V in banks by changing a jumper as shown in Figure 7. CAUTION: Do not simultaneously jumper more than one setting on a particular jumper header (JP3, JP4, and JP5) when configuring a bank of digital inputs. DCIN +5 V +3.3 V +K 27 kW DIN16DIN31 DIN16DIN19 100 kW DIN24DIN31 Rabbit® 3000 Microprocessor DIN20DIN23 27 kW Figure 7. BL2600 Digital Inputs DIN16–DIN31 [Pulled Up—Factory Default] Table 4 lists the banks of digital inputs and summarizes the jumper settings. Table 4. Banks of BL2600 Digital Inputs Digital Inputs Header Pins Jumpered Pulled Up/Pulled Down DIN16–DIN19 JP3 1–2 Inputs pulled up to +5 V DIN20–DIN23 JP4 3–4 Inputs pulled up to DCIN DIN24–DIN31 JP5 5–6 Inputs pulled up to +K 7–8 Inputs pulled down to GND When you use the software digIn function call to read the digital inputs, DIN16–DIN31 are considered to be digital input channels 16–31. User’s Manual 19 NOTE: If the inputs are pulled up to +K or to DCIN, the voltage range over which the digital inputs are protected changes to +K (or DCIN) – 36 V to +36 V. Individual DIN16–DIN23 channels may be used for interrupts, input capture, as quadrature decoders, or as PWM outputs. Normal Switching Levels +40 V Digital Input Voltage The actual switching threshold is approximately 1.40 V. Anything below this value is a logic 0, and anything above is a logic 1. The digital inputs are each fully protected over a range of -36 V to +36 V, and can handle short spikes of ±40 V. Spikes +36 V Spikes +3.3 V 40 V Spikes Figure 8. BL2600 Digital Input Protected Range The use of these channels for interrupts, input capture, and as quadrature decoders is described in the Rabbit 3000 Microprocessor User’s Manual, and is illustrated through sample programs in the Dynamic C SAMPLES\RABBIT3000 folder. Table 5 lists these alternate uses. Table 5. Alternate Uses for BL2600 Channels DIN16–DIN23 Channel Interrupt DIN16 × DIN17 × Input Capture DIN18 DIN19 × × DIN22 DIN23 PWM Outputs × DIN20 DIN21 Quadrature Decoder × × × × × × × × × × 3.2.2 PWM Outputs Digital inputs DIN20–DIN23 can be used as PWM output channels by setting the jumper on header JP4 across pins 7–8 to pull the digital inputs to ground. Once the PWM driver sets up a given PWM channel, the corresponding digital input channel is no longer available for use as a digital input. The output voltage swing will be 0 to 1.65 V, which is not suitable for interfacing only to CMOS-level inputs. Since the output impedance is approximately 13 k, the input impedance of the circuit the PWM output is connected to should be at least 10 times as high. The sample program PWM.C in the IO subdirectory in SAMPLES\BL2600 shows how to set up and use the PWM outputs. 20 SBC BL2600 3.2.3 High-Current Digital Outputs The BL2600 has four high-current digital outputs, HOUT0–HOUT3, which can each sink or source up to 2 A. Figure 9 shows a wiring diagram for using the digital outputs in either a sinking or a souring configuration. +HKx A MMBT4401 10 kW 27 kW 10 kW (in sinking mode) 1 nF 100 kW B 330 W (in sourcing mode) 100 kW 1 nF Figure 9. BL2600 High-Current Digital Outputs All the digital outputs sink and source actively. They can be used as high-side drivers, lowside drivers, or as an H-bridge driver. When the BL2600 is first powered up or reset, all the outputs are disabled, that is, at a high-impedance tristate, until the digHoutConfig software function call is made. The digHoutConfig call sets the initial state of each high-current output according to the configuration specified by the user, and enables the digital outputs to their initial status. Table 6. BL2600 High-Current Outputs Logic States U3 Output High-Current Output User’s Manual A B High High Prohibited (defaults to sourcing) High Low Sourcing Low High Sinking Low Low High-impedance (tristate) 21 Each high-current output has its own +K supply. When wiring the high-current outputs, keep the distance to the power supply as short as possible. GND +HK0 HOUT0 GND +HK1 HOUT1 GND +HK2 HOUT2 GND +HK3 HOUT3 GND CAUTION: If you are using a BL2600 with the IDC header connectors, beware that an individual IDC header pin can only handle up to 1 A. Since the same high-current outputs are available on opposite pairs of IDC header connectors, you can still use the 2 A sinking or sourcing capability of the BL2600 by wiring all your connections, including the ground, in parallel to the opposite pairs (see Figure 10 for an example). +HK0 GND +HK0 HOUT0 GND +HK1 HOUT1 GND +HK2 HOUT2 GND +HK3 HOUT3 GND J13 0 1 2 3 Figure 10. Example of Wiring HK0 In Parallel on IDC Header For the H bridge, which is shown in Figure 11, Ka and Kb should be the same. +Ka A B +Kb LOAD B A Figure 11. H Bridge 22 SBC BL2600 3.2.4 Configurable I/O The BL2600 has 16 configurable I/O that may be configured individually in software as either digital inputs or as sinking digital outputs. By default, a configurable I/O channel is a digital input, but may be set as a sinking digital output by using the digOutConfig function call. The inputs are factory-configured to be pulled up to +5 V, but they can also be pulled up to +K or DCIN, or pulled down to 0 V in banks by changing a jumper as shown in Figure 12. CAUTION: Do not simultaneously jumper more than one setting on a particular jumper header (JP1 and JP2) when configuring a bank of configrable I/O. +K +5 V Sinking Output setting DCIN +K Factory Default setting 27 kW DIGITAL INPUT Buffer DIO00DIO15 100 kW Rabbit® 3000 Microprocessor +K SINKING OUTPUT Latch 220 W 27 kW GND Figure 12. BL2600 Configurable I/O DIO00–DIIO15 [Inputs Pulled Up—Factory Default] User’s Manual 23 When you use the software digIn function call to read the configurable I/O, DIO00– DIO15 are considered to be digital input channels 00–15. Note that the digIn function call can also read these channels if they are set to be sinking digital outputs. Table 7 lists the banks of configured digital inputs and summarizes the jumper settings. Table 7. Banks of BL2600 Configured Digital Inputs Digital Inputs Header Pins Jumpered Pulled Up/Pulled Down DIO00–DIO07 JP1 1–2 Inputs pulled up to +5 V DIO08–DIO15 JP2 3–4 Inputs pulled up to DCIN 5–6 Inputs pulled up to +K 7–8 Inputs pulled down to GND As for the nonconfigurable digital inputs, the actual switching threshold is approximately 1.40 V. Anything below this value is a logic 0, and anything above is a logic 1. The digital inputs are each fully protected over a range of -36 V to +36 V, and can handle short spikes of ±40 V. NOTE: If the inputs are pulled up to +K or to DCIN, the voltage range over which the digital inputs are protected changes to +K (or DCIN) – 36 V to +36 V. When set as a sinking digital output, a configurable I/O channel can sink up to 200 mA at up to 40 V. When you use the software digOutConfig function call to set the configurable I/O, DIO00–DIO15 are considered to be digital output channels 00–15. The output can be set up either as a sinking output or it can be put in a high-impedance tristate. When a configurable I/O is configured as a sinking output, be sure to connect an external voltage source up to 36 V DC across +K and GND on header J1/J3, and set the pullup jumper on the corresponding JP1/JP2 header to +K. +K LOAD DIO00DIO15 GND Figure 13. Load and +K Power Supply Connections for Sinking Digital Output 24 SBC BL2600 3.3 Serial Communication The BL2600 has three serial communication ports, which can be configured as one RS-232 serial channel (with RTS/CTS) and one RS-232 (3-wire) channel or one RS-485 channel, or as three RS-232 (3-wire) channels, or as two RS-232 (3-wire) channels and one RS-485 channel by using the serMode software function call. Table 8 summarizes the options. Table 8. Serial Communication Configurations Serial Port Mode C E F 0 RS-232, 3-wire RS-232, 3-wire RS-232, 3-wire 1 RS-232, 3-wire RS-485 RS-232, 3-wire 2 RS-232, 5-wire RS-232, 3-wire CTS/RTS 3 RS-232, 5-wire RS-485 CTS/RTS The BL2600 also has one CMOS serial channel that serves as the programming port. All four serial ports operate in an asynchronous mode. An asynchronous port can handle 7 or 8 data bits. A 9th bit address scheme, where an additional bit is sent to mark the first byte of a message, is also supported. Serial Port A, the programming port, can be operated alternately in the clocked serial mode. In this mode, a clock line synchronously clocks the data in or out. Either of the two communicating devices can supply the clock. The BL2600 boards typically use all four ports in the asynchronous serial mode. Serial Ports C and F are used for RS-232 communication, and Serial Port E is used for RS-232 or RS-485 communication. The BL2600 uses a 22.12 MHz resonator, which is doubled to 44.2 MHz. At this frequency, the BL2600 supports standard asynchronous baud rates up to a maximum of 5.525 Mbps. 3.3.1 RS-232 The BL2600 RS-232 serial communication is supported by an RS-232 transceiver. This transceiver provides the voltage output, slew rate, and input voltage immunity required to meet the RS-232 serial communication protocol. Basically, the chip translates the Rabbit 3000’s CMOS signals to RS-232 signal levels. Note that the polarity is reversed in an RS-232 circuit so that a +3.3 V output becomes approximately -10 V and 0 V is output as +10 V. The RS-232 transceiver also provides the proper line loading for reliable communication. RS-232 can be used effectively at the BL2600’s maximum baud rate for distances of up to 15 m. 3.3.2 RS-485 The BL2600 can be set for one RS-485 serial channel, which is connected to the Rabbit 3000 Serial Port E through an RS-485 transceiver. The half-duplex communication uses the Rabbit 3000’s PE3 pin to control the transmit enable on the communication line. User’s Manual 25 GND RS485+ RS-485 GND RS485+ RS-485 GND RS485+ RS-485 The BL2600 can be used in an RS-485 multidrop network. Connect the 485+ to 485+ and 485– to 485– using single twisted-pair wires (nonstranded, tinned) as shown in Figure 14. Note that a common ground is recommended. Figure 14. BL2600 Multidrop Network The BL2600 comes with a 220 termination resistor and two 681 bias resistors installed and enabled with jumpers across pins 1–2 and 5–6 on header JP7, as shown in Figure 15. DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 R55 R42 R37 20 1 19 C4 R5 D2 Q18 DCIN DCIN GND GND 1 33 34 J10 C31 U17 DS1 R71 R75 C86 D4 Q20 C34 C35 C36 C37 RXE RXC RXF 2 26 2 1 25 1 GND +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND GND +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND DS3 U18 C30 D3 Q19 DS2 C32 GND R58 R59 R60 485 TERM. RESISTOR 485+ J14 J16 J15 AGND C28 J13 C22 AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND 15 16 C5 C6 R9 RCM2 J4 R73 U15 C25 J12 2 RP4 GND +K DCIN +5V JP3, JP4 AND JP4 RP3 C79 Y4 5 3 1 SPD LNK ACT C26 C24R57 R56 R31 C21 DS1 1 U10 C15 C16 C19 R41 R36 R40 R35 33 34 C7 R112 R11 C11 R12 R13 C12 R14 C71 R63 R64 R74 R23 C18 R24 R8 U16 C64 C67 C83 R39 JP7 C68 R67 R70 R33 R34R22 C62 C72 R38 U3 16 RP13 RP11 R3 R2 R4 Q11 RP10 RP9 15 JP2 JP1 AND JP2 R1 RP1 DIO 0815 PULLS GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND RP8 RP7 2 2 1 40 JP1 J3 39 DIO 0007 PULLS GND +K DCIN +5V SW1 JP3 R42 6 4 R51 R49 R48 2 C33 L1 2 L2 R69 C27 D1 Q17 C30 R27 R31 R7 C61 R44 C23 C35 C37 C36 C59 C57 C33 J11 AI3 R47 R44 L1 R32 C23 U14 AV0 AV1 AV2 AV3 AI0 AI1 AI2 C49 R26 R28 R30 GND/EGND U8 R72 R19 R25 R27 R29 BT1 R29 R37 R39 R40 JA Q1 C48 R58 R18 C20 JP5 R28 C17 R43 AIN0 AIN1 AIN2 AIN3 JP6 420 mA Factory Default C74 AGND R21 U13 JP6 C14 C78 U4 C42 R41 C53 R111 R15 C13 U12 R16 R17 R20 U11 C47 R35 Y3 C75 AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 C10 R10 U5 U6 U9 C9 R25 RP17 RP18 RP1 RCM1 RCM3000 ETHERNET CORE MODULE C8 C45 C44 C43 R38 J9 J7 J8 R6 C29 JP3 C39 RP16 C28 C27 C31 D1 RP6 C18 U4 JP4 U8 C20 R20 R23 C24 R22 U2 C12 R17 R18 RP14 RP15 RP12 U1 C5 R19 J3 RP5 C3 R10 R14 C17 Q14 Q15 Q16 C1 U1 R8 C19 R96 681 W U7 R1 R7 R9 Q8 C32 U6 C3 Q7 R24 485 U5 Q12 Q13 bias C2 Q6 JP4 R98 220 W C16 C15 Q10 Q9 J6 RABBITNET 0 termination Q3 Q4 Q5 JP5 Q2 RESET 6 Q1 C4 5J5 R84 C9 C8 7 RP2 C1 J4 RABBITNET 1 DIN 1619 PULLS R97 681 W bias 2 DIN 2023 PULLS JP7 1 DIN 2431 PULLS J1 J2 GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND 6 +K U17 DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 485+ JP7 TXC GND TXC TXF RXC TXF TXE RXF TXE 485 RXE J17 485+ 485 GND Figure 15. RS-485 Termination and Bias Resistors 26 SBC BL2600 For best performance, the bias and termination resistors in a multidrop network should only be enabled on both end nodes of the network. Disable the termination and bias resistors on any intervening BL2600 units in the network by removing both jumpers from header JP6. TIP: Save the jumpers for possible future use by “parking” them across pins 1–3 and 4–6 of header JP7. Pins 3 and 4 are not otherwise connected to the BL2600. 3.3.3 Programming Port The RabbitCore module on the BL2600 has a 10-pin programming header. The programming port uses the Rabbit 3000’s Serial Port A for communication, and is used for the following operations. • Programming/debugging • Cloning The programming port is used to start the BL2600 in a mode where the BL2600 will download a program from the port and then execute the program. The programming port transmits information to and from a PC while a program is being debugged. The Rabbit 3000 startup-mode pins (SMODE0, SMODE1) are presented to the programming port so that an externally connected device can force the BL2600 to start up in an external bootstrap mode. The BL2600 can be reset from the programming port via the /EXT_RSTIN line. The Rabbit 3000 status pin is also presented to the programming port. The status pin is an output that can be used to send a general digital signal. NOTE: Refer to the Rabbit 3000 Microprocessor User’s Manual for more information related to the bootstrap mode. User’s Manual 27 3.3.4 Ethernet Port Figure 16 shows the pinout for the Ethernet port (J4 on the BL2600 module). Note that there are two standards for numbering the pins on this connector—the convention used here, and numbering in reverse to that shown. Regardless of the numbering convention followed, the pin positions relative to the spring tab position (located at the bottom of the RJ-45 jack in Figure 16) are always absolute, and the RJ-45 connector will work properly with off-the-shelf Ethernet cables. ETHERNET 1 8 1. 2. 3. 6. RJ-45 Plug E_Tx+ E_Tx E_Rx+ E_Rx RJ-45 Jack Figure 16. RJ-45 Ethernet Port Pinout Two LEDs are placed next to the RJ-45 Ethernet jack, one to indicate an Ethernet link (LNK) and one to indicate Ethernet activity (ACT). The RJ-45 connector is shielded to minimize EMI effects to/from the Ethernet signals. 28 SBC BL2600 3.4 A/D Converter Inputs The single A/D converter chip used in the BL2600 has a resolution of 12 bits (11 bits for the value and one bit for the polarity). The A/D converter chip has a programmable amplifier. Each external input has circuitry that provides scaling and filtering. All 8 external inputs are scaled and filtered to provide the user with an input impedance of 1 M and a variety of single-ended unipolar, single-ended bipolar, and differential bipolar ranges as shown in Table 9. Figure 17 shows a pair of A/D converter input circuits. The resistors form an approx. 10:1 attenuator, and the capacitors filter noise pulses from the A/D converter inputs. Ref. Voltage from D/A Converter ADC 1 MW AIN0 1 nF 105 kW 105 kW AIN1 1 nF AGND Figure 17. Buffered A/D Converter Inputs The A/D converter chip can only accept positive voltages. By pairing the analog inputs and setting the reference voltage from the D/A converter [0 V for single-ended unipolar or differential measurements, V = (voltage range) ÷ 9 for single-ended bipolar measurements], single-ended unipolar, single-ended bipolar, differential bipolar, or current (4–20 mA on channels 0–3 only) measurements are possible, and can be configured for each channel or channel pair with the opmode parameter in the anaInConfig software function call. Adjacent A/D converter inputs are paired to make bipolar measurements. The default setup is to measure only voltages for the ranges listed in Table 9. User’s Manual 29 Table 9. A/D Converter Input Voltage Ranges Voltage Range Amplifier Gain Single-Ended Single-Ended Unipolar Bipolar Differential Bipolar mV per Tick 1 0–20 V ±10 V ± 20 V 10 2 0–10 V ±5 V ± 10 V 5 4 0–5 V ±2.5 V ±5V 2.5 5 0–4 V ±2 V ±4V 2.0 8* 0–2.5 V ±1.25 V ± 2.5 V 1.25 10 0–2 V ±1 V ±2V 1.0 16 0–1.25 V ±0.625 V ± 1.25 V 0.625 20 0–1 V ±0.5 V ±1V 0.500 * 4–20 mA operation is available with an amplifier gain of 8 When using channels AIN0–AIN3 for current measurements, remember to set the corresponding jumper(s) on header JP6. The A/D converter inputs are factory-calibrated and the calibration constants are stored in a separate EEPROM. 3.4.1 A/D Converter Calibration To get the best results form the A/D converter, it is necessary to calibrate each mode (single-ended, differential, and current) for each of its gains. It is imperative that you calibrate each of the A/D converter inputs in the same manner as they are to be used in the application. For example, if you will be performing floating differential measurements or differential measurements using a common analog ground, then calibrate the A/D converter in the corresponding manner. The calibration table in software only holds calibration constants based on mode, channel, and gain. Other factors affecting the calibration must be taken into account by calibrating using the same mode and gain setup as in the intended use. Sample programs are provided to illustrate how to read and calibrate the various A/D inputs for the three operating modes. Mode Single-Ended, unipolar Read Calibrate AD_RD_SE_UNIPOLAR.C ADC_CAL_SE_UNIPOLAR.C Single-Ended, bipolar AD_RD_SE_BIPOLAR.C ADC_CAL_SE_BIPOLAR.C Differential, bipolar AD_RD_DIFF.C ADC_CAL_DIFF.C Milli-Amp AD_RD_MA.C ADC_CAL_MA.C These sample programs are found in the ADC subdirectory in SAMPLES\BL2600. See Section 4.2.4 for more information on these sample programs and how to use them. 30 SBC BL2600 3.5 D/A Converter Outputs The four D/A converter outputs are buffered and scaled to provide an output from 0 V to +10 V (12-bit resolution) or ±10 V (11-bit resolution, one bit used for polarity). There are also four 4–20 mA current outputs. Figure 18 shows the D/A converter outputs. 52.3 kW 10 kW DAC 1.667 V ref. AV0 11 kW 133 kW AV1 11 kW AI0 AI1 2.5 V ref. 133 kW Voltage Outputs Current Outputs 11 kW AGND Figure 18. D/A Converter Outputs To stay within the maximum power dissipation of the D/A converter circuit, the maximum D/A converter output current is 10 mA per channel for the voltage outputs. If you are using the current outputs, keep the resistance driven by a current output channel below 400 to stay within the voltage compliance capability of the op-amp output circuit. As Figure 18 shows, both the voltage and the current outputs for a particular channel are driven by the same output on the D/A converter chip. As a result, either the anaOutVolts or the anaOutmAmps function calls will set both the voltage and the current outputs corresponding to a particular channel. For example, if anaOutVolts sets unipolar channel AV0 to be +10 V, AI0 will be 20 mA; if anaOutVolts sets unipolar channel AV0 to be +5 V, AI0 will be 12 mA, the midpoint of the 4–20 mA range. It is possible to connect a load to both the corresponding voltage and current outputs as long as the combined current consumption does not exceed the 20 mA individual limit. Because of the “connection” between the analog voltage outputs and the analog current outputs, the configuration of the analog voltage outputs with the anaOutConfig function call as unipolar outputs with 12-bit resolution or as bipolar outputs with 11-bit resolution User’s Manual 31 also affects the resolution of the 4–20 mA current outputs—you need to configure a voltage output for unipolar operation if you want 12-bit resolution on the associated current output. There are other effects on a current output when the associated voltage output is operating in the bipolar mode. While voltages of 0 to +10 V still correspond to currents of 4 to 20 mA, the current cannot be determined reliably for voltages below 0 V, and will be “negative” at voltages below -2.5 V. Thus the current output effectively becomes a “current sink” instead of a “current source.” The D/A converter outputs are factory-calibrated and the calibration constants are stored in a separate EEPROM. 3.5.1 D/A Converter Calibration To get the best results form the D/A converter, it is necessary to calibrate each mode (unipolar, bipolar, and current) for each of its gains. It is imperative that you calibrate each of the D/A converter outputs in the same manner as they are to be used in the application. The calibration table in software only holds calibration constants based on unipolar, bipolar, and voltage or current operation. Other factors affecting the calibration must be taken into account by calibrating using the same mode and voltage/current setup as in the intended use. Sample programs are provided to illustrate how to calibrate the various D/A outputs for the three operating modes. Mode Calibrate Voltage DAC_CAL_VOLTS.C Current DAC_CAL_MA.C These sample programs are found in the DAC subdirectory in SAMPLES\BL2600. See Section 4.2.5 for more information on these sample programs and how to use them. 32 SBC BL2600 3.6 Analog Reference Voltage Circuit Figure 19 shows the analog voltage reference circuit. 10 kW 15.8 kW 1.667 V 2.500 V 15.8 kW 11 kW 1.024 V ADREF 2.048 V 100 nF 10 kW 10 kW Figure 19. Analog Reference Voltages The A/D converter chip supplies the 2.048 V reference voltage, which is divided in half and then amplified and buffered to provide the 1.667 V and 2.5 V reference voltages used by the digital output circuits. The D/A converter chip provides the reference voltages for the digital inputs to provide single-ended unipolar or differential measurements [0 V], or to provide single-ended bipolar measurements [V = (voltage range) ÷ 9]. Because the D/A converter chip operation is configured by the anaOutConfig function, it is important to run the anaOutConfig function before running anaInConfig if you plan to use the digital outputs to ensure that the reference voltages are established first before the analog inputs are configured. User’s Manual 33 3.7 Serial Programming Cable The programming cable is used to connect the serial programming port of the BL2600 to a PC serial COM port. The programming cable converts the RS-232 voltage levels used by the PC serial port to the CMOS voltage levels used by the Rabbit 3000. When the PROG connector on the programming cable is connected to the programming header on the BL2600’s RabbitCore module, programs can be downloaded and debugged over the serial interface. The DIAG connector of the programming cable may be used on the programming header on the BL2600’s RabbitCore module with the BL2600 operating in the Run Mode. This allows the programming port to be used as a regular serial port. 3.7.1 Changing Between Program Mode and Run Mode The BL2600 is automatically in Program Mode when the PROG connector on the programming cable is attached, and is automatically in Run Mode when no programming cable is attached. When the Rabbit 3000 is reset, the operating mode is determined by the status of the SMODE pins. When the programming cable’s PROG connector is attached, the SMODE pins are pulled high, placing the Rabbit 3000 in the Program Mode. When the programming cable’s PROG connector is not attached, the SMODE pins are pulled low, causing the Rabbit 3000 to operate in the Run Mode. Program Mode 40 RP4 GND +K DCIN +5V JP3, JP4 AND JP4 1 2 RP3 C4 15 16 R5 C5 C6 33 34 RCM2 J10 C31 R75 C86 +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND GND +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND 26 2 25 1 DS3 C35 C36 C37 C34 RXC RXF RXE 485+ TXC TXE 485 C32 GND U18 C30 D4 Q20 DS2 SPD LNK ACT 15 U3 R9 34 U10 C26 C24R57 R56 33 R3 R4 C16 R31 C21 R41 R36 DS1 1 2 16 RP11 RP13 Q11 RP10 RP9 R1 R2 C15 R112 R11 C11 R12 R13 C12 R14 R23 C18 R24 C19 R33 R34R22 R39 R38 R44 R40 R35 J10 C31 SPD LNK ACT RCM2 C30 RP1 39 2 1 J3 RP8 RP7 C7 33 R55 R42 R37 GND J16 J16 GND +K DCIN +5V 1 15 16 1 RP4 GND +K DCIN +5V JP3, JP4 AND JP4 C4 R5 U3 34 34 U10 C26 R56 C24R57 2 RP3 DS1 C5 R9 R3 R4 R1 R2 C15 C6 16 RP11 RP13 Q11 RP10 RP9 RP8 RP7 C7 R112 C16 R31 C21 R41 R36 R55 R42 R37 C19 33 JP2 JP1 AND JP2 R40 R35 15 2 GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND GND +K DCIN +5V J2 J1 40 39 RP1 J3 1 2 JP1 R11 JP1 AND JP2 DIO 0007 PULLS DIO 0815 PULLS C11 GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND SW1 JP3 R12 JP2 J1 J2 RESET DIO 0007 PULLS DIO 0815 PULLS R13 SW1 JP3 GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND To PC COM port +K DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 C12 JP4 JP5 DIN 1619 PULLS R14 DIN 2023 PULLS DIN 2431 PULLS R23 C18 R24 RESET DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND R33 R34R22 +K JP1 DS1U17 R71 R74 C83 R39 DIN 1619 PULLS JP4 R42 J4 R67 R70 R38 DIN 2023 PULLS JP5 C35 GND C33 C29 DCIN DCIN GND C30 R44 DIN 2431 PULLS C23 C79 Y4 J14 2 J15 C18 D3 Q19 1 AGND Power D2 Q18 J13 C25 J12 C22 C4 C17 AI3 C28 U15 20 AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND AV0 AV1 AV2 AV3 AI0 AI1 AI2 R63 R64 R73 C27 D1 Q17 C12 AIN0 AIN1 AIN2 AIN3 JP6 420 mA U16 C72 J17 R27 485+ 485 GND R51 R49 R48 RXE C61 TXE R31 RXF JP5 TXF C37 C36 RXC JP4 TXC C28 C27 GND C68 C64 C67 C33 19 1 R8 L2 R69 BT1 J11 2 R7 L1 C62 C71 R32 C23 U14 R43 C20 JP7 C16 C15 485 C57 C59 R72 TXE TXF R29 R37 R39 R40 JA GND/EGND C75 TXC U8 C74 1 JP6 R47 +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND 2 25 485 TERM. RESISTOR R44 485+ R30 U4 Y3 R58 L1 RP1 C42 C49 RXE U13 R58 R59 R60 R26 R28 R35 Q1 R41 C53 R18 C20 R6 C48 C35 C36 C37 RXC RXF R20 C47 U9 C9 C17 R19 RP6 R25 RP17 U5 RP18 U6 C14 C78 R25 R27 R29 U2 RCM1 RCM3000 ETHERNET CORE MODULE C8 C45 C44 C43 R38 GND 26 D1 RP16 RP5 C3 U1 C5 U4 R28 +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND AGND GND U18 R21 R20 R23 C31 R111 R15 C13 U12 R16 R17 R22 C39 R74 C83 GND C32 U8 JP3 R67 R70 DCIN DCIN GND C34 DS3 U11 J3 C32 C72 J15 D4 Q20 DS2 GND J14 2 AGND DS1U17 R71 R75 C86 C10 R10 AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 R51 R49 R48 J4 R73 D3 Q19 RP14 RP15 RP12 U7 R42 C61 R72 AI3 C75 C74 AV0 AV1 AV2 AV3 AI0 AI1 AI2 U6 C1 R17 R18 R19 R24 R27 R31 U16 C64 C67 C28 Q8 Q14 Q15 Q16 J7 J8 R8 C79 Y4 Q7 R10 R14 C24 C35 JP5 R7 R63 R64 1 C25 J12 C22 AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND Q6 C3 J9 L1 C62 C68 J13 20 19 1 C33 C29 C37 C36 C57 U15 J11 2 C30 JP4 R47 R44 C59 L2 D2 Q18 Q5 Q12 Q13 R84 U1 R8 C19 C23 C28 C27 C49 D1 Q17 J6 RABBITNET 0 Q4 C2 R29 R37 C48 U8 C27 U5 R39 R40 JA C33 R32 C23 U14 Q3 Q10 GND/EGND R69 BT1 L1 RP1 U4 R41 R58 R18 C20 R19 Q2 Q9 C42 Y3 C53 Q1 J5 C18 C20 C45 C44 C43 R38 C47 R35 Q1 C71 R25 R27 R29 R30 R6 R25 RP17 U5 RP18 U6 C17 R26 R28 RP6 RP2 R1 R7 R9 J4 RABBITNET 1 U2 RCM1 RCM3000 ETHERNET CORE MODULE C8 C14 C78 R43 AIN0 AIN1 AIN2 AIN3 JP6 420 mA R28 JP6 C39 AGND U13 D1 JP3 AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 R21 U4 C31 R111 R15 C13 U12 R16 R17 R20 U11 U8 U9 C9 J7 C10 R10 R20 R23 C32 RP16 J9 R22 R24 RP14 RP15 RP12 U7 C24 U6 R17 R18 R19 C19 J6 RABBITNET 0 J8 J3 Programming Cable U5 RP5 C3 U1 C5 C17 C3 C1 R10 R14 C12 Q14 Q15 Q16 Q12 Q13 R84 U1 R8 C9 C8 Q8 C1 Q7 C4 Q6 C9 C8 C2 Q5 C16 C15 Q10 Q9 Q4 C1 Q3 PROG J5 Q2 DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 DIAG RP2 R1 R7 R9 Q1 DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 Colored edge J4 RABBITNET 1 Run Mode R58 R59 R60 485 TERM. RESISTOR JP7 GND TXC TXF RXC TXF RXF TXE RXE J17 485+ 485 GND Power RESET BL2600 when changing mode: Cycle power off/on or press RESET after removing or attaching programming cable. Figure 20. BL2600 Program Mode and Run Mode Setup A program “runs” in either mode, but can only be downloaded and debugged when the BL2600 is in the Program Mode. Refer to the Rabbit 3000 Microprocessor User’s Manual for more information on the programming port and the programming cable. 34 SBC BL2600 3.8 Other Hardware 3.8.1 Clock Doubler The BL2600 takes advantage of the Rabbit 3000 microprocessor’s internal clock doubler. A built-in clock doubler allows half-frequency crystals to be used to reduce radiated emissions. The 44.2 MHz frequency specified for the BL2600 is generated using a 22.12 MHz resonator, and the 29.4 MHz frequency specified for the BL2610 is generated using a 14.7456 MHz crystal. The clock doubler may be disabled if the higher clock speeds are not required. Disabling the Rabbit 3000 microprocessor’s internal clock doubler will reduce power consumption and further reduce radiated emissions. The clock doubler is disabled with a simple configuration macro as shown below. 1. Select the “Defines” tab from the Dynamic C Options > Project Options menu. 2. Add the line CLOCK_DOUBLED=0 to always disable the clock doubler. The clock doubler is enabled by default, and usually no entry is needed. If you need to specify that the clock doubler is always enabled, add the line CLOCK_DOUBLED=1 to always enable the clock doubler. 3. Click OK to save the macro. The clock doubler will now remain off whenever you are in the project file where you defined the macro. 3.8.2 Spectrum Spreader The Rabbit 3000 features a spectrum spreader, which helps to mitigate EMI problems. By default, the spectrum spreader is on automatically, but it may also be turned off or set to a stronger setting. The means for doing so is through a simple configuration macro as shown below. 1. Select the “Defines” tab from the Dynamic C Options > Project Options menu. 2. Normal spreading is the default, and usually no entry is needed. If you need to specify normal spreading, add the line ENABLE_SPREADER=1 For strong spreading, add the line ENABLE_SPREADER=2 To disable the spectrum spreader, add the line ENABLE_SPREADER=0 NOTE: The strong spectrum-spreading setting is not recommended since it may limit the maximum clock speed or the maximum baud rate. It is unlikely that the strong setting will be used in a real application. 3. Click OK to save the macro. The spectrum spreader will now remain off whenever you are in the project file where you defined the macro. NOTE: Refer to the Rabbit 3000 Microprocessor User’s Manual for more information on the spectrum-spreading setting and the maximum clock speed. User’s Manual 35 3.9 Memory 3.9.1 SRAM The BL2600 modules running at clock speeds of 44.2 MHz have 512K of programexecution SRAM. All the BL2600 modules have 256K–512K of data SRAM. 3.9.2 Flash Memory The BL2600 also has 512K of flash memory. NOTE: Rabbit recommends that any customer applications should not be constrained by the sector size of the flash memory since it may be necessary to change the sector size in the future. Writing to arbitrary flash memory addresses at run time is also discouraged. Instead, define a “user block” area to store persistent data. The functions writeUserBlock and readUserBlock are provided for this. A Flash Memory Bank Select jumper configuration option based on 0 surface-mounted resistors exists at location JP4 on the RabbitCore module (BL2600) or at location JP1 on the RabbitCore module (BL2610). These options are reserved for future use. 3.9.3 Serial Flash Socket J9 is provided to allow you to plug in an optional Rabbit SF1000 serial flash via Serial Port D. You may use two 0.375" (9.5 mm) spacers with 4-40 × 3/4 screws and nuts to attach the SF1000 securely. DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 +K GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND DIN 2023 PULLS DIN 1619 PULLS J1 J2 DIN 2431 PULLS DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 RESET DIO 0007 PULLS R55 R42 R37 DCIN DCIN GND GND RP4 GND +K DCIN +5V JP3, JP4 AND JP4 C4 1 15 R5 16 C5 C6 33 34 J10 C31 C86 C34 RCM2 C35 C36 C37 RXC RXF RXE 485+ TXC TXE 485 J14 2 26 2 25 1 GND +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND GND +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND DS2 DS3 C32 GND U18 C30 D4 Q20 1 J16 J15 AGND D3 Q19 J13 C25 J12 C22 AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND D2 Q18 DS1U17 R71 R75 SPD LNK ACT U10 C26 R56 C24R57 R31 C21 R41 R36 20 19 C28 U15 J11 2 RP3 U3 R9 34 33 R3 R4 R1 R2 C15 C16 C19 R44 J4 R74 D1 Q17 1 AI3 C79 Y4 R73 C27 2 AV0 AV1 AV2 AV3 AI0 AI1 AI2 R63 R64 C83 R23 C18 R24 U16 C64 C67 R67 R70 R40 R35 15 16 RP11 RP13 Q11 RP10 RP9 RP8 RP7 C7 R112 R11 C11 R12 R13 C12 C68 C72 R14 R42 R51 R49 R48 R33 R34R22 C35 C61 R47 R8 L2 C33 R32 C23 U14 C33 C29 R27 R31 C49 R7 L1 C62 R72 L1 C30 JP5 R28 C37 C36 C57 R69 BT1 R29 R37 R39 R40 JA GND/EGND C59 C75 R39 C23 JP4 U8 C74 R19 R25 R27 R29 C18 C28 C27 R44 R38 C17 C24 C20 U4 Y3 R58 R18 C20 RP1 C42 C71 R43 AIN0 AIN1 AIN2 AIN3 JP6 420 mA R35 Q1 R41 C53 C17 R30 R6 C48 JP6 C47 C14 C78 R26 R28 RP6 R25 RP17 U5 RP18 U6 C45 C44 C43 R38 AGND U13 U4 C39 AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 R21 U2 RCM1 RCM3000 ETHERNET CORE MODULE R111 R15 C13 U12 R16 R17 R20 U11 R20 R23 C31 C8 U9 C9 J7 C10 R10 R22 D1 RP16 J9 J8 J3 U8 JP3 RP14 RP15 RP12 U7 RP5 C3 U1 C5 R17 R18 R19 C32 U6 C1 R10 R14 C12 C3 1 JP1 AND JP2 Q8 DS1 RP1 JP2 GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND GND +K DCIN +5V 2 DIO 0815 PULLS J3 1 39 2 40 JP1 SW1 JP3 Q7 Q14 Q15 Q16 R24 J6 RABBITNET 0 Q6 C16 C15 C2 Q5 Q12 Q13 C19 U5 Q4 JP4 Q3 Q10 C4 Q2 Q9 C9 C8 Q1 J5 C1 J4 RABBITNET 1 R84 U1 R8 JP5 RP2 R1 R7 R9 R58 R59 R60 485 TERM. RESISTOR JP7 GND TXC TXF RXC TXF RXF TXE RXE J17 485+ 485 GND Figure 21. Installation of Optional SF1000 Serial Flash 36 SBC BL2600 3.9.4 NAND Flash The RCM3365 and the RCM3375 RabbitCore modules used with the additional BL2600 versions described in Section 1.2.2 support a removable memory card to store data and Web pages. The RCM3365 and the RCM3375 both can handle up to a 128 MByte removable memory card, and the RCM3365 also has a 16 MByte onboard NAND flash. NOTE: Rabbit-based systems do not implement the xD-Picture Card™ specification for data storage, and are neither compatible nor compliant with xD-Picture Card™ card readers. The NAND flash and removable memory cards are particularly suitable for mass-storage applications, but are generally unsuitable for direct program execution. The NAND flash differs from parallel NOR flash (the type of flash memory used to store program code on Rabbit-based boards and RabbitCore modules currently in production) in two respects. First, the NAND flash requires error-correcting code (ECC) for reliability. Although NAND flash manufacturers do guarantee that block 0 will be error-free, most manufacturers guarantee that a new NAND flash chip will be shipped with a relatively small percentage of errors, and will not develop more than some maximum number or percentage of errors over its rated lifetime of up to 100,000 writes. Second, the standard NAND flash addressing method multiplexes commands, data, and addresses on the same I/O pins, while requiring that certain control lines must be held stable for the duration of the NAND flash access. The software function calls provided by Rabbit for the NAND flash take care of the data-integrity and reliability attributes. Figure 22 shows how to insert or remove the memory card. While you remove or insert the memory card, take care to avoid touching the electrical contacts on the bottom of the card to prevent electrostatic discharge damage to the card and to keep any moisture and contaminants off the contacts. Do not remove or insert the memory card while it is being accessed. RP1 R45 R11 R13 R12 U5 U2 C1 C4 R5 U1 C5 R6 C6 R59 C14 R9 R2 Y1 R29 C3 C2 R7 U3 C10 R61 C12 C13 R8 R60 C9 R10 J6 C26 C25 C67 J1 C11 C18 C19 C24 C20 C21 C22 C65 C15 JP7JP8JP4JP5 R83 R76 C35 Y2 R24 JP6 C36 C43 C58 R44 C61 R53 R54 R31 L3 R30 C82 R81 C81 C29 C27 R25 R22 R23 C34 R20 R21 R75 R68 C74 C78 R65 C79 R66 C42 DS1 R36 R37 R38 DS2 DS3 U13 R35 USR FM LINK ACT C77 R79 L1 J2 L2 C75 C86 C76 R72 C72 C71 C70 C80 R82 C64 R1 R14 R15 R26 R27 R17 C28 R19 U4 R18 RCM 3360/3370 Figure 22. Insertion/Removal of Memory Card User’s Manual 37 Rabbit recommends that you use header J6 on the RCM3365/RCM3375 only for the memory card since other devices are not supported. Be careful to remove and insert the memory card as shown, and be careful not to insert any foreign objects, which may short out the contacts and lead to the destruction of your memory card. Sample programs in the SAMPLES\BL2600\NANDFlash folder illustrate the use of the NAND flash. These sample programs are described in Section 4.2.7, “Use of NAND Flash.” Pay careful attention to the sample programs to see how to close files and secure any data on the memory card before you remove it. 38 SBC BL2600 4. SOFTWARE Dynamic C is an integrated development system for writing embedded software. It runs on an IBM-compatible PC and is designed for use with single-board computers and other devices based on the Rabbit microprocessor. Chapter 4 provides the libraries, function calls, and sample programs related to the BL2600. 4.1 Running Dynamic C You have a choice of doing your software development in the flash memory or in the static RAM included on the BL2600. The flash memory and SRAM options are selected with the Options > Project Options > Compiler menu. The advantage of working in RAM is to save wear on the flash memory, which is limited to about 100,000 write cycles. The disadvantage is that the code and data might not both fit in RAM. NOTE: On the BL2600, compiling a program to flash will produce a warning message. You will receive an error message if you attempt to compile a program to the batterybacked data SRAM. If you still want to compile to the battery-backed data SRAM, you will have to comment out some code as instructed in the error message. The program should be run from the program execution SRAM after the programming cable is disconnected. Your final code must always be stored in flash memory for reliable operation. Select Code and BIOS in Flash, Run in RAM from the Dynamic C Options > Project Options > Compiler menu to store the code in flash and copy it to the fast program execution SRAM at run-time to take advantage of the faster clock speed. This option optimizes the performance of the BL2600 with an RCM3200 RabbitCore module running at 44.2 MHz. NOTE: On the BL2610, an application can be developed in RAM, but cannot run standalone from RAM after the programming cable is disconnected. Standalone applications can only run from flash memory. NOTE: Do not depend on the flash memory sector size or type. Due to the volatility of the flash memory market, the BL2600 and Dynamic C were designed to accommodate flash devices with various sector sizes. User’s Manual 39 Developing software with Dynamic C is simple. Users can write, compile, and test C and assembly code without leaving the Dynamic C development environment. Debugging occurs while the application runs on the target. Alternatively, users can compile a program to an image file for later loading. Dynamic C runs on PCs under Windows 95, 98, 2000, NT, Me, and XP. Programs can be downloaded at baud rates of up to 460,800 bps after the program compiles. Dynamic C has a number of standard features: • Full-feature source and/or assembly-level debugger, no in-circuit emulator required. • Royalty-free TCP/IP stack with source code and most common protocols. • Hundreds of functions in source-code libraries and sample programs: Exceptionally fast support for floating-point arithmetic and transcendental functions. RS-232 and RS-485 serial communication. Analog and digital I/O drivers. I2C, SPI, GPS, file system. LCD display and keypad drivers. • Powerful language extensions for cooperative or preemptive multitasking • Loader utility program to load binary images into Rabbit targets in the absence of Dynamic C. • Provision for customers to create their own source code libraries and augment on-line help by creating “function description” block comments using a special format for library functions. • Standard debugging features: Breakpoints—Set breakpoints that can disable interrupts. Single-stepping—Step into or over functions at a source or machine code level, µC/OS-II aware. Code disassembly—The disassembly window displays addresses, opcodes, mnemonics, and machine cycle times. Switch between debugging at machine-code level and source-code level by simply opening or closing the disassembly window. Watch expressions—Watch expressions are compiled when defined, so complex expressions including function calls may be placed into watch expressions. Watch expressions can be updated with or without stopping program execution. Register window—All processor registers and flags are displayed. The contents of general registers may be modified in the window by the user. Stack window—shows the contents of the top of the stack. Hex memory dump—displays the contents of memory at any address. STDIO window—printf outputs to this window and keyboard input on the host PC can be detected for debugging purposes. printf output may also be sent to a serial port or file. 40 SBC BL2600 4.1.1 Upgrading Dynamic C 4.1.1.1 Patches and Updates Dynamic C patches that focus on bug fixes and updates are available from time to time. Check the Web site at www.rabbit.com/support/ for the latest patches, workarounds, and updates. The default installation of a patch or update is to install the file in a directory (folder) different from that of the original Dynamic C installation. Rabbit recommends using a different directory so that you can verify the operation of the patch or update without overwriting the existing Dynamic C installation. If you have made any changes to the BIOS or to libraries, or if you have programs in the old directory (folder), make these same changes to the BIOS or libraries in the new directory containing the patch. Do not simply copy over an entire file since you may overwrite an update; of course, you may copy over any programs you have written. Once you are sure the new patch or update works entirely to your satisfaction, you may retire the existing installation, but keep it available to handle legacy applications. 4.1.1.2 Upgrades Dynamic C installations are designed for use with the board they are included with, and are included at no charge as part of our low-cost kits. Dynamic C is a complete software development system, but does not include all the Dynamic C features. Rabbit also offers for sale add-on Dynamic C modules containing the popular µC/OS-II real-time operating system, as well as PPP, Advanced Encryption Standard (AES), RabbitWeb, FAT File System, Secure Socket Layer (SSL) and other select libraries. In addition to the Webbased technical support included at no extra charge, a one-year telephone-based technical support module is also available for purchase. User’s Manual 41 4.2 Sample Programs Sample programs are provided in the Dynamic C Samples folder. The sample program PONG.C demonstrates the output to the STDIO window. The various directories in the Samples folder contain specific sample programs that illustrate the use of the corresponding Dynamic C libraries. The BL2600 folder provides sample programs specific to the BL2600. Each sample program has comments that describe the purpose and function of the program. Follow the instructions at the beginning of the sample program. To run a sample program, open it with the File menu (if it is not still open), then compile and run it by pressing F9. The BL2600 must be in Program mode (see Section 3.7, “Serial Programming Cable,”) and must be connected to a PC using the programming cable as described in Section 2.2, “BL2600 Connections.” More complete information on Dynamic C is provided in the Dynamic C User’s Manual. TCP/IP specific functions are described in the Dynamic C TCP/IP User’s Manual. Information on using the TCP/IP features and sample programs is provided in Section 5, “Using the TCP/IP Features.” 4.2.1 General BL2600 Sample Programs The following sample programs are found in the SAMPLES\BL2600 folder. • BOARD_ID.C—This program is used to identify the model of BL2600 being used, and displays that information in the STDIO window. 4.2.2 Digital I/O The following sample programs are found in the IO subdirectory in SAMPLES\BL2600. • DIGIN.C—Demonstrates the use of the digital inputs. Using the Demonstration Board, you can see an input channel toggle from HIGH to LOW when pressing a pushbutton on the Demonstration Board. See Appendix C for hookup instructions for the Demonstration Board. This sample program does not explicitly configure any of the configurable I/O, so all the configurable I/O are available by default as digital inputs. • DIGIN_BANK.C—Demonstrates the use of digInBank to read digital inputs. Using the Demonstration Board, you can see an input channel toggle from HIGH to LOW when pressing a pushbutton on the Demonstration Board. See Appendix C for hookup instructions for the Demonstration Board. This sample program does not explicitly configure any of the configurable I/O, so all the configurable I/O are available by default as digital inputs. • DIGOUT.C—Demonstrates the use of the configurable I/O sinking outputs. Using the Demonstration Board, you can see an LED toggle on/off via a sinking output. See Appendix C for hookup instructions for the Demonstration Board. • DIGOUT_BANK.C—Demonstrates the use of digInBank to control the configurable I/O sinking outputs. Using the Demonstration Board, you can see an LED toggle on/off via a sinking output. See Appendix C for hookup instructions for the Demonstration Board. 42 SBC BL2600 • HIGH_CURRENT_IO.C—Demonstrates the use of the high-current outputs configured as either sinking or sourcing outputs. High-current output HOUT0 is configured for sourcing to provide power to the Demonstration Board. Outputs HOUT1 and HOUT2 are configured to demonstrate tristate operation to toggle the LEDs on the Demonstration Board. Output HOUT3 is configured as a sinking output to toggle an LED on the Demonstration Board. See Appendix C for hookup instructions for the Demonstration Board. • PWM.C—Demonstrates the use of the four PWM channels on Parallel Port F (PF4–PF7) on pins DIN20–DIN23. The PWM signals are set for a frequency of 10 kHz with the duty cycle adjustable from 1 to 99% by the user. Follow these instructions when running this sample program. 1. Connect the jumper across pins 7–8 on header JP4 to select the GND option. 2. Once you have compiled and run this program, you may change duty cycle for a given PWM channel via the Dynamic C STDIO window and use either an oscilloscope or a voltmeter to view the output. When monitoring with a voltmeter, you can compute the expected voltage Vout = PWM percentage × 1.65 V since the output voltage swing is from 0 V to 1.65 V DC. 4.2.3 Serial Communication The following sample programs are found in the RS232 subdirectory in SAMPLES\BL2600. • PARITY.C—This sample program repeatedly sends byte values 0–127 from Serial Port F to Serial Port C. The program switches between generating parity and not generating parity on Serial Port F. Serial Port C will always be checking parity, so parity errors should occur during every other sequence. The results are displayed in the Dynamic C STDIO window. Connect TxF to RxC before compiling and running this sample program. NOTE: For the sequence that does yield parity errors, the errors won't occur for each byte received. This is because certain byte patterns along with the stop bit will appear to generate the correct parity for the UART. • SIMPLE3WIRE.C—This program demonstrates basic RS-232 serial communication. Connect TxC to RxF on header J17 and connect TxF to RxC on header J17 before compiling and running this sample program. • SIMPLE5WIRE.C—This program demonstrates 5-wire RS-232 serial communication. Connect TxC to RxC on header J17 and connect TxF to RxF on header J17 before compiling and running this sample program. TxF and RxF become the flow control RTS and CTS. To test flow control, disconnect RTS from CTS while running this program. Characters should stop printing in the Dynamic C STDIO window and should resume when RTS and CTS are connected again User’s Manual 43 The following sample programs are found in the RS485 subdirectory in SAMPLES\BL2600. • MASTER.C—This program demonstrates a simple RS-485 transmission of lower case letters to a slave. The slave will send back converted upper case letters back to the master BL2600 and display them in the STDIO window. Use SLAVE.C to program the slave. Make the following connections between the master and slave: 485+ to 485+ 485- to 485GND to GND • SLAVE.C—This program demonstrates a simple RS-485 transmission of lower case letters to a slave. The slave will send back converted upper case letters back to the master BL2600 and display them in the STDIO window. Use MASTER.C to program the master BL2600. 4.2.4 A/D Converter Inputs The following sample programs are found in the ADC subdirectory in SAMPLES\BL2600. NOTE: The calibration sample programs will overwrite the calibration constants set at the factory. • ADC_CAL_DIFF.C—Demonstrates how to recalibrate a differential A/D converter channel using two known voltages to generate two coefficients, gain and offset, which are rewritten into the reserved EEPROM. The voltage that is being monitored is displayed continuously. • ADC_CAL_MA.C—Demonstrates how to recalibrate a milli-amp A/D converter channel using two known currents to generate two coefficients, gain and offset, which are rewritten into the reserved EEPROM. The current that is being monitored is displayed continuously. • ADC_CAL_SE_BIPOLAR.C—Demonstrates how to recalibrate a single-ended bipolar A/D converter channel using two known voltages to generate two coefficients, gain and offset, which are rewritten into the reserved EEPROM. The voltage that is being monitored is displayed continuously. • ADC_CAL_SE_UNIPOLAR.C—Demonstrates how to recalibrate a single-ended unipolar A/D converter channel using two known voltages to generate two coefficients, gain and offset, which are rewritten into the reserved EEPROM. The voltage that is being monitored is displayed continuously. • ADC_RD_CALDATA.C—Demonstrates how to display the two calibration coefficients, gain and offset, in the Dynamic C STDIO window for each channel and mode of operation. • AD_RD_DIFF.C—Demonstrates how to read and display voltage and equivalent values for a differential A/D converter channel using calibration coefficients previously stored in the EEPROM. The user selects to display either the raw data or the voltage equivalent. • AD_RD_MA.C—Demonstrates how to read and display voltage and equivalent values for a milli-amp A/D converter channel using calibration coefficients previously stored in the EEPROM. The user selects to display either the raw data or the current equivalent. 44 SBC BL2600 • AD_RD_SE_BIPOLAR.C—Demonstrates how to read and display the voltage of all single-ended A/D converter channels using calibration coefficients previously stored in the EEPROM. • AD_RD_SE_UNIPOLAR.C—Demonstrates how to read and display the voltage of all single-ended A/D converter channels using calibration coefficients previously stored in the EEPROM. 4.2.5 D/A Converter Outputs The following sample programs are found in the SAMPLES\BL2600\DAC subdirectory. NOTE: The calibration sample programs will overwrite the calibration constants set at the factory. • DAC_CAL_MA.C—Demonstrates how to recalibrate a D/A converter channel using a known current to generate calibration constants, which are written into the reserved EEPROM. • DAC_CAL_VOLTS.C—Demonstrates how to recalibrate a D/A converter channel using a known voltage to generate calibration constants, which are written into the reserved EEPROM. • DAC_MA_ASYNC.C—Demonstrates how to output a current that can be read with an ammeter. The output current is computed with using the calibration constants that are stored in the reserved EEPROM. The D/A converter circuit is set up for asynchronous operation, which updates the D/A converter output at the time it's being written via the anaOut or anaOutmAmps function calls. • DAC_MA_SYNC.C—Demonstrates how to output a current that can be read with an ammeter. The output current is computed with using the calibration constants that are stored in the reserved EEPROM. The D/A converter circuit is set up for synchronous operation, which updates the D/A converter output when the anaOutStrobe function call executes. The outputs will be updated with values previously written via the anaOut or anaOutmAmps function calls. • DAC_RD_CALDATA.C—Demonstrates how to display the calibration coefficients, gain and offset, in the Dynamic C STDIO window for each channel and mode of operation. • DAC_VOLT_ASYNC.C—Demonstrates how to output a voltage that can be read with a voltmeter. The output voltage is computed with using the calibration constants that are stored in the reserved EEPROM. The D/A converter circuit is set up for asynchronous operation, which updates the D/A converter output at the time it's being written via the anaOut or anaOutVolts function calls. User’s Manual 45 • DAC_VOLT_SYNC.C—Demonstrates how to output a voltage that can be read with a voltmeter. The output voltage is computed with using the calibration constants that are stored in the reserved EEPROM. The D/A converter circuit is set up for synchronous operation, which updates the D/A converter output when the anaOutStrobe function call executes. The outputs will be updated with values previously written via the anaOut or anaOutVolts function calls. 4.2.6 Use of BL2600 with SF1000 Serial Flash Card The following sample programs found in the SAMPLES\BL2600\SF1000 folder demonstrate the use of the optional SF1000 serial flash card on the BL2600. The SF1000 User’s Manual contains additional information and function calls for the SF1000. • FLASH_PATTERN_INSPECT.C—Writes a pattern to the first 100 sectors of the SF1000, which can then be inspected or cleared by the user. The user then has the option to either inspect or clear a page of serial flash memory. • SFLASH_TEST.C—Demonstrates how to read and write data from/to the SF1000. Once the sample program is compiled and run, it displays a message in the Dynamic C STDIO window to report whether the test was successful. 4.2.7 Use of NAND Flash The following sample programs can be found in the SAMPLES\BL2600\NANDFlash folder. • NFLASH_DUMP.C—This program is a utility for dumping the nonerased contents of a NAND flash chip to the Dynamic C STDIO window, and the contents may be redirected to a serial port. When the sample program starts running, it attempts to initialize the user-selected NAND flash chip. If the initialization is successful and the main page size is acceptable, the nonerased page contents (non 0xFF) from the NAND flash page are dumped to the Dynamic C STDIO win.for inspection. Note that an error message will appear when the first 32 pages (0x20 pages) are “dumped.” You may ignore the error message. • NFLASH_INSPECT.C—This program is a utility for inspecting the contents of a NAND flash chip. When the sample program starts running, it attempts to initialize the NAND flash chip selected by the user. Once a NAND flash chip is found, the user can execute various commands to print out the contents of a specified page, clear (set to zero) all the bytes in a specified page, erase, or write to specified pages. CAUTION: When you run this sample program, enabling the #define NFLASH_CANERASEBADBLOCKS macro makes it possible to write to bad blocks. The first two blocks on the memory card are marked bad to protect the configuration data needed to use the card in a digital camera or PC. You will only be able to use the memory card in Rabbit-based systems if either of the first two blocks is written to. • NFLASH_LOG.C—This program runs a simple Web server and stores a log of hits in the NAND flash. This log can be viewed and cleared from a browser. 46 SBC BL2600 • NFLASH_ERASE.C—This program is a utility to erase all the good blocks on a NAND flash chip. When the program starts running, it attempts to initialize the NAND flash chip selected by the user. If the initialization is successful, the progress in erasing the blocks is displayed in the Dynamic C STDIO window. 4.2.8 Real-Time Clock If you plan to use the real-time clock functionality in your application, you will need to set the real-time clock. You may set the real-time clock using the SETRTCKB.C sample program from the Dynamic C SAMPLES\RTCLOCK folder. The RTC_TEST.C sample program in the Dynamic C SAMPLES\RTCLOCK folder provides additional examples of how to read and set the real-time clock 4.2.9 TCP/IP Sample Programs TCP/IP sample programs are described in Chapter 5. 4.3 BL2600 Libraries Two library directories provide libraries of function calls that are used to develop applications for the BL2600. • BL2600—libraries associated with features specific to the BL2600. The functions in the BL26xx.LIB library are described in Section 4.4, “BL2600 Function Calls.” • RN_CFG_BL26.LIB—used to configure the BL2600 for use with RabbitNet peripheral boards. • TCPIP—libraries specific to using TCP/IP functions on the BL2600. Further information about TCP/IP is provided in Chapter 5, “Using the TCP/IP Features.” User’s Manual 47 4.4 BL2600 Function Calls 4.4.1 Board Initialization void brdInit (void); Call this function at the beginning of your program. This function initializes the system I/O ports and loads all the A/D converter and D/A converter calibration constants from flash memory into SRAM for use by your program. The ports are initialized according to Table A-3 in Appendix A. SEE ALSO digOut, digIn, serMode, anaOut, anaIn, anaInDriver, anaOutDriver 48 SBC BL2600 4.4.2 Digital I/O void digHoutConfig(char configuration); Configures a high-current output to be either a sinking or a sourcing output. This configuration information is also used to initially set the output to the off state for the given hardware output configuration. The configuration options are described below. NOTE: Configuring a given output channel for tristate operation using the digHTriStateConfig function will override the configuration set by the digHoutConfig function. NOTE: The brdInit function must be executed before calling digHoutConfig. NOTE: You must execute the digHoutConfig function to set the high-current drivers to be either sinking or sourcing. A runtime error will occur in digHout if digHoutConfig has not executed. NOTE: The extra digital outputs resulting from the configuration of DIO00–DIO15 as digital outputs are sinking outputs only and cannot be configured with digHoutConfig. PARAMETER configuration is a 1-byte parameter where 4 bits are used for the high-current outputs HOUT0– HOUT3. Bit 3 = high-current output channel HOUT3 Bit 2 = high-current output channel HOUT2 Bit 1 = high-current output channel HOUT1 Bit 0 = high-current output channel HOUT0 (bits 4–7 are not used) The high-current outputs can be configured to be sinking or sourcing outputs by setting the corresponding bit to an 0 or 1: 0 = sinking, 1 = sourcing. RETURN VALUE None. SEE ALSO brdInit, digHout, digHTriStateConfig, digHoutTriState EXAMPLE configuration = 0x0C 0x06 = 00001100 (bits 7–0) HOUT3 is sourcing HOUT2 is sourcing HOUT1 is sinking HOUT0 is sinking User’s Manual 49 void digHout(int channel, int state); Sets the state of a high-current digital output (HOUT0–HOUT3) to a logic 0, logic 1, or high impedance. Remember to call the brdInit and the digHoutConfig functions before executing this function. A runtime error will occur for the following conditions: 1. channel or state out of range. 2. brdInit or digHoutConfig was not executed before executing digHout. 3. If you try to use a channel that is configured as a tristate output by digHTriStateConfig. PARAMETERS channel is the output channel number (0–3). state sets a given channel to one of the following output states depending on how the output was configured by digHoutConfig. Sinking configuration: 0 = connect the load to GND 1 = put the output in a high-impedance state Sourcing configuration: 0 = put the output in a high-impedance state 1 = connects the load to +K(0–3) RETURN VALUE None. SEE ALSO brdInit, digHoutConfig, digHoutTriState, digOut 50 SBC BL2600 void digHTriStateConfig(char configuration); Configures whether a high-current output is a tristate type output. This configuration information is also used to initially set the output to the off state for the given hardware output configuration. The configuration options are described below. PARAMETER configuration is a 1-byte parameter where 4 bits are used for the high-current outputs HOUT0– HOUT3. Bit 3 = high-current output channel HOUT3 Bit 2 = high-current output channel HOUT2 Bit 1 = high-current output channel HOUT1 Bit 0 = high-current output channel HOUT0 (bits 4–7 are not used) The high-current outputs can be configured as tristate outputs by setting the corresponding bit to a 0 or 1: 0 = disable operation as tristate output, 1 = enable operation as tristate output. RETURN VALUE None. SEE ALSO brdInit, digHout, dgigHoutConfig, digHoutTriState EXAMPLE configuration = 0x09 0x09 = 00001001 (remember these bits are bits 7–0) HOUT3tristate output is enabled HOUT2 tristate output is disabled HOUT1 tristate output is disabled HOUT0 tristate output is enabled User’s Manual 51 void digHoutTriState(int channel, int state); Sets the state of a high-current digital output (HOUT0–HOUT3) to a logic 0, logic 1, or high impedance. Remember to call the brdInit and the digHTriStateConfig functions before executing this function. A runtime error will occur for the following conditions: 1. channel or state out of range. 2. brdInit or digHTritateConfig was not executed before executing digHoutTriState. 3. If you try to use a channel that is not configured as a tristate output by digHTriStateConfig. PARAMETERS channel is the output channel number (0–3). state sets a given channel to one of the following output states depending on how the output was configured by digHTriStateConfig. Trisate configuration: 0 = connect the load to GND 1 = connects the load to +K(0–3) 2 = put the output in a high-impedance state RETURN VALUE None. SEE ALSO brdInit, digHout, digHoutConfig, digHTriStateConfig 52 SBC BL2600 void digOutConfig(int configuration); Configures any of the 16 configurable I/O channels to be a sinking output. This configuration information is then used by the digOut function to determine whether a given channel is configured to be an output. If it is not, digOut will prevent the given channel from being used by the digOut function. The configuration options are described below. PARAMETER configuration is a 16-bit parameter for which each bit corresponds to a configurable I/O channel (0– 15). An output channel is enabled by setting the corresponding bit number to a logic one. Bit 15 = output channel DIO15 Bit 14 = output channel DIO14 Bit 13 = output channel DIO13 Bit 12 = output channel DIO12 Bit 11 = output channel DIO11 Bit 10 = output channel DIO10 Bit 9 = output channel DIO09 Bit 8 = output channel DIO08 Bit 7 = output channel DIO07 Bit 6 = output channel DIO06 Bit 5 = output channel DIO05 Bit 4 = output channel DIO04 Bit 3 = output channel DIO03 Bit 2 = output channel DIO02 Bit 1 = output channel DIO01 Bit 0 = output channel DIO00 The configurable I/O are configured to be sinking by setting the corresponding bit to 1; setting the bit to 0 disables that channel for output operation. RETURN VALUE None. SEE ALSO brdInit, digHout, dgigHoutConfig, digHoutTriState EXAMPLE configuration = 0x8005 0x8005 = 1000000000000101 (bits 15–0) DIO15, DIO02, and DIO00 have been enabled for use as sinking outputs. The remaining configurable I/O are locked out from being used by the digOut function. User’s Manual 53 void digOut(int channel, int state); Sets the state of a configurable I/O channel (DIO00–DIO15) configured as a sinking digital output to a logic 0 or a logic 1. This function only allows control of channels that are configured to be an output by the digOutConfig function. Remember to call the brdInit and the digOutConfig functions before executing this function. A runtime error will occur for the following conditions: 1. channel or state out of range. 2. brdInit or digOutConfig was not executed before executing digOut. 3. If you try to use a channel that is not configured as a digital output by digOutConfig. PARAMETERS channel is the output channel number (0–15). state sets a given channel to one of the following output states. 0 = connect the load to GND 1 = put the output in a high-impedance state RETURN VALUE None. SEE ALSO brdInit, digHout, digOutConfig, digBankOut, digIn 54 SBC BL2600 void digOutBank(char bank, char data); Sets the state of a bank of configurable I/O channels (DIO00–DIO15) configured as sinking digital outputs to a logic 0 or a logic 1. This function only allows control of channels that are configured to be an output by the digOutConfig function. Remember to call the brdInit and the digOutConfig functions before executing this function. A runtime error will occur for the following conditions: 1. bank is out of range. 2. brdInit or digOutConfig was not executed before executing digOutBank. PARAMETERS bank is 0 or 1. 0 = DIO00–DIO07 1 = DIO08–DIO15 data is a value to be written to the specified digital output bank. The data format and bitwise value are as follows. Data Format Data D7 D6 D5 D4 D3 D2 D1 D0 Bank 0 DIO07 DIO06 DIO05 DIO04 DIO03 DIO02 DIO01 DIO00 Bank 1 DIO15 DIO14 DIO13 DIO12 DIO11 DIO10 DIO09 DIO08 0 = connect the load to GND 1 = put the output in a high-impedance state RETURN VALUE None. SEE ALSO brdInit, digHout, digOutConfig, digBankOut, digIn User’s Manual 55 int digIn(int channel); Reads the state of a digital input channel. If a configurable I/O channel (DIO00–DIO15) that was configured as a digital output is read by digIn, then the value read will be the state of the output channel. A run-time error will occur for the following conditions: 1. channel out of range. 2. brdInit was not executed before executing digIn. PARAMETER channel is the input channel number (0–15 for DIO00–DIO15, 16–31 for IN16–IN31). RETURN VALUE The logic state of the specified channel (0 = low or 1 = high). SEE ALSO brdInit, digOut, digOutConfig, digInBank char digInBank(int bank); Reads the state of a bank of 8 digital input channels. If a configurable I/O channel (DIO00–DIO15) that was configured as a digital output is read by digInBank, then the value returned will be the state of the output channel. A run-time error will occur for the following conditions: 1. bank out of range. 2. brdInit was not executed before executing digInBank. PARAMETER bank is the bank of digital input channels to read. 0 = DIO00–DIO07 (bank 0) 1 = DIO08–DIO15 (bank 1) 2 = IN16–IN23 (bank 2) 3 = IN24–IN31 (bank 3) RETURN VALUE The logic state of each channel in the specified bank (0 = low or 1 = high). The data is returned as a byte, with each bit representing the state of a particular channel in the bank ordered from the most significant bit to the least significant bit. SEE ALSO brdInit, digOut, digOutConfig, digInBank 56 SBC BL2600 4.4.3 Serial Communication Library files included with Dynamic C provide a full range of serial communications support. The RS232.LIB library provides a set of circular-buffer-based serial functions. The PACKET.LIB library provides packet-based serial functions where packets can be delimited by the 9th bit, by transmission gaps, or with user-defined special characters. Both libraries provide blocking functions, which do not return until they are finished transmitting or receiving, and nonblocking functions, which must be called repeatedly until they are finished. For more information, see the Dynamic C User’s Manual and Technical Note 213, Rabbit Serial Port Software. Use the following function calls with the BL2600. int serMode(int mode); User interface to set up BL2600 serial communication lines. Call this function after serXOpen(). Whether you are opening one or multiple serial ports, this function must be executed after executing the last serXOpen function AND before you start using any of the serial ports. This function is non-reentrant. If Mode 1 is selected, CTS/RTS flow control is exercised using the serCflowcontrolOn and serCflowcontrolOff functions from the RS232.LIB library. PARAMETER mode is the defined serial port configuration. Serial Port Mode C F E 0 RS-232, 3-wire RS-232, 3-wire RS-232, 3-wire 1 RS-232, 3-wire RS-232, 3-wire RS-485 2 RS-232, 5-wire RTS/CTS RS-232, 3-wire 3 RS-232, 5-wire RTS/CTS RS-485 RETURN VALUE 0 if valid mode selected, 1 if not. SEE ALSO brdInit, ser485Tx, ser485Rx User’s Manual 57 void ser485Tx(void); Enables the RS-485 transmitter. serMode must be executed before running this function. NOTE: Transmitted data are echoed back into the receive data buffer. The echoed data could be used to identify when to disable the transmitter by using one of the following methods. Byte mode—disables the transmitter after the byte that is transmitted is detected in the receive data buffer. Block data mode—disable the transmitter after the same number of bytes transmitted are detected in the receive data buffer. RETURN VALUE None. SEE ALSO brdInit, serMode, ser485Rx void ser485Rx(void); Disables the RS-485 transmitter. This puts you in listen mode, which allows you to receive data from the RS-485 interface. serMode must be executed before running this function. RETURN VALUE None. SEE ALSO brdInit, serMode, ser485Tx 58 SBC BL2600 4.4.4 A/D Converter Inputs void anaInConfig(int ch_pair, int opmode); Configures an A/D converter input channel pair for a given mode of operation. This function must be called before accessing the A/D converter chip. NOTE: If you plan to configure the D/A converter chip using anaOutConfig, you must call anaOutConfig before executing anaInConfig. This is because the A/D converter uses internal channels 4–7 on the D/A converter chip to bias the A/D converter input circuit. PARAMETERS ch_pair are the channel pairs: 0 = channels 0 and 1 1 = channels 2 and 3 2 = channels 4 and 5 3 = channels 6 and 7 opmode selects the mode of operation for the channel pair on A/D converter: 0 = Single-Ended unipolar (0–10 V) 1 = Single-Ended bipolar (±10 V) 2 = Differential bipolar (±20 V) 3 = 4–20 mA RETURN VALUE None. SEE ALSO brdInit, anaInCalib, anaInDriver, anaIn, anaInVolts, anaInmAmps, anaInDiff User’s Manual 59 int anaInCalib(int channel, int opmode, int gaincode, int value1, float volts1, int value2, float volts2); Calibrates the response of a given A/D converter channel as a linear function using the two conversion points provided. Gain and offset constants are calculated and placed into global table _adcInCalib. PARAMETERS channel is the analog input channel number (0 to 7) corresponding to AIN0–AIN7 channel Single-Ended Differential 4–20 mA 0 +AIN0 +AIN0 -AIN1 +AIN0 1 +AIN1 — +AIN1 2 +AIN2 +AIN2 -AIN3 +AIN2 3 +AIN3 — +AIN3 4 +AIN4 +AIN4 -AIN5 5 +AIN5 — 6 +AIN6 +AIN6 -AIN7 7 +AIN7 — opmode is the mode of operation for the specified channel. Use one of the following macros to set the mode for the channel being configured. 0 = Single-Ended unipolar (0–20 V) 1 = Single-Ended bipolar (±10 V) 2 = Differential bipolar (±20 V) 3 = 4–20 mA gaincode is the gain code of 0 to 7 (use a gain code of 4 for 4–20 mA operation) Voltage Range Gain Code Macro 0 GAIN_X1 0–20 V ±10 V ± 20 V 1 GAIN_X2 0–10 V ±5 V ± 10 V 2 GAIN_X4 0–5 V ±2.5 V ±5V 3 GAIN_X5 0–4 V ±2 V ±4V 4 GAIN_X8 0–2.5 V ±1.25 V ± 2.5 V 5 GAIN_X10 0–2 V ±1 V ±2V 6 GAIN_X16 0–1.25 V — ± 1.25 V 7 GAIN_X20 0–1 V — ±1V Single-Ended Single-Ended Unipolar Bipolar Differential Bipolar value1 is the first A/D converter value (0–4095). volts1 is the voltage corresponding to the first A/D converter value. value2 is the second A/D converter value (0–4095). volts2 is the voltage corresponding to the second A/D converter value. 60 SBC BL2600 NOTE: The 10 and 90% points of the maximum voltage range are recommended when calibrating a channel. RETURN VALUE 0 if successful. -1 if not able to make calibration constants. SEE ALSO brdInit, anaInConfig, anaIn, anaInmAmps, anaInDiff, anaInVolts User’s Manual 61 int anaIn(int channel, int gaincode); Reads the state of an A/D converter input channel. If the access is for an A/D converter single-ended bipolar channel and the gain code for the given channel has changed from the previous cycle, the EEPROM will be read to get the calibration constants for the new gain value. PARAMETER channel is the analog input channel number (0 to 7) corresponding to AIN0–AIN7 channel Single-Ended Differential 4–20 mA 0 +AIN0 +AIN0 -AIN1 +AIN0 1 +AIN1 — +AIN1 2 +AIN2 +AIN2 -AIN3 +AIN2 3 +AIN3 — +AIN3 4 +AIN4 +AIN4 -AIN5 5 +AIN5 — 6 +AIN6 +AIN6 -AIN7 7 +AIN7 — gaincode is the gain code of 0 to 7 (use a gain code of 4 for 4–20 mA operation) Voltage Range Gain Code Macro 0 GAIN_X1 0–20 V ±10 V ± 20 V 1 GAIN_X2 0–10 V ±5 V ± 10 V 2 GAIN_X4 0–5 V ±2.5 V ±5V 3 GAIN_X5 0–4 V ±2 V ±4V 4 GAIN_X8 0–2.5 V ±1.25 V ± 2.5 V 5 GAIN_X10 0–2 V ±1 V ±2V 6 GAIN_X16 0–1.25 V — ± 1.25 V 7 GAIN_X20 0–1 V — ±1V Single-Ended Single-Ended Unipolar Bipolar Differential Bipolar RETURN VALUE A value corresponding to the voltage or current on the analog input channel (0–2047 for 11-bit conversions). SEE ALSO brdInit, anaInConfig, anaInCalib, anaInmAmps, anaInDiff, anaInVolts 62 SBC BL2600 float anaInVolts(int channel, int gaincode); Reads the state of a single-ended A/D converter input channel and uses the previously set calibration constants to convert it to volts. If the gain code for a given channel has changed from the previous cycle, the following code accesses will occur. 1. The EEPROM will be read to get the calibration constants for the new gain value. 2. The D/A converter will be written to bias the A/D converter input circuit for proper operation. (The D/A converter access only applies for the single-ended bipolar A/D converter operation.) PARAMETER channel is the A/D converter input channel (0–7). gaincode is the gain code of 0 to 7. RETURN VALUE A voltage value corresponding to the voltage on the analog input channel. A value of -4096 indicates an overflow or out-of-range condition. SEE ALSO brdInit, anaInConfig, anaIn, anaInmAmps, anaInDiff, anaInCalib User’s Manual 63 float anaInDiff(int channel, int gaincode); Reads the state of a differential A/D converter input channel and uses the previously set calibration constants to convert it to volts. If the gain code for a given channel has changed from the previous cycle, the EEPROM will be read to get the calibration constants for the new gain value. PARAMETER channel is the analog input channel number (0, 2, 4, 6) as shown below channel Differential Inputs 0 +AIN0 -AIN1 2 +AIN2 -AIN3 4 +AIN4 -AIN5 6 +AIN6 -AIN7 gaincode is the gain code of 0 to 7 Gain Code Macro Actual Gain Differential Voltage Range 0 GAIN_X1 ×1 ± 20 V 1 GAIN_X2 ×2 ± 10 V 2 GAIN_X4 ×4 ±5V 3 GAIN_X5 ×5 ±4V 4 GAIN_X8 ×8 ± 2.5 V 5 GAIN_X10 ×10 ±2V 6 GAIN_X16 ×16 ± 1.25 V 7 GAIN_X20 ×20 ±1V RETURN VALUE A voltage value corresponding to the voltage on the analog input channel. A value of -4096 indicates an overflow or out-of-range condition. SEE ALSO brdInit, anaInConfig, anaIn, anaInmAmps, anaInVolts, anaInCalib 64 SBC BL2600 float anaInmAmps(int channel); Reads the state of a single-ended A/D converter input channel and uses the previously set calibration constants to convert it to the current value. PARAMETER channel is the A/D converter input channel (0–3 corresponding to AIN0–AIN3). RETURN VALUE A current value corresponding to the current on the analog input channel with a range of 4–20 mA. A value of -4096 indicates an overflow or out-of-range condition. SEE ALSO brdInit, anaInConfig, anaIn, anaInDiff, anaInVolts, anaInCalib User’s Manual 65 4.4.5 D/A Converter Outputs int anaOutConfig(char configuration, int mode); Configures the D/A converter chip for a given output voltage range, 0–10 V or ±10 V, and loads the calibration data for use by the D/A converter API functions. This function must be called before accessing any of the D/A converter channels. NOTE: If you are using the analog outputs, you must configure the D/A converter chip using the anaOutConfig function before executing anaInConfig to configure the A/D converter chip. This is because the A/D converter chip uses internal channels 4–7 on the D/A converter chip to bias the A/D converter input circuit, and the correct configuration of the A/D converter would be affected if the D/A converter configuration was changed later. PARAMETERS configuration sets the output configuration as follows: 0 = unipolar operation. (0–10V and 4–20 mA) 1 = bipolar operation. (±10V and 4–20 mA) NOTE: When the D/A converter is configured for bipolar operation, the 4–20 mA channels change from 12-bit to 11-bit resolution. mode is the mode of operation: 0 = asynchronous—an output is updated at the time data are written to the given channel 1 = synchronous—all outputs are updated with data previously written when the anaOutStrobe function is executed. RETURN VALUE None. SEE ALSO brdInit, anaOut, anaOutmAmps, anaOutStrobe, anaOutConfig, anaOutCalib 66 SBC BL2600 int anaOutCalib(int channel, int calib_index, int value1, float volts1, int value2, float volts2); Calibrates the response of a given D/A converter channel as a linear function with using two conversion points provided by the user. Gain and offset constants are calculated and written to the EEPROM for use by the D/A converter API functions. PARAMETERS channel is the D/A converter output channel (0–3). calib_index is an index used to go to the proper location in the lookup table for writing the calibration data: 0 = 0–10 V calibration data 1 = ±10 V calibration data 2 = 4–20 mA calibration data (unipolar configuration) 3 = 4–20 mA calibration data (bipolar configuration) value1 is the first D/A converter value (0–4095). volts1 is the voltage or current corresponding to the first D/A converter value (0–10 V, ±10 V or 4– 20 mA). value2 is the second D/A converter value (0–4095). volts2 is the voltage or current corresponding to the second D/A converter value (0–10 V, ±10 V or 4– 20 mA). NOTE: The 10 and 90% points of the maximum voltage range are recommended when calibrating a channel. RETURN VALUE 0 if sucessful. -1 if not able to make calibration constants. SEE ALSO brdInit, anaOut, anaOutVolts, anaOutmAmps, anaOutStrobe, anaOutConfig void anaOutStrobe(void); Strobes the D/A converter chip, which will update all the outputs with the previously written values (or default value of zero). This function is only valid if the D/A converter chip has been configured for synchronous operation using the anaOutConfig function. RETURN VALUE None. SEE ALSO brdInit, anaOut, anaOutmAmps, anaOutStrobe, anaOutConfig, anaOutCalib User’s Manual 67 void anaOutPwr(int control); Enables or disables the BL2600 power supply used to drive the D/A converter output voltage or current circuits. NOTE: Call this function only after you have configured all the D/A converter output channels to the desired voltage or current. Unconfigured D/A converter channels, both voltage and 4–20 mA, will be set to approx. 0 V or 4 mA respectively. PARAMETER control sets whether the power supply is on or off: 0 = off 1 = on RETURN VALUE None. SEE ALSO anaOutDisable, anaOut, anaOutVolts, anaOutmAmps void anaOut(int ch, int rawdata); Sets the voltage of a D/A converter output channel. PARAMETERS ch is the D/A converter output channel (0–3). rawdata is a data value corresponding to the voltage desired on the output channel (0–4095). RETURN VALUE 0 if sucessful. -1 if rawcount is more than 4095. SEE ALSO anaOutDriver, anaOutVolts, anaOutCalib void anaOutVolts(int ch, float voltage); Sets the voltage of a D/A converter output channel by using the previously set calibration constants to calculate the correct data values. PARAMETERS ch is the D/A converter output channel (0–3). voltage is the voltage desired on the output channel. RETURN VALUE None. SEE ALSO brdInit, anaOut, anaOutStrobe, anaOutConfig, anaOutCalib 68 SBC BL2600 void anaOutmAmps(int ch, float current); Sets the current of a D/A converter output channel by using the previously set calibration constants to calculate the correct data values. PARAMETERS ch is the D/A converter output channel (0–3). current is the current desired on the output channel (the valid range is 4–20 mA). RETURN VALUE None. SEE ALSO brdInit, anaOut, anaOutVolts, anaOutStrobe, anaOutConfig, anaOutCalib User’s Manual 69 4.4.6 SRAM Use The BL2600 model and some memory variations described in Section 1.2.2 have a batterybacked data SRAM and a program-execution SRAM. Dynamic C provides the protected keyword to identify variables that are to be placed into the battery-backed SRAM. The compiler generates code that maintains two copies of each protected variable in the battery-backed SRAM. The compiler also generates a flag to indicate which copy of the protected variable is valid at the current time. This flag is also stored in the batterybacked SRAM. When a protected variable is updated, the “inactive” copy is modified, and is made “active” only when the update is 100% complete. This assures the integrity of the data in case a reset or a power failure occurs during the update process. At power-on the application program uses the active copy of the variable pointed to by its associated flag. The sample code below shows how a protected variable is defined and how its value can be restored. protected nf_device nandFlash; int main() { ... _sysIsSoftReset(); // restore any protected variables The bbram keyword may also be used instead if there is a need to store a variable in battery-backed SRAM without affecting the performance of the application program. Data integrity is not assured when a reset or power failure occurs during the update process. Additional information on bbram and protected variables is available in the Dynamic C User’s Manual. 4.4.7 NAND Flash Drivers The Dynamic C NANDFlash\NFLASH.LIB library is used to interface to NAND flash memory devices on the RCM3365 and the RCM3375. The function calls were written specifically to work with industry-standard flash devices with a 528-byte page program and 16896-byte block erase size. The NAND flash function calls are designed to be closely cross-compatible with the newer serial flash function calls found in the SFLASH.LIB library. These function calls use an nf_device structure as a handle for a specific NAND flash device. This allows multiple NAND flash devices to be used by an application. More information on these function calls is available in the Dynamic C Function Reference Manual. 70 SBC BL2600 5. USING THE TCP/IP FEATURES Chapter 5 discusses using the TCP/IP features on the BL2600 and BL2610 boards. The TCP/IP feature is not available on BL2610. 5.1 TCP/IP Connections Before proceeding you will need to have the following items. • If you don’t have Ethernet access, you will need at least a 10Base-T Ethernet card (available from your favorite computer supplier) installed in a PC. • Two RJ-45 straight-through CAT 5/6 Ethernet cables and a hub, or an RJ-45 crossover CAT 5/6 Ethernet cable. The CAT 5/6 Ethernet cables and Ethernet hub are available from Rabbit in a TCP/IP tool kit. More information is available at www.rabbit.com. 1. Connect the AC adapter and the programming cable as shown in Chapter 2, “Getting Started.” 2. Ethernet Connections If you do not have access to an Ethernet network, use a crossover CAT 5/6 Ethernet cable to connect the BL2600 to a PC that at least has a 10Base-T Ethernet card. If you have Ethernet access, use a straight-through CAT 5/6 Ethernet cable to establish an Ethernet connection to the BL2600 from an Ethernet hub. These connections are shown in Figure 23. BL2600 Board BL2600 Board CAT 5/6 Ethernet cables User’s PC Crossover CAT 5/6 Ethernet cable Hub Direct Connection (network of 2 computers) To additional network elements Direct Connection Using a Hub Figure 23. Ethernet Connections User’s Manual 71 The PC running Dynamic C through the serial programming port on the BL2600 does not need to be the PC with the Ethernet card. 3. Apply Power Plug in the AC adapter. The BL2600 is now ready to be used. NOTE: A hardware RESET is accomplished by unplugging the AC adapter, then plugging it back in, or by momentarily grounding the board reset input at pin 9 on screw terminal header J2. When working with the BL2600, the green LNK light is on when a program is running and the board is properly connected either to an Ethernet hub or to an active Ethernet card. The orange ACT light flashes each time a packet is received. 72 SBC BL2600 5.2 TCP/IP Sample Programs We have provided a number of sample programs demonstrating various uses of TCP/IP for networking embedded systems. These programs require that you connect your PC and the BL2600 together on the same network. This network can be a local private network (preferred for initial experimentation and debugging), or a connection via the Internet. 5.2.1 How to Set IP Addresses in the Sample Programs With the introduction of Dynamic C 7.30 we have taken steps to make it easier to run many of our sample programs. You will see a TCPCONFIG macro. This macro tells Dynamic C to select your configuration from a list of default configurations. You will have three choices when you encounter a sample program with the TCPCONFIG macro. 1. You can replace the TCPCONFIG macro with individual MY_IP_ADDRESS, MY_NETMASK, MY_GATEWAY, and MY_NAMESERVER macros in each program. 2. You can leave TCPCONFIG at the usual default of 1, which will set the IP configurations to 10.10.6.100, the netmask to 255.255.255.0, and the nameserver and gateway to 10.10.6.1. If you would like to change the default values, for example, to use an IP address of 10.1.1.2 for the BL2600 board, and 10.1.1.1 for your PC, you can edit the values in the section that directly follows the “General Configuration” comment in the TCP_CONFIG.LIB library. You will find this library in the LIB\TCPIP directory. 3. You can create a CUSTOM_CONFIG.LIB library and use a TCPCONFIG value greater than 100. Instructions for doing this are at the beginning of the TCP_CONFIG.LIB library in the LIB\TCPIP directory. There are some other “standard” configurations for TCPCONFIG that let you select different features such as DHCP. Their values are documented at the top of the TCP_CONFIG.LIB library in the LIB\TCPIP directory. More information is available in the Dynamic C TCP/IP User’s Manual. User’s Manual 73 5.2.2 How to Set Up your Computer’s IP Address for a Direct Connection When your computer is connected directly to the BL2600 via an Ethernet connection, you need to assign an IP address to your computer. To assign the PC the address 10.10.6.101 with the subnetmask 255.255.255.0, do the following. Click on Start > Settings > Control Panel to bring up the Control Panel, and then double-click the Network icon. Depending on which version of Windows you are using, look for the TCP/IP Protocol/Network > Dial-Up Connections/Network line or tab. Double-click on this line or select Properties or Local Area Connections > Properties to bring up the TCP/IP properties dialog box. You can edit the IP address and the subnet mask directly. (Disable “obtain an IP address automatically”.) You may want to write down the existing values in case you have to restore them later. It is not necessary to edit the gateway address since the gateway is not used with direct connect. BL2600 Board IP 10.10.6.101 Netmask 255.255.255.0 User’s PC crossover CAT 5/6 Ethernet cable Direct Connection PC to BL2600 74 SBC BL2600 5.2.3 Run the PINGME.C Demo Connect the crossover cable from your computer’s Ethernet port to the BL2600’s RJ-45 Ethernet connector. Open this sample program from the SAMPLES\TCPIP\ICMP folder, compile the program, and start it running under Dynamic C. When the program starts running, the green LNK light on the BL2600 should be on to indicate an Ethernet connection is made. (Note: If the LNK light does not light, you may not have a crossover cable, or if you are using a hub perhaps the power is off on the hub.) The next step is to ping the board from your PC. This can be done by bringing up the MSDOS window and running the ping program: ping 10.10.6.100 or by Start > Run and typing the command ping 10.10.6.100 Notice that the orange ACT light flashes on the BL2600 while the ping is taking place, and indicates the transfer of data. The ping routine will ping the board four times and write a summary message on the screen describing the operation. User’s Manual 75 5.2.4 Running More Demo Programs With a Direct Connection The program SSI.C (SAMPLES\BL2600\TCPIP\) demonstrates how to make the BL2600 a Web server. This program allows you to turn the LEDs on an attached Demonstration Board from the Tool Kit on and off from a remote Web browser. The LEDs on the Demonstration Board match the ones on the Web page. Follow the instructions included with the sample program. As long as you have not modified the TCPCONFIG 1 macro in the sample program, enter the following server address in your Web browser to bring up the Web page served by the sample program. http://10.10.6.100. Otherwise use the TCP/IP settings you entered in the TCP_CONFIG.LIB library. The sample program SMTP.C (SAMPLES\BL2600\TCPIP\) allows you to send an E-mail when a switch on the Demonstration Board is pressed. Follow the instructions included with the sample program. The sample program TELNET.C (SAMPLES\BL2600\TCPIP\) allows you to communicate with the BL2600 using the Telnet protocol. This program takes anything that comes in on a port and sends it out Serial Port C. It uses a digital input to indicate that the TCP/IP connection should be closed and a digital output to toggle a LED to indicate that there is an active connection. Follow the instructions included with the sample program. Run the Telnet program on your PC (Start > Run telnet 10.10.6.100). As long as you have not modified the TCPCONFIG 1 macro in the sample program, the IP address is 10.10.6.100 as shown; otherwise use the TCP/IP settings you entered in the TCP_CONFIG.LIB library. Each character you type will be printed in Dynamic C's STDIO window, indicating that the board is receiving the characters typed via TCP/IP. 5.3 Where Do I Go From Here? NOTE: If you purchased your BL2600 through a distributor or Rabbit partner, contact the distributor or partner first for technical support. If there are any problems at this point: • Use the Dynamic C Help menu to get further assistance with Dynamic C. • Check the Rabbit Technical Bulletin Board and forums at www.rabbit.com/support/bb/ and at www.rabbit.com/forums/. • Use the Technical Support e-mail form at www.rabbit.com/support/questionSubmit.shtml. If the sample programs ran fine, you are now ready to go on. Additional sample programs are described in the Dynamic C TCP/IP User’s Manual. Refer to the Dynamic C TCP/IP User’s Manual to develop your own applications. An Introduction to TCP/IP provides background information on TCP/IP, and is available on the Web site. 76 SBC BL2600 APPENDIX A. SPECIFICATIONS Appendix A provides the specifications for the BL2600 and describes the conformal coating. User’s Manual 77 A.1 Electrical and Mechanical Specifications Figure A-1 shows the mechanical dimensions for the BL2600. (3.2) DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 2 1 15 RP4 GND +K DCIN +5V JP3, JP4 AND JP4 RP3 DS1 C4 (28.6) C5 C6 33 (126) (17.5) J10 0.69 C31 DS1 DS3 USR FM LINK ACT RCM2 4.96 34 33 R9 2 20 1 19 C25 J12 DCIN DCIN GND GND C30 D4 Q20 C34 C35 C36 C37 RXE RXC RXF 2 26 2 1 25 1 GND +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND +HK0 GND HOUT1 +HK2 GND HOUT3 GND HOUT0 +HK1 GND HOUT2 +HK3 GND R58 R59 R60 485 TERM. RESISTOR 485+ J14 J16 J15 AGND D3 Q19 J13 C22 AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND D2 Q18 U18 1.80 D1 Q17 C28 U15 J11 AI3 DS2 C26 C24R57 R31 C21 R56 C27 R55 R42 R37 C19 U17 C32 C33 R32 C23 U14 AV0 AV1 AV2 AV3 AI0 AI1 AI2 1.126 R5 U3 15 16 34 U10 R8 BT1 L1 (7.8) U16 C16 R30 R41 R36 R40 R35 R26 R28 0.31 GND/EGND C15 R112 R11 C11 R12 R13 R39 R38 R25 R27 R43 AIN0 AIN1 AIN2 AIN3 JP6 420 mA JA J2 R44 JP6 C8 U9 C9 R18 C20 R19 R29 RJ-45 jack extends 0.16" (4.0 mm) past edge of board U4 RCM1 RCM3000 ETHERNET CORE MODULE R7 C12 R33 R34R22 U13 R6 C14 C78 R14 AGND R20 RP6 C17 R23 C18 R24 1.89 (48.0) AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 R21 U8 R111 R15 C13 U12 R16 R17 RP13 RP11 R3 R2 R1 RP16 J7 U11 J6 connector height is 0.12" (3.0 mm) U2 RP17 RP18 C7 0.62 (15.7) RP14 RP15 RP12 U7 RP5 J6 R4 Q11 RP10 RP9 RP8 RP7 0.62 (15.7) C3 C1 U1 J1 Q8 Q14 Q15 Q16 Q12 Q13 U6 Q7 (5.0) 16 1 JP1 AND JP2 Q6 J9 C10 R10 0.20 40 2 GND +K DCIN +5V RP1 39 2 1 J3 JP2 0.50 DIO 0815 PULLS GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND C2 Q5 R84 (45.8) DIO 0007 PULLS JP1 SW1 JP3 Q4 JP4 RP2 JP5 (12.7) RESET Q3 Q10 Q9 J8 (15.4) DIN 1619 PULLS J5 Q2 U5 0.605 DIN 2023 PULLS Q1 J6 RABBITNET 0 (5.1) DIN 2431 PULLS J1 J2 GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND (16.1) +K 0.635 DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 J4 RABBITNET 1 0.20 0.125 dia × 4 JP7 TXC GND TXC TXF RXC TXF TXE RXF TXE 485 RXE J17 485+ 485 GND 4.45 (113) 4.85 (123) (16) 0.65 1.00 0.45 (25) (11) 4.85 (123) Figure A-1. BL2600 Dimensions NOTE: All measurements are in inches followed by millimeters enclosed in parentheses. All dimensions have a manufacturing tolerance of ±0.01" (0.25 mm). 78 SBC BL2600 Table A-1 lists the electrical, mechanical, and environmental specifications for the BL2600. Table A-1. BL2600 Specifications Feature Microprocessor Ethernet Port BL2600 BL2610 Rabbit 3000® at 44.2 MHz Rabbit 3000® at 29.4 MHz 10/100Base-T, 3 LEDs None Flash Memory 512K (standard) Program Execution SRAM 512K — Data SRAM 256K 512K Panasonic CR2477 or equivalent 3 V lithium coin type, 950 mA·h standard, socket-mounted Backup Battery 16 individually software-configurable I/O channels may be configured as digital inputs ± 36 V DC, switching threshold 1.5 V typical, or as sinking digital outputs up to 40 V, 200 mA each Configurable I/O 8 inputs hardware-configurable pull-up or pull-down, ± 36 V DC, switching threshold 1.4 V typical Digital Inputs 4 outputs individually software-configurable as sinking or sourcing, +40 V DC, 2 A max. per channel High-Current Digital Outputs Eight 11-bit res. channels, software-selectable ranges unipolar: 1, 2, 2.5, 5, 10, 20 V DC; bipolar ± 1, ±2, ±5, ±10 V DC: 4 channels can be hardware-configured for 4–20 mA; 1 M input impedanceup to 4,100 samples/s Analog Inputs Four 12-bit res. channels, buffered, 0–10 V DC, ±10 VDC, and 4–20 mA, update rate 12 kHz Analog Outputs 5 serial ports: one RS-485 or one RS-232 Serial Ports • • • • two RS-232 or one RS-232 (with CTS/RTS) one clocked serial port multiplexed to two RS-422 SPI master ports one serial port dedicated for programming/debug Serial Rate Max. asynchronous rate = CLK/8, Max. synchronous rate = CLK/2 Connectors RJ-45 connectors: one Ethernet and two RabbitNet™ Friction-lock connectors: two polarized 9-position terminals with 0.1" pitch three 4-position power terminals with 0.156" pitch two 20-position terminals with 0.1" pitch (2 × 20 IDC option) one 13-position terminal with 0.1" pitch (2 × 13 IDC option) one 10-position terminal with 0.1" pitch (2 × 7 IDC option) Programming port: 2 × 5 IDC, 1.27 mm pitch (BL2600), 2 × 5 IDC, 2 mm pitch (BL2610) Real-Time Clock User’s Manual Yes 79 Table A-1. BL2600 Specifications (continued) Feature BL2600 BL2610 Ten 8-bit timers (6 cascadable, 3 reserved for internal peripherals), one 10-bit timer with 2 match registers Timers Watchdog/Supervisor Yes Power 9–36 V DC, 12 W max. –40°C to +70°C (–40°C to +85°C without battery) Operating Temperature Humidity 5–95%, noncondensing Board Size 4.85" × 4.96" × 1.00" (123 mm × 126 mm × 25 mm) Other memory and clock speed options are available—see Section 1.2.2. A.1.1 Exclusion Zone (3) 0.12 (25) 1.00 (6) 0.25 It is recommended that you allow for an “exclusion zone” of 0.25" (6 mm) around the BL2600 in all directions when the BL2600 is incorporated into an assembly that includes other components. This “exclusion zone” that you keep free of other components and boards will allow for sufficient air flow, and will help to minimize any electrical or EMI interference between adjacent boards. An “exclusion zone” of 0.12" (3 mm) is recommended below the BL2600. Figure A-2 shows this “exclusion zone.” 4.85 0.25 (123) (6) 0.25 (6) 0.25 (6) (3) 0.12 (25) 1.00 Exclusion Zone 0.25 (6) 4.96 (126) 0.25 (6) Figure A-2. BL2600 “Exclusion Zone” 80 SBC BL2600 A.1.2 Headers The BL2600 has 0.1" IDC header sockets or friction-lock connectors at J1, J2, J3, J11, J13, J14, J15, J16, and J17 for physical connection to other boards or ribbon cables. There are friction-lock connectors at J5, J7, and J12 for power-supply connections, and at J8. Figure A-3 shows the BL2600 footprint. These reference design values are relative to the mounting hole below the RabbitCore module. 3.835 (97.41) 3.720 (94.49) 2.320 (58.93) 0.220 (5.59) J2 J1 J3 J6 J1 J5 3.650 (92.71) J9 J12 J14 J16 J17 (9.53) 0.375 (9.65) 0.380 0.415 (10.54) J15 J13 0.790 (20.07) 0.845 DS1 (15.37) J11 0.605 (0.64) 0.025 DS3 1.785 DS2 USR FM LINK ACT J2 (45.34) 1.970 (50.04) 2.106 2.670 (53.49) J8 (67.82) 3.720 (94.49) 4.125 (104.78) J7 J2 0.200 (5.08) (21.46) 2.290 (58.17) 2.930 (74.42) 2.970 4.195 (75.44) (106.55) 4.265 (108.33) 4.450 (113.03) 4.495 (114.17) Figure A-3. User Board Footprint for BL2600 User’s Manual 81 A.2 Conformal Coating The areas around the crystal oscillator and the battery backup circuit on the BL2600 module have had the Dow Corning silicone-based 1-2620 conformal coating applied. The conformally coated areas are shown in Figure A-4. The conformal coating protects these high-impedance circuits from the effects of moisture and contaminants over time. DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 +K GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND DIN 2023 PULLS DIN 1619 PULLS J1 J2 DIN 2431 PULLS DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 RESET DIO 0007 PULLS C4 C5 RCM2 R73 20 1 19 C25 J12 GND 1 33 J10 C31 C86 C34 C35 C36 C37 RXE RXC RXF 2 26 2 25 1 GND +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND +HK0 GND HOUT1 +HK2 GND HOUT3 GND HOUT0 +HK1 GND HOUT2 +HK3 GND DS2 DS3 C32 GND U18 C30 D4 Q20 1 J16 DCIN DCIN GND R75 R58 R59 R60 485 TERM. RESISTOR 485+ J14 J13 J15 AGND D3 Q19 U15 C22 AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND C28 D2 Q18 DS1U17 R71 SPD LNK ACT C26 C24R57 R56 R31 C21 R55 R42 R37 R41 R36 R44 J4 R74 D1 Q17 2 AI3 C79 Y4 R69 C27 J11 AV0 AV1 AV2 AV3 AI0 AI1 AI2 R63 R64 C33 R32 C23 U14 15 16 R5 U3 U16 C64 C67 C83 L1 2 RP4 GND +K DCIN +5V JP3, JP4 AND JP4 RP3 DS1 34 34 C15 U10 C68 R9 R3 R4 R2 R1 C7 C16 C19 L2 R67 R70 R40 R35 15 16 RP11 RP13 Q11 RP10 RP9 RP8 RP7 R112 R11 C11 R12 R13 C6 JP1 AND JP2 C12 33 JP2 GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND R14 R8 C62 C72 R23 C18 R24 L1 R51 R49 R48 R39 C59 C61 R47 R44 U8 R7 R72 R33 R34R22 1 39 RP1 2 1 J3 DIO 0815 PULLS GND +K DCIN +5V SW1 JP3 R42 C49 GND/EGND C57 R58 BT1 R29 R37 R39 R40 JA R41 C75 R38 JP4 2 40 JP1 U4 C42 Y3 C53 C74 R19 R25 R27 R29 C33 R31 R27 R35 Q1 C71 C20 C30 C35 C37 C36 JP5 R28 C47 U9 C9 Conformally coated area RP1 C23 C29 JP3 JP4 R25 RP17 U5 RP18 U6 R18 R43 AIN0 AIN1 AIN2 AIN3 JP6 420 mA R6 C48 JP6 RP6 RCM1 RCM3000 ETHERNET CORE MODULE C17 R30 C28 C27 RP16 C24 D1 C8 C45 C44 C43 R38 AGND U13 U8 C14 C78 R26 R28 U4 C39 AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 R21 R20 R23 C31 R111 R15 C13 U12 R16 R17 R20 U11 R22 C20 RP14 RP15 RP12 U7 J9 C10 R10 J3 C32 U6 J7 J8 R19 U2 C18 C3 RP5 C3 U1 C5 R17 R18 C12 Q14 Q15 Q16 Q12 Q13 C1 R10 R14 Q8 R24 J6 RABBITNET 0 Q7 C19 U5 Q6 C17 C2 Q5 C16 C15 Q10 Q9 Q4 C4 Q3 C9 C8 J5 Q2 C1 Q1 R84 U1 R8 R7 R9 J4 RABBITNET 1 JP5 RP2 R1 JP7 TXC GND TXC TXF RXC TXF TXE RXF TXE 485 RXE J17 485+ 485 GND Figure A-4. BL2600 Areas Receiving Conformal Coating Any components in the conformally coated area may be replaced using standard soldering procedures for surface-mounted components. A new conformal coating should then be applied to offer continuing protection against the effects of moisture and contaminants. NOTE: For more information on conformal coatings, refer to Technical Note 303, Conformal Coatings. 82 SBC BL2600 A.3 Jumper Configurations Figure A-5 shows the header locations used to configure the various BL2600 options via jumpers. JP1 JP4 JP3 JP2 R1 R8 C3 U1 C5 C18 C33 C37 C36 R27 R31 JP5 R28 R35 R29 R37 R39 R40 C42 C45 C44 C43 R38 Y3 Q1 R42 C48 R41 C49 C53 C57 C61 C59 L1 R51 R49 R48 R47 R44 U8 C62 L2 R58 C35 JP4 JP3 C39 R25 U5 U6 C47 C30 C29 C28 C27 C32 C31 RP1 C23 R24 U4 D1 C12 C24 R23 C20 R20 C19 R22 C17 R19 J3 C16 C15 R17 R18 C4 R10 R14 C9 C8 C1 R7 R9 JP5 C68 C64 C67 J4 C79 Y4 R74 C83 R72 R73 DS1 R71 R75 C86 JP6 SPD LNK ACT R63 R64 R69 R67 R70 C75 C74 C72 C71 DS2 DS3 GND JP7 Figure A-5. Location of BL2600 Configurable Positions Table A-2 lists the configuration options. Table A-2. BL2600 Jumper Configurations Header JP1 Description DIO00–DIO07 User’s Manual Pins Connected 1–2 Inputs pulled up to +5 V 3–4 Inputs pulled up to DCIN 5–6 Inputs pulled up to +K 7–8 Inputs pulled down to GND Factory Default × 83 Table A-2. BL2600 Jumper Configurations Header JP2 JP3 JP4 JP5 Description DIO08–DIO15 DIN16–DIN19 DIN20–DIN23 DIN24–DIN31 Pins Connected 1–2 Inputs pulled up to +5 V 3–4 Inputs pulled up to DCIN 5–6 Inputs pulled up to +K 7–8 Inputs pulled down to GND 1–2 Inputs pulled up to +5 V 3–4 Inputs pulled up to DCIN 5–6 Inputs pulled up to +K 7–8 Inputs pulled down to GND 1–2 Inputs pulled up to +5 V 3–4 Inputs pulled up to DCIN 5–6 Inputs pulled up to +K 7–8 Inputs pulled down to GND (needed for these to be PWM outputs) 1–2 Inputs pulled up to +5 V 3–4 Inputs pulled up to DCIN 5–6 Inputs pulled up to +K 7–8 Inputs pulled down to GND None Voltage Option JP6 JP7 A/D Converter Voltage/Current Measurement Options RS-485 Bias and Termination Resistors 1–2 AIN0 4–20 mA option 3–4 AIN1 4–20 mA option 5–6 AIN2 4–20 mA option 7–8 AIN3 4–20 mA option 1–2 5–6 Bias and termination resistors connected 1–3 4–6 Bias and termination resistors not connected* Factory Default × × × × × × * Although pins 1–3 and 4–6 of header JP7 are shown “jumpered” for the termination and bias resistors not connected, pins 3 and 4 are not actually connected to anything, and this configuration is a “parking” configuration for the jumpers so that they will be readily available should you need to enable the termination and bias resistors in the future. 84 SBC BL2600 A.4 Use of Rabbit 3000 Parallel Ports Figure A-6 shows the Rabbit 3000 parallel ports. PC0, PC2, PC4 PA0PA7 PB2PB4 PD0PD1 PD4PD5 Port A Port B (+Ethernet Port) Port C PG2, PG6 (+Ethernet Port) 3000 Port G Real-Time Clock Watchdog 11 Timers Slave Port Clock Doubler Programming Port PC6 PC7, /RES (Serial Port A) Ethernet Port 4 Ethernet signals RAM PE4PE5 PF0 Port F (Serial Ports E & F) PG3, PG7 PE0PE3 Port E RABBIT (Serial Ports B,C & D) PC1, PC3, PC5 Port D Backup Battery Support PF1PF7 Port G PG0, PG1, PG4 /RES_IN /IORD /RESET, /IOWR, STATUS SMODE0 SMODE1 (+Serial Ports) Misc. I/O Flash Figure A-6. BL2600 Rabbit-Based Subsystems Table A-3 lists the Rabbit 3000 parallel ports and their use in the BL2600. Table A-3. Use of Rabbit 3000 Parallel Ports Port I/O PA0–PA7 I/O PB0–PB1 Input PB2–PB4 Output IA0–IA2 High PB5–PB7 Output Not connected High PC0 Output TXD SPI PC1 Input RXD SPI PC2 Output TXC RS-232 PC3 Input RXC RS-232 PC4 Output Not connected Inactive high PC5 Input Not connected Pulled up PC6 Output TXA Programming Port PC7 Input RXA Programming Port User’s Manual Signal Initial State ID0–ID7 Pulled up Not connected Pulled up Serial Port D Serial Port C Serial Port A Inactive high Pulled up Inactive high Pulled up Low Pulled up 85 Table A-3. Use of Rabbit 3000 Parallel Ports (continued) Port I/O Signal Initial State PD0–PD1 Output/ENET PD2–PD3 Output Not connected Low PD4 Output Load D/A converter data Low PD5 Output RS-485/RS-232 select Low PD6–PD7 Output Not connected Low PE0 Output/ENET PE1 Output PE2 Output/ENET PE3 Output PE4–PE5 Input PE6–PE7 Output Not connected Low PF0 Output Serial CLKD Low PF1 Input A/D converter busy Pulled up PF2–PF7 Input IN02–IN07 Pulled up PG0 Output EEPROM CLK — PG1 Output EEPROM data Pulled up PG2 Output TXF RS-232 PG3 Input RXF RS-232 PG4 Output /CS (digital output enable) Low PG5 Output Not connected Low PG6 Output TXE RS-232 PG7 Input RXE RS-232 Not connected or Ethernet See Note Not connected or Ethernet See Note /CS strobe (digital I/O enable) Not connected or Ethernet Inactive high See Note RS-485 transmit control Low IN00-IN01 Pulled up Serial Port F Serial Port E Inactive high Pulled up Inactive high Pulled up The PD0, PD1, PE0, and PE2 signals are configured on the RabbitCore module, and not on the BL2600. These parallel-port bits are configured for Ethernet on RabbitCore modules with Ethernet and for output low on RabbitCore modules without Ethernet. The signals are not available on the BL2600 for customer use in applications. 86 SBC BL2600 APPENDIX B. POWER SUPPLY Appendix B describes the power circuitry provided on the BL2600. B.1 Power Supplies Power is supplied to the BL2600 via the friction-lock connector at J12. The BL2600 is protected against reverse polarity by a diode at D1 as shown in Figure B-1. SWITCHING POWER REGULATOR RAW POWER IN J12 1 4 D41 1B220 1 TVS1 U15 C25 47 µF LINEAR POWER REGULATOR +3.3 V 3 4 2 LM2576 +5 V 330 µH C22 D42 L1 330 µF B220 C44 10 µF LM1117T U10 2 1 C44 10 µF ANALOG POWER +5 V SUPPLY R56 4.7 W ±12 V POWER SUPPLIES C24 10 µF R57 C23 0.1 µF 0W C78 GND 0.1 µF AGND Figure B-1. BL2600 Power Supply The input voltage range is from 9 V to 36 V. A switching power regulator is used to provide +5 V for the BL2600 logic circuits. In turn, the regulated +5 V DC power supply is used to drive a regulated +3.3 V power supply and ±12 V power supplies used by the opamps driving the digital outputs. The digital ground and the analog ground share a single split ground plane on the board, with the analog ground connected at a single point to the digital ground by a 0 resistor (R57). This is done to minimize digital noise in the analog circuits and to eliminate the possibility of ground loops. External connections to analog ground are made on a polarized friction-lock connector at J8. User’s Manual 87 B.1.1 Power for Analog Circuits Power to the analog circuits is provided by way of a one-stage low-pass filter, which isolates the analog section from digital noise generated by the other components. The analog +5 V supply powers the D/A converter, and is not accessible to the user. The A/D converter is powered by the regulated +3.3 V supply, and supplies the +2.048 V reference violate from which the 1.667 V and 2.5 V reference voltages for the D/A converter output circuits are derived. B.2 Batteries and External Battery Connections The SRAM and the real-time clock on the BL2600 module have battery backup. Power to the SRAM and the real-time clock (VRAM) is provided by two different sources, depending on whether the main part of the BL2600 is powered or not. When the BL2600 is powered normally, and the +3.3 V supply is within operating limits, the SRAM and the real-time clock are powered from the +3.3 V supply. If power to the board is lost or falls below 2.93 V (2.63 V on the BL2610), the VRAM and real-time clock power will come from the battery. The reset generator circuit controls the source of power by way of its /RESET output signal. A replaceable 950 mA·h lithium battery provides power to the real-time clock and SRAM when external power is removed from the circuit board. The drain on the battery is typically less than 10 µA when there is no external power applied to the BL2600, and so the expected shelf life of the battery is 950 mA·h ------------------------ = 9.0 years. 12 µA B.2.1 Replacing the Backup Battery The battery is user-replaceable, and is fitted in a battery holder. To replace the battery, lift up on the spring clip and slide out the old battery. Use only a Panasonic CR2477 or equivalent replacement battery, and insert it into the battery holder with the + side facing up. NOTE: The SRAM contents and the real-time clock settings will be lost if the battery is replaced with no power applied to the BL2600. Exercise care if you replace the battery while external power is applied to the BL2600. CAUTION: There is an explosion danger if the battery is short-circuited, recharged, or replaced incorrectly. Replace the battery only with the same type or an equivalent type recommended by the battery manufacturer. Dispose of used batteries according to the battery manufacturer’s instructions. Cycle the main power off/on on the BL2600 whenever you replace the backup battery. This step will minimize the current drawn by the real-time clock oscillator circuit from the backup battery should the BL2600 experience a loss of main power. NOTE: Remember to cycle the main power off/on any time the BL2600’s RabbitCore module is removed from the main board since removing the RabbitCore module disconnects power to its real-time clock oscillator. 88 SBC BL2600 B.3 Power to Peripheral Boards J1 DCIN and Vcc are available on friction-lock connector terminals J5 and J7 to power peripheral boards that may be used with the BL2600. GND R1 R8 C17 C18 C23 C35 C33 C29 C37 C36 R27 R31 JP5 R28 C39 R25 R35 R29 R37 R39 R40 C42 C45 C44 C43 R38 Y3 Q1 R42 C48 R41 C49 C53 C59 C57 C61 L1 R51 R49 R48 R47 R44 U8 C62 L2 C68 R58 C64 C67 R69 C79 Y4 J4 R74 C83 R72 R73 DS1 R67 R70 C75 C74 C72 C71 R63 R64 R71 R75 C86 DS2 DS3 SPD LNK ACT DCIN C30 JP4 JP3 J7 RP1 U5 U6 C47 C12 C28 C27 C32 D1 GND C20 R24 U4 C31 J6 RABBITNET 0 n.c. R20 R23 C24 R22 C19 J3 J7 U1 C5 R17 R18 R19 DCIN Vcc C3 R10 R14 C4 R7 R9 C16 C15 n.c. J5 C9 C8 J5 C1 Vcc J4 RABBITNET 1 GND Figure B-2. Pinout Friction-Lock Connector Terminals J5 and J7 Keep in mind that the BL2600 draws 377 mA from the Vcc supply, and that the diode at D41 (shown in Figure B-1) can handle at most 1 A at VRAW, so that leaves the remaining current capacity to be shared among the DCIN and Vcc pins on friction-lock connector terminals J5 and J7. Table B-1 lists the available current at DCIN based on the current drawn at Vcc. Table B-1. DCIN Current Available at J7 and J8 (in mA) Based on Power Supply and Vcc (= 5 V) Current Used at J5 and J7 VRAW Power Supply Input at J2 (V) Current at J5 and J7 with Vcc = 5 V 100 mA 200 mA 300 mA 400 mA 500 mA 600 mA 623 mA 8.0 545 450 355 260 164 69 47 8.5 574 484 395 306 216 127 107 9.0 599 515 431 347 263 178 159 10 641 566 490 415 340 265 248 12 703 641 579 517 455 393 378 18 805 764 723 682 642 601 591 24 855 824 794 763 733 703 696 30 884 860 836 811 787 763 750 40 913 895 877 859 841 823 819 User’s Manual 89 90 SBC BL2600 APPENDIX C. DEMONSTRATION BOARD Appendix C shows how to connect the Demonstration Board to the BL2600. C.1 Connecting Demonstration Board Before running sample programs based on the Demonstration Board, you will have to connect the Demonstration Board from the BL2600 Tool Kit to the BL2600 board. Proceed as follows. 1. Use the wires included in the BL2600 Tool Kit to connect header J1 on the Demonstration Board to screw-terminal headers J1 and J12 on the BL2600. The connections are shown in Figure C-1 for sample program DIGIN.C and for sample program SMTP.C, in Figure C-2 for sample program DIGOUT.C and for sample program SSI.C, and in Figure C-3 for sample program HIGH_CURRENT_IO.C. 2. Make sure that your BL2600 is connected to your PC via the programming cable and that the power supply is connected to the BL2600 and plugged in as described in Chapter 2, “Getting Started.” User’s Manual 91 J1 · · · · · · · · · · · · 1-2 BUZZER AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 AGND AIN0 AIN1 AIN2 AIN3 JP6 420 mA R43 U11 R21 U13 J7 R18 R26 R28 R19 C14 C78 C17 R32 C23 U14 19 1 AV0 AV1 AV2 AV3 AI0 AI1 AI2 AI3 U6 C2 C22 J15 AGND AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND 20 J11 2 R30 C20 R25 R27 R29 R15 C13 U12 R16 2 1 J3 R111 Q10 Q11 J1 R17 C10 R10 Q9 Q3 + U7 C3 Q12 Q13 Q5 Q6 Q8 GND C25 J12 U15 J9 RP12 1 2 J13 GND D1 Q17 BT1 C8 U8 C27 J3 R22 R7 R9 R58 C53 C47 R69 D2 Q18 R73 R8 RP2 R23 R41 C28 R84 U1 R20 R10 R14 C31 D1 R1 U4 R19 R17 R18 C1 U6 C3 U2 RP17 U5 RP18 U1 C5 Q1 L1 C57 +HK0 GND HOUT1 +HK2 GND HOUT3 GND HOUT0 +HK1 GND HOUT2 +HK3 GND C71 C68 L2 C64 C67 R25 TXC TXC GND 1 25 RXC TXF TXF RXC RXF RP5 U4 J4 R7 Y3 R6 RP6 C33 RXF TXE TXE RXE R71 C86 RXE 485+ 485 GND J17 JP7 485 TERM. RESISTOR R58 R59 R60 C32 DS3 DS2 U18 485 485+ R8 U16 DS1U17 GND R75 RP1 1 R29 R37 R39 R40 GND/EGND JA C35 C36 C37 C79 Y4 C42 C34 R63 R64 D4 Q20 2 J14 C62 26 D3 Q19 U8 C59 R35 RCM1 RCM3000 ETHERNET CORE MODULE +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND U9 C9 RP16 RP14 RP15 Q14 Q15 Q16 Q7 DCIN DCIN GND L1 Q4 R72 JP6 R20 J8 RP8 RP7 U5 C7 R31 C21 Q2 RP10 RP9 GND +K DCIN +5V J6 RABBITNET 0 R11 C11 R12 R13 C12 R14 Q1 R2 J5 C75 R33 R34R22 C74 R39 R44 R38 R51 R49 R48 R44 DEMO BOARD C19 R47 R23 C18 R24 BUZZER LED4 LED1 LED2 LED3 LED4 R112 C49 C16 C48 R41 R36 C39 C45 C44 C43 R38 LED3 LED2 LED1 K +5V SW4 SW3 SW2 SW1 GND H1 ·· ·· ·· ·· 8-7 6-5 4-3 2-1 SW4 JP5 R74 R40 R35 40 39 U10 J2 RP13 DS1 R28 C72 C83 R55 R42 R37 R1 RP11 R3 1 15 JP3 C15 C32 C61 R56 JP4 R31 C24R57 J4 RABBITNET 1 R4 R24 C37 C36 R67 R70 J16 2 RP1 2 16 34 C4 R5 C5 JP1 AND JP2 JP2 SW3 C28 C27 R27 R42 C26 C19 C6 C20 C35 R9 U3 RP4 GND +K DCIN +5V JP3, JP4 AND JP4 C29 RCM2 GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND JP1 DIO 0007 PULLS DIO 0815 PULLS SW2 16 DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 3-4 C24 34 SW1 RESET 5-6 C33 J10 C16 C15 C30 C31 JP3 DIN 1619 PULLS H2 C17 33 JP4 RP3 DIN 2023 PULLS SW1 C1 15 JP5 ·· ·· ·· C9 C8 C18 C23 33 DIN 2431 PULLS Jumpers: H1: None H2: As shown GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND J1 +K 92 DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 BL2600 C12 C30 C4 J12 BL2600 (Header J1) Demonstration Board (Header J1) +DCIN (J12) GND DIO00 DIO01 DIO02 DIO03 K GND SW1 SW2 SW3 SW4 Figure C-1. General Digital Input Connections Between BL2600 and Demonstration Board SBC BL2600 SPD LNK ACT J1 · · · · · · · · · · · · 1-2 BUZZER AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 AGND AIN0 AIN1 AIN2 AIN3 JP6 420 mA R43 U11 R21 U13 J7 R18 R26 R28 R19 C14 C78 C17 R32 C23 U14 19 1 AV0 AV1 AV2 AV3 AI0 AI1 AI2 AI3 U6 C2 C22 J15 AGND AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND 20 J11 2 R30 C20 R25 R27 R29 R15 C13 U12 R16 2 1 J3 R111 Q10 Q11 J1 R17 C10 R10 Q9 Q3 + U7 C3 Q12 Q13 Q5 Q6 Q8 GND C25 J12 U15 J9 RP12 1 2 J13 GND D1 Q17 BT1 C8 U8 C27 J3 R22 R7 R9 R58 C53 C47 R69 D2 Q18 R73 R8 RP2 R23 R41 C28 R84 U1 R20 R10 R14 C31 D1 R1 U4 R19 R17 R18 C1 U6 C3 U2 RP17 U5 RP18 U1 C5 Q1 L1 C57 +HK0 GND HOUT1 +HK2 GND HOUT3 GND HOUT0 +HK1 GND HOUT2 +HK3 GND C71 C68 L2 C64 C67 R25 TXC TXC GND 1 25 RXC TXF TXF RXC RXF RP5 U4 J4 R7 Y3 R6 RP6 C33 RXF TXE TXE RXE R71 C86 R8 U16 485+ 485 GND J17 JP7 485 TERM. RESISTOR R58 R59 R60 C32 DS3 DS2 U18 485 485+ RXE R29 R37 DS1U17 GND R75 RP1 1 R39 R40 GND/EGND JA C35 C36 C37 C79 Y4 C42 C34 R63 R64 D4 Q20 2 J14 C62 26 D3 Q19 U8 C59 R35 RCM1 RCM3000 ETHERNET CORE MODULE +HK0 GND HOUT1 +HK2 GND HOUT3 HOUT0 +HK1 GND HOUT2 +HK3 GND U9 C9 RP16 RP14 RP15 Q14 Q15 Q16 Q7 DCIN DCIN GND L1 Q4 R72 JP6 R20 J8 RP8 RP7 U5 C7 R31 C21 Q2 RP10 RP9 GND +K DCIN +5V J6 RABBITNET 0 R11 C11 R12 R13 C12 R14 Q1 R2 J5 C75 R33 R34R22 C74 R39 R44 R38 R51 R49 R48 R44 DEMO BOARD C19 R47 R23 C18 R24 BUZZER LED4 LED1 LED2 LED3 LED4 R112 C49 C16 C48 R41 R36 C39 C45 C44 C43 R38 LED3 LED2 LED1 K +5V SW4 SW3 SW2 SW1 GND H1 ·· ·· ·· ·· 8-7 6-5 4-3 2-1 SW4 JP5 R74 R40 R35 40 39 U10 J2 RP13 DS1 R28 C72 C83 R55 R42 R37 R1 RP11 R3 1 15 JP3 C15 C32 C61 R56 JP4 R31 C24R57 J4 RABBITNET 1 R4 R24 C37 C36 R67 R70 J16 2 RP1 2 16 34 C4 R5 C5 JP1 AND JP2 JP2 SW3 C28 C27 R27 R42 C26 C19 C6 C20 C35 R9 U3 RP4 GND +K DCIN +5V JP3, JP4 AND JP4 C29 RCM2 GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND JP1 DIO 0007 PULLS DIO 0815 PULLS SW2 16 DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 3-4 C24 34 SW1 RESET 5-6 C33 J10 C16 C15 C30 C31 JP3 DIN 1619 PULLS H2 C17 33 JP4 RP3 DIN 2023 PULLS SW1 C1 15 JP5 ·· ·· ·· C9 C8 C18 C23 33 DIN 2431 PULLS Jumpers: H1: None H2: As shown GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND J1 +K User’s Manual DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 BL2600 C12 C30 C4 J12 BL2600 (Header J1) Demonstration Board (Header J1) +DCIN (J12) GND DIO00 DIO01 DIO02 DIO03 K GND LED1 LED2 LED3 LED4 Figure C-2. Digital Output Connections Between BL2600 and Demonstration Board 93 SPD LNK ACT DIN31 DIN29 DIN27 DIN25 +K DIN23 DIN21 DIN19 DIN17 GND GND DIN30 DIN28 DIN26 DIN24 GND DIN22 DIN20 DIN18 DIN16 +K GND DIO14 DIO12 DIO10 DIO08 DIO06 DIO04 DIO02 DIO00 GND DIO15 DIO13 DIO11 DIO09 DIO07 DIO05 DIO03 DIO01 GND JP4 JP5 DIN 1619 PULLS J1 J2 DIN 2023 PULLS DIN 2431 PULLS DIN31 DIN27 DIN23 DIN19 +K DIO15 DIO11 DIO07 DIO03 GND GND DIN29 DIN25 DIN21 DIN17 GND DIO13 DIO09 DIO05 DIO01 RESET DIO 0007 PULLS J15 AGND C25 J12 GND C5 1 15 33 34 J10 C31 C86 C34 RCM2 C35 C36 C37 RXE RXC RXF 26 2 25 1 +HK0 GND HOUT1 +HK2 GND HOUT3 GND HOUT0 +HK1 GND HOUT2 +HK3 GND +HK0 GND HOUT1 +HK2 GND HOUT3 GND HOUT0 +HK1 GND HOUT2 +HK3 GND J12 DS3 C32 R58 R59 R60 485 TERM. RESISTOR 485+ J14 2 DS2 GND U18 C30 D4 Q20 1 J16 + DCIN DCIN GND 2 RP4 GND +K DCIN +5V JP3, JP4 AND JP4 C4 R5 16 U3 R9 34 U10 C26 R56 C24R57 R31 C21 R55 R42 R37 D3 Q19 J13 C22 AIN1 AIN3 AIN5 AIN7 AGND AV1 AV3 AI1 AI3 AGND AIN0 AIN2 AIN4 AIN6 AGND AV0 AV2 AI0 AI2 AGND C28 D2 Q18 DS1U17 R71 R75 SPD LNK ACT R4 R3 R2 R1 C15 C16 C19 RP3 DS1 15 16 RP11 RP13 Q11 RP10 RP9 RP8 RP7 C7 R112 R11 C11 R12 R13 C12 R14 R41 R36 J4 R74 R40 R35 C79 Y4 C83 R23 C18 R24 R63 R64 R67 R70 R39 C6 JP1 AND JP2 C72 R33 R34R22 R42 R51 R49 R48 R38 C35 C61 R47 R44 U16 R73 D1 Q17 20 19 C33 C29 C49 R8 C64 C67 R69 U15 J11 C30 R27 R31 C48 R44 C23 C37 C36 JP5 R28 R7 L1 C71 L1 R40 C62 C68 C27 1 C18 JP3 JP4 C57 L2 BT1 R37 R39 C33 2 AI3 C59 U8 R58 R32 C23 U14 AV0 AV1 AV2 AV3 AI0 AI1 AI2 R29 JA GND/EGND R72 R30 U4 Q1 C75 R26 R28 RP1 C42 Y3 C53 R18 R25 R27 R35 R41 C47 C17 R19 R29 R6 R25 U5 RP18 RP17 U6 C14 C78 C20 RP6 RCM1 RCM3000 ETHERNET CORE MODULE U9 C9 BL2600 U2 C28 C27 RP16 R43 AIN0 AIN1 AIN2 AIN3 JP6 420 mA C24 D1 C8 C74 JP6 C31 C45 C44 C43 R38 AGND U13 U8 C39 AIN0 AIN1 AIN2 AIN3 AIN4 AIN5 AIN6 AIN7 R21 U4 R111 R15 C13 U12 R16 R17 R20 U11 R20 R23 C20 RP14 RP15 RP12 U7 J7 C10 R10 R22 C32 U6 J9 J8 R19 J3 C17 C3 RP5 C3 U1 C5 R17 R18 Q14 Q15 Q16 Q12 Q13 C1 R10 R14 Q8 R24 J6 RABBITNET 0 Q7 C19 U5 Q6 C12 C2 Q5 C16 C15 Q10 Q9 Q4 33 JP2 GND DIN28 DIN24 DIN20 DIN16 GND DIO12 DIO08 DIO04 DIO00 DIN30 DIN26 DIN22 DIN18 +K DIO14 DIO10 DIO06 DIO02 GND Q3 C4 J5 Q2 C9 C8 Q1 C1 R7 R9 J4 RABBITNET 1 R84 U1 R8 1 39 RP1 2 1 J3 DIO 0815 PULLS GND +K DCIN +5V JP3 2 40 JP1 SW1 RP2 R1 JP7 TXC GND TXC TXF RXC TXF TXE RXF TXE 485 RXE J17 485+ 485 GND J16 J1 · · · · · · · · · · · · LED1 LED2 LED3 LED4 BUZZER LED4 LED3 LED2 LED1 K +5V 1-2 3-4 5-6 DEMO BOARD BUZZER H1 ·· ·· ·· ·· ·· ·· ·· SW4 H2 SW3 SW2 SW1 GND Jumpers: H1: None H2: As shown Demonstration Board (Header J1) +DCIN (J12) ® +HK0,+HK1,+HK2,+HK3 GND (J12) HOUT0 HOUT1 HOUT2 HOUT3 GND K LED1 LED2 LED3 8-7 SW4 4-3 SW3 6-5 SW2 2-1 SW1 BL2600 (Header J16) Figure C-3. HIGH_CURRENT_IO.C Connections Between BL2600 and Demonstration Board NOTE: +HK0…+HK3 on header J16 must be connected to +DCIN on friction-lock connector J12 as shown in Figure C-3. 94 SBC BL2600 APPENDIX D. RABBITNET D.1 General RabbitNet Description RabbitNet is a high-speed synchronous protocol developed by Rabbit to connect peripheral cards to a master and to allow them to communicate with each other. D.1.1 RabbitNet Connections All RabbitNet connections are made point to point. A RabbitNet master port can only be connected directly to a peripheral card, and the number of peripheral cards is limited by the number of available RabbitNet ports on the master. SLAVE Straight-through CAT 5/6 Ethernet cable SLAVE Rabbit 3000® Microprocessor MASTER Crossover CAT 5/6 Ethernet cable MASTER SLAVE Straight-through CAT 5/6 Ethernet cable Figure D-1. Connecting Peripheral Cards to a Master User’s Manual 95 Use a straight-through CAT 5/6 Ethernet cable to connect the master to slave peripheral cards, unless you are using a device such as the OP7200 that could be used either as a master or a slave. In this case you would use a crossover CAT 5/6 Ethernet cable to connect an OP7200 that is being used as a slave. Distances between a master unit and peripheral cards can be up to 10 m or 33 ft. D.1.2 RabbitNet Peripheral Cards • Digital I/O 24 inputs, 16 push/pull outputs, 4 channels of 10-bit A/D conversion with ranges of 0 to 10 V, 0 to 1 V, and -0.25 to +0.25 V. The following connectors are used: Signal = 0.1" friction-lock connectors Power = 0.156" friction-lock connectors RabbitNet = RJ-45 connector • A/D converter 8 channels of programmable-gain 12-bit A/D conversion, configurable as current measurement and differential-input pairs. 2.5 V reference voltage is available on the connector. The following connectors are used: Signal = 0.1" friction-lock connectors Power = 0.156" friction-lock connectors RabbitNet = RJ-45 connector • D/A converter 8 channels of 0–10 V 12-bit D/A conversion. The following connectors are used: Signal = 0.1" friction-lock connectors Power = 0.156" friction-lock connectors RabbitNet = RJ-45 connector • Display/Keypad interface Allows you to connect your own keypad with up to 64 keys and one character liquid crystal display from 1 × 8 to 4 × 40 characters with or without backlight using standard 1 × 16 or 2 × 8 connectors. The following connectors are used: Signal = 0.1" headers or sockets Power = 0.156" friction-lock connectors RabbitNet = RJ-45 connector • Relay card 6 relays rated at 250 V AC, 1200 V·A or 100 V DC up to 240 W. The following connectors are used: Relay contacts = screw-terminal connectors Power = 0.156" friction-lock connectors RabbitNet = RJ-45 connector Visit our Web site for up-to-date information about additional cards and features as they become available. The Web site also has the latest revision of this user’s manual. 96 SBC BL2600 D.2 Physical Implementation There are four signaling functions associated with a RabbitNet connection. From the master’s point of view, the transmit function carries information and commands to the peripheral card. The receive function is used to read back information sent to the master by the peripheral card. A clock is used to synchronize data going between the two devices at high speed. The master is the source of this clock. A slave select (SS) function originates at the master, and when detected by a peripheral card causes it to become selected and respond to commands received from the master. The signals themselves are differential RS-422, which are series-terminated at the source. With this type of termination, the maximum frequency is limited by the round-trip delay time of the cable. Although a peripheral card could theoretically be up to 45 m (150 ft) from the master for a data rate of 1 MHz, Rabbit recommends a practical limit of 10 m (33 ft). Connections between peripheral cards and masters are done using standard 8-conductor CAT 5/6 Ethernet cables. Masters and peripheral cards are equipped with RJ-45 8-pin female connectors. The cables may be swapped end for end without affecting functionality. D.2.1 Control and Routing Control starts at the master when the master asserts the slave select signal (SS). Then it simultaneously sends a serial command and clock. The first byte of a command contains the address of the peripheral card if more than one peripheral card is connected. A peripheral card assumes it is selected as soon as it receives the select signal. For direct master-to-peripheral-card connections, this is as soon as the master asserts the select signal. The connection is established once the select signal reaches the addressed slave. At this point communication between the master and the selected peripheral card is established, and data can flow in both directions simultaneously. The connection is maintained so long as the master asserts the select signal. User’s Manual 97 D.3 Function Calls The function calls described in this section are used with all RabbitNet peripheral cards, and are available in the RNET.LIB library in the Dynamic C RABBITNET folder. int rn_init(char portflag, char servicetype); Resets, initializes, or disables a specified RabbitNet port on the master single-board computer. During initialization, the network is enumerated and relevant tables are filled in. If the port is already initialized, calling this function forces a re-enumeration of all devices on that port. Call this function first before using other RabbitNet functions. PARAMETERS portflag is a bit that represents a RabbitNet port on the master single-board computer (from 0 to the maximum number of ports). A set bit requires a service. If portflag = 0x03, both RabbitNet ports 0 and 1 will need to be serviced. servicetype enables or disables each RabbitNet port as set by the port flags. 0 = disable port 1 = enable port RETURN VALUE 0 int rn_device(char pna); Returns an address index to device information from a given physical node address. This function will check device information to determine that the peripheral card is connected to a master. PARAMETER pna is the physical node address, indicated as a byte. 7,6—2-bit binary representation of the port number on the master 5,4,3—Level 1 router downstream port 2,1,0—Level 2 router downstream port RETURN VALUE Pointer to device information. -1 indicates that the peripheral card either cannot be identified or is not connected to the master. SEE ALSO rn_find 98 SBC BL2600 int rn_find(rn_search *srch); Locates the first active device that matches the search criteria. PARAMETER srch is the search criteria structure rn_search: unsigned int flags; unsigned int ports; char productid; char productrev; char coderev; long serialnum; // // // // // // status flags see MATCH macros below port bitmask product id product rev code rev serial number Use a maximum of 3 macros for the search criteria: RN_MATCH_PORT RN_MATCH_PNA RN_MATCH_HANDLE RN_MATCH_PRDID RN_MATCH_PRDREV RN_MATCH_CODEREV RN_MATCH_SN // // // // // // // match match match match match match match port bitmask physical node address instance (reg 3) id/version (reg 1) product revision code revision serial number For example: rn_search newdev; newdev.flags = RN_MATCH_PORT|RN_MATCH_SN; newdev.ports = 0x03; //search ports 0 and 1 newdev.serialnum = E3446C01L; handle = rn_find(&newdev); RETURN VALUE Returns the handle of the first device matching the criteria. 0 indicates no such devices were found. SEE ALSO rn_device int rn_echo(int handle, char sendecho, char *recdata); The peripheral card sends back the character the master sent. This function will check device information to determine that the peripheral card is connected to a master. PARAMETERS handle is an address index to device information. Use rn_device() or rn_find() to establish the handle. sendecho is the character to echo back. recdata is a pointer to the return address of the character from the device. RETURN VALUE The status byte from the previous command. -1 means that device information indicates the peripheral card is not connected to the master. User’s Manual 99 int rn_write(int handle, int regno, char *data, int datalen); Writes a string to the specified device and register. Waits for results. This function will check device information to determine that the peripheral card is connected to a master. PARAMETERS handle is an address index to device information. Use rn_device() or rn_find() to establish the handle. regno is the command register number as designated by each device. data is a pointer to the address of the string to write to the device. datalen is the number of bytes to write (0–15). NOTE: A data length of 0 will transmit the one-byte command register number. RETURN VALUE The status byte from the previous command. -1 means that device information indicates the peripheral card is not connected to the master, and -2 means that the data length was greater than 15. SEE ALSO rn_read int rn_read(int handle, int regno, char *recdata, int datalen); Reads a string from the specified device and register. Waits for results. This function will check device information to determine that the peripheral card is connected to a master. PARAMETERS handle is an address index to device information. Use rn_device() or rn_find() to establish the handle. regno is the command register number as designated by each device. recdata is a pointer to the address of the string to read from the device. datalen is the number of bytes to read (0–15). NOTE: A data length of 0 will transmit the one-byte command register number. RETURN VALUE The status byte from the previous command. -1 means that device information indicates the peripheral card is not connected to the master, and -2 means that the data length was greater than 15. SEE ALSO rn_write 100 SBC BL2600 int rn_reset(int handle, int resettype); Sends a reset sequence to the specified peripheral card. The reset takes approximately 25 ms before the peripheral card will once again execute the application. Allow 1.5 seconds after the reset has completed before accessing the peripheral card. This function will check peripheral card information to determine that the peripheral card is connected to a master. PARAMETERS handle is an address index to device information. Use rn_device() or rn_find() to establish the handle. resettype describes the type of reset. 0 = hard reset—equivalent to power-up. All logic is reset. 1 = soft reset—only the microprocessor logic is reset. RETURN VALUE The status byte from the previous command. -1 means that device information indicates the peripheral card is not connected to the master. int rn_sw_wdt(int handle, float timeout); Sets software watchdog timeout period. Call this function prior to enabling the software watchdog timer. This function will check device information to determine that the peripheral card is connected to a master. PARAMETERS handle is an address index to device information. Use rn_device() or rn_find() to establish the handle. timeout is a timeout period from 0.025 to 6.375 seconds in increments of 0.025 seconds. Entering a zero value will disable the software watchdog timer. RETURN VALUE The status byte from the previous command. -1 means that device information indicates the peripheral card is not connected to the master. User’s Manual 101 int rn_enable_wdt(int handle, int wdttype); Enables the hardware and/or software watchdog timers on a peripheral card. The software on the peripheral card will keep the hardware watchdog timer updated, but will hard reset if the time expires. The hardware watchdog cannot be disabled except by a hard reset on the peripheral card. The software watchdog timer must be updated by software on the master. The peripheral card will soft reset if the timeout set by rn_sw_wdt() expires. This function will check device information to determine that the peripheral card is connected to a master. PARAMETERS handle is an address index to device information. Use rn_device() or rn_find() to establish the handle. wdttype 0 enables both hardware and software watchdog timers 1 enables hardware watchdog timer 2 enables software watchdog timer RETURN VALUE The status byte from the previous command. -1 means that device information indicates the peripheral card is not connected to the master. SEE ALSO rn_hitwd, rn_sw_wdt int rn_hitwd(int handle, char *count); Hits software watchdog. Set the timeout period and enable the software watchdog prior to using this function. This function will check device information to determine that the peripheral card is connected to a master. PARAMETERS handle is an address index to device information. Use rn_device() or rn_find() to establish the handle. count is a pointer to return the present count of the software watchdog timer. The equivalent time left in seconds can be determined from count × 0.025 seconds. RETURN VALUE The status byte from the previous command. -1 means that device information indicates the peripheral card is not connected to the master. SEE ALSO rn_enable_wdt, rn_sw_wdt 102 SBC BL2600 int rn_rst_status(int handle, char *retdata); Reads the status of which reset occurred and whether any watchdogs are enabled. PARAMETERS handle is an address index to device information. Use rn_device() or rn_find() to establish the handle. retdata is a pointer to the return address of the communication byte. A set bit indicates which error occurred. This register is cleared when read. 7—HW reset has occurred 6—SW reset has occurred 5—HW watchdog enabled 4—SW watchdog enabled 3,2,1,0—Reserved RETURN VALUE The status byte from the previous command. int rn_comm_status(int handle, char *retdata); PARAMETERS handle is an address index to device information. Use rn_device() or rn_find() to establish the handle. retdata is a pointer to the return address of the communication byte. A set bit indicates which error occurred. This register is cleared when read. 7—Data available and waiting to be processed MOSI (master out, slave in) 6—Write collision MISO (master in, slave out) 5—Overrun MOSI (master out, slave in) 4—Mode fault, device detected hardware fault 3—Data compare error detected by device 2,1,0—Reserved RETURN VALUE The status byte from the previous command. User’s Manual 103 D.3.1 Status Byte Unless otherwise specified, functions returning a status byte will have the following format for each designated bit. 7 × 6 5 4 3 2 1 0 00 = Reserved 01 = Ready 10 = Busy 11 = Device not connected × 0 = Device 1 = Router × 0 = No error × 1 = Communication error* Reserved for individual peripheral cards × Reserved for individual peripheral cards × 0 = Last command accepted 1 = Last command unexecuted × × 0 = Not expired 1 = HW or SW watchdog timer expired† * Use the function rn_comm_status() to determine which error occurred. † Use the function rn_rst_status() to determine which timer expired. 104 SBC BL2600 SCHEMATICS 090-0195 BL2600 Schematic www.rabbit.com/documentation/schemat/090-0195.pdf 090-0214 RCM3365/RCM3375 Module Schematic www.rabbit.com/documentation/schemat/090-0214.pdf 090-0120 RCM3200 Module Schematic www.rabbit.com/documentation/schemat/090-0152.pdf 090-0119 RCM3100 Module Schematic www.rabbit.com/documentation/schemat/090-0144.pdf 090-0042 Demonstration Board Schematic www.rabbit.com/documentation/schemat/090-0042.pdf 090-0128 Programming Cable Schematic www.rabbit.com/documentation/schemat/090-0128.pdf You may use the URL information provided above to access the latest schematics directly. User’s Manual 105 106 SBC BL2600 INDEX A A/D converter ....................... 29 buffered inputs .................. 29 calibration ......................... 30 calibration constants ......... 30 current-measurement setup 30 function calls anaIn .............................. 62 anaInCalib ..................... 60 anaInVolts ......... 63, 64, 65 analog I/O reference voltage circuit .... 33 reference voltages ............. 33 analog inputs See A/D converter analog outputs See D/A converter B battery backup use of battery-backed SRAM 70 battery connections ............... 88 board initialization function calls ..................... 48 brdInit ............................ 48 C CE compliance ........................ 6 design guidelines ................. 7 clock doubler ........................ 35 conformal coating ................. 82 connections Ethernet cable ................... 71 connectivity tools crimp tool ............................ 5 friction-lock connector parts . 18 RS-232/USB converter ....... 5 connector options .................... 3 D D/A converter ....................... 31 User’s Manual calibration ......................... 32 calibration constants ......... 32 function calls anaOut ........................... 68 anaOutCalib .................. 67 anaOutVolts .................. 68 Demonstration Board .............. 4 hookup instructions ........... 91 digital input sample programs .......................... 92 digital output sample programs .......................... 93 TCP/IP sample programs .. 92, 94 jumper configurations 92, 93, 94 wire assembly ..................... 4 digital I/O function calls digIn .............................. 56 digOut ........................... 50 digOutConfig ................ 21 digital inputs ......................... 19 pullup/pulldown configuration 19 switching threshold ..... 20, 24 digital outputs ....................... 21 sinking or sourcing ............ 21 dimensions BL2600 main board .......... 78 Dynamic C .................. 5, 39, 40 add-on modules ........... 12, 41 installation ..................... 12 basic instructions ............... 39 battery-backed SRAM ...... 70 debugging features ............ 40 installation ......................... 12 protected variables ............ 70 standard features debugging ...................... 40 starting .............................. 13 telephone-based technical support ............................ 5, 41 upgrades and patches ........ 41 E Ethernet cables ...................... 71 Ethernet connections ............. 71 steps .................................. 71 Ethernet port ......................... 28 pinout ................................ 28 exclusion zone ...................... 80 F features .................................... 1 flash memory lifetime write cycles .......... 39 serial flash ......................... 36 flash memory addresses user blocks ........................ 36 friction-lock connectors parts ................................... 18 H headers BL2600 JP1 ................................. 24 JP2 ................................. 24 JP3 ................................. 19 JP4 ................................. 19 JP5 ................................. 19 JP6 ................................. 30 JP7 ................................. 26 Demonstration Board H1 ...................... 92, 93, 94 H2 ...................... 92, 93, 94 I IP addresses .......................... 74 how to set .......................... 73 how to set PC IP address .. 74 J jumper configurations ........... 83 Demonstration Board . 92, 93, 94 JP1 (digital input DIO00– 107 DIO07 pullup/pulldown configuration) ..........24, 83 JP2 (digital input DIO08– DIO15 pullup/pulldown configuration) ..........24, 84 JP3 (digital input DIN16– DIN19 pullup/pulldown configuration) ..........19, 84 JP4 (digital input DIN20– DIN23 pullup/pulldown configuration) ....19, 20, 84 JP5 (digital input DIN24– DIN31 pullup/pulldown configuration) ..........19, 84 JP6 (A/D converter voltage/ current measurement options) .......................30, 84 JP7 (RS-485 bias and termination resistors) ...........26, 84 jumper locations ................83 module flash memory bank select .................................36 M memory .................................36 flash memory configurations . 36 insertion/removal of memory card ................................37 NAND flash options ..........37 SRAM configuration for different sizes ....................36 models .....................................2 additional Ethernet options ..3 additional memory options ..3 BL2600 ................................2 BL2610 ................................2 connector options ................3 memory, clock speed, and Ethernet options ..............3 O options connectors ............................3 P peripheral boards connection to master ....95, 96 power from BL2500 ..........89 RabbitNet power-supply connections .........................89 pinout BL2600 headers .................16 108 Ethernet port ......................28 power management ...............87 power supply .........................87 battery backup ...................88 connections ........................10 RabbitNet peripheral boards . 89 switching voltage regulator 87 Program Mode .......................34 programming flash vs. RAM ...................39 programming cable ..............4 programming port ..............27 programming cable .................4 connections ........................10 PROG connector ...............34 switching between Program Mode and Run Mode ....34 programming port .................27 PWM outputs ........................20 jumper configuration .........20 R Rabbit 3000 parallel ports ......................85 RabbitNet Ethernet cables to connect peripheral boards ........95, 96 function calls rn_comm_status ...........103 rn_device .......................98 rn_echo ..........................99 rn_enable_wdt .............102 rn_find ...........................99 rn_hitwd .......................102 rn_init ............................98 rn_read .........................100 rn_reset ........................101 rn_rst_status .................103 rn_sw_wdt ...................101 rn_write .......................100 general description ............95 peripheral boards ...............96 A/D converter ................96 D/A converter ................96 digital I/O ......................96 display/keypad interface 96 relay card .......................96 physical implementation ...97 real-time clock how to set ..........................47 reset hardware ............................11 RS-232 ..................................25 RS-485 ..................................25 RS-485 network ....................26 termination and bias resistors 26 Run Mode ..............................34 S sample programs ...................42 A/D converter AD_CAL_ALL.C ..........30 AD_CALDIFF_CH.C ...30 AD_RD_DIFF.C ...........44 AD_RD_MA.C ..............44 AD_RD_SE_BIPOLAR.C 45 AD_RD_SE_UNIPOLAR.C ........................45 AD_RDVOLT_ALL.C ..30 ADC_CAL_DIFF.C ......44 ADC_CAL_MA.C ..32, 44 ADC_CAL_SE_BIPOLAR.C ........................44 ADC_CAL_SE_UNIPOLAR.C ........................44 ADC_RD_CALDATA.C .. 44 BOARD_ID.C ...................42 D/A converter DAC_CAL_MA.C ........45 DAC_CAL_VOLTS.C ..45 DAC_MA_ASYNC.C ...45 DAC_MA_SYNC.C ......45 DAC_RD_CALDATA.C .. 45 DAC_VOLT_ASYNC.C ... 45 DAC_VOLT_SYNC.C ..46 digital I/O DIGIN_BANK.C ...........42 DIGIN.C ........................42 DIGOUT_BANK.C .......42 DIGOUT.C ....................42 HIGH_CURRENT_IO.C .. 43 PWM.C ..........................43 how to set IP address .........73 NAND flash NFLASH_DUMP.C ......46 NFLASH_ERASE.C .....47 NFLASH_INSPECT.C ..46 NFLASH_LOG.C ..........46 PONG.C ............................14 real-time clock RTC_TEST.C ................47 SBC BL2600 SETRTCKB.C .............. 47 serial communication MASTER.C ................... 44 PUTS.C ......................... 43 SIMPLE3WIRE.C ........ 43 SIMPLE5WIRE.C ........ 43 SLAVE.C ...................... 44 SF1000 serial flash card FLASH_PATTERN_INSPECT.C .................... 46 SFLASH_TEST.C ........ 46 TCP/IP ........................ 47, 73 PINGME.C .................... 75 SMTP.C ........................ 76 SSI.C ............................. 76 TELNET.C .................... 76 serial communication ............ 25 flow control ....................... 57 function calls ser485Rx ....................... 58 ser485Tx ........................ 58 serCflowcontrolOff ....... 57 serCflowcontrolOn ........ 57 serMode ......................... 57 programming port ............. 27 RS-232 description ........... 25 RS-485 description ........... 25 RS-485 network ................ 26 RS-485 termination and bias resistors ......................... 26 serial ports Ethernet port ..................... 28 setup ...................................... 10 power supply connections . 10 software ................................... 5 libraries ............................. 47 BL2600 ......................... 47 BL26xx.LIB .................. 47 NAND flash .................. 70 PACKET.LIB ................ 57 RN_CFG_BL26.LIB ..... 47 RNET.LIB ..................... 98 RS232.LIB .................... 57 TCP/IP ........................... 47 NAND flash drivers .......... 70 sample programs ............... 42 PONG.C ........................ 14 specifications BL2600 electrical ........................ 79 exclusion zone ............... 80 header footprint ............. 81 headers .......................... 81 relative pin 1 locations .. 81 User’s Manual temperature ................... 79 dimensions (BL2600 main board) ............................ 78 spectrum spreader settings .............................. 35 status byte ........................... 104 subsystems ............................ 15 T TCP/IP connections .............. 71 10Base-T Ethernet card .... 71 additional resources .......... 76 Ethernet hub ...................... 71 steps .................................. 71 Tool Kit ................................... 4 AC adapter .......................... 4 DC power supply ................ 4 Demonstration Board .......... 4 Dynamic C software ........... 4 programming cable ............. 4 software ............................... 4 User’s Manual ..................... 4 wire assembly ..................... 4 U user block function calls readUserBlock ............... 36 writeUserBlock ............. 36 109 110 SBC BL2600