Benutzeranleitung / Produktwartung A2400 des Produzenten Omega
Zur Seite of 68
omega.com e-mail: info@omega.com Fo r la te st p ro du ct m an ua ls : omegamanual.info U ser ’ s Guide A 2 4 0 0 S e r i e s R ad i o M od e m M od u le Shop online at MADE IN.
Servicing Nor th America: U.S.A.: One Omega Drive, Box 4047 ISO 9001 Certified Stamford, CT 06907-0047 Tel: (203) 359-1660 FAX: (203) 359-7700 e-mail: info@omega.com Canada: 976 Bergar Laval (Quebec) H7L 5A1, Canada Tel: (514) 856-6928 FAX: (514) 856-6886 e-mail: info@omega.
A2400 USERS MANUAL REVISED: 4/17/95 OMEGA ENGINEERING ONE OMEGA DRIVE P. O. BOX 4047 STAMFORD, CT 06907 PHONE: 1-800-DAS-IEEE FAX: 203-359-7990 e-mail: das@omega.
TABLE OF CONTENTS CHAPTER 1 Getting Started Quick Hook-Up 1-3 Default Mode 1-4 CHAPTER 2 Functional Description Block Diagram 2-1 CHAPTER 3 Communications RS-485 3-2 Multi-party Connection 3-3 RS-485 .
Chapter 1 Getting Started Introduction This manual describes the function and application of the Radio Modem Interface Module (A2400). The A2400 provides an intelligent interface between radio modems available from many manufacturers and devices designed to operate on a bi-directional RS-485 serial bus.
Getting Started 1 -2 A2400 is to control the slave transmitter to allow multiple slave sites. Figure 1.1 System Overview. Leased Lines This manual has been written with emphasis on radio modems. However, the A2400’s may be used just as effectively with leased telephone lines.
Getting Started 1 -3 Getting Started To get your A2400 up and running for an initial check-out, connect the unit to a power supply and terminal as shown in Figure 1.2. The power supply can be any dc source from 10 to 30 volts, capable of 1 Watt of power.
Getting Started 1 -4 This message is terminated with a carriage return. If the response message cannot be obtained, re-check all the wiring, making sure that the proper power is on the A2400 connector and that the DEFAULT* line is shorted to the GND pin.
Getting Started 1 -5 values (NULL, CR, $, #, {, }). A dummy address must be included in every command for proper responses. Setup information in an A2400 may be changed at will with the SetUp (SU) command. Baud rates and parity setups may be changed without affecting the Default values of 300 baud and no parity.
Chapter 2 Functional Description Block Diagram The A2400 is an RS-232/RS-485 converter specifically designed to inter- face D series RS-485 modules to radio modems. To this end the A2400 provides three functions: 1) Perform the RS-232 to RS-485 electrical conversion.
Functional Description 2-2 EEPROM MICRO- PRCESSOR +5 5.6K DO0/RTS RX TX CTS RTS +5V UART RX TX DEFAULT Figure 2.1 A2400 Block Diagram..
Functional Description 2-3 Pinout 1) TRANSMIT This is the RS-232 Transmit output from the A2400. This pin is normally connected to the Receive input of a modem. This output is also used to connect to a terminal or computer to configure the A2400 2) RECEIVE This is the RS-232 Receive input of the A2400.
Functional Description 2-4 bus. This bus connects to multidrop RS-485 devices such as D series modules. 8) (G)DATA- This is the negative polarity of the differential RS-485 bus. 9) (R)V+ A2400 power connection. The A2400 operates on 10 to 30 volts dc.
Functional Description 2-5 reaching the RS-485 bus. The first operation performed on the modem data is to check for noise and framing errors. If either condition exists, the bad character is re-formatted as a null character (ASCII $00).
Functional Description 2-6 addressed command and it responds back with information on the bus. The A2400 receives this information and places it in a buffer that can hold up to 96 characters. The parity of received characters is ignored. As soon as a character is received, the A2400 starts a timing sequence to control the modem transmitter.
Functional Description 2-7 T1 As soon as the A2400 detects a character in the RS-485 receive buffer, time delay T1 is activated. This is a dead time to allow the host to prepare for the receipt of a message. This is particularly important when a simplex connec- tion is used, where the send and receive data is transmitted on the same frequency.
Chapter 3 Communications Introduction The A2400 modules have been carefully designed to be easy to interface to all radio modems and many leased-line modems.
Communication 3-2 improper command prompt or address is transmitted. The table below lists the timeout specification for each command assuming that delay times T1, T2, T3 = 0: Table 3.
Communication 3-3.
Communication 3-4 RS-485 Multidrop System Figure 3.1 illustrates the wiring required for multiple-module RS-485 system. Notice that every module has a direct connection to the A2400. Any number of modules may be unplugged without affecting the remaining modules.
Communication 3-5 becomes an important consideration. The GND wire is used both as a power connection and the common reference for the transmission line receivers in the modules. Voltage drops in the GND leads appear as a common-mode voltage to the receivers.
Chapter 4 A2400 Command Set The A2400 operates with a simple command/response protocol to control all module functions. A command must be transmitted to the A2400 by the host computer or terminal before the A2400 will respond with useful data. A module can never initiate a communications sequence.
Command Set 4-2 All commands must be terminated by a carriage return character (ASCII $0D). In all command examples in this text the carriage return is either implied or denoted by the symbol ‘CR’. Data Structure Many commands require additional data values to complete the command definition as shown in the example commands in Table 4.
Command Set 4-3 A command/response sequence is not complete until a valid response is received. The host may not initiate a new command until the response from a previous command is complete. Failure to observe this rule will result in communications collisions.
Command Set 4-4 interprets a command, it looks for the two extra characters and assumes that it is a checksum. If the checksum is not present, the module will perform the command normally. If the two extra characters are present, the module will calculate the checksum for the message.
Command Set 4-5 Example: Append a checksum to the command $1WE Characters: $ 1 W E ASCII hex values: 24 31 57 45 Sum (hex addition) 24 + 31 + 57 + 45 = F1 The checksum is F1 (hex).
Command Set 4-6 Each A2400 user command is described in detail following Table 4.1. All of the commands are listed in alphabetical order according to command nomenclature. Table 4.1 A2400 Command Set Command and Definition Typical Typical Command Response Message Message ($ prompt) DO Digital Output $1DO01 * RD Read Data $1RD *+99999.
Command Set 4-7 Command Descriptions All the commands may be used with normal addressing or Extended Addressing unless otherwise noted. Commands that are exclusive to the Extended Address mode are noted near the right hand margin.
Command Set 4-8 To turn the output off you could use the command: Command: $1DO00 Response: * Command: #1DO00 Response: *1DO004E Digital output 0 shares the connector pin with the Alternate RTS. Bit 3 of byte 4 of the SetUp command is used to configure this pin as either digital output or RTS function.
Command Set 4-9 Identification (ID) The IDentification command allows the user to write a message into the nonvolatile memory which may be read back at a later time with the Read IDentification (RID) command. It serves only as a convenience to the user and has no affect on the module operation.
Command Set 4-10 Open Channel (OC) (Extended) The Open Channel (CC) command is used to open the communications data channel in Extended Address mode. The open channel will allow serial communications data to flow from the A2400’s RS-232 port to a string of RS- 485 devices.
Command Set 4-11 In this example the ‘30’ and ‘31’ are the hex ASCII codes for the characters ‘0’ and ‘1’ respectively. The Extended Address is ‘01’. Read Identification (RID) The Read IDentification command reads back the user data stored by the IDentification (ID) command.
Command Set 4-12 Command: #1RR Response: *1RRFF Read Setup (RS or RSU) The read setup command reads back the setup information stored in the A2400’s EEPROM with the SetUp (SU) command. The response to the RS or RSU command is four bytes of information formatted as eight hex characters.
Command Set 4-13 Read Time Delay 1 (RT1) The Read Time 1 command reads back the time value stored in EEPROM by T1 command. Command: $1RT1 Response: *+00100.00 Command: #1RT1 Response: *1RT1+00100.00DC Read Time Delay 2 (RT2) The Read Time 2 command reads back the time value stored in EEPROM by the T2 command.
Command Set 4-14 The SetUp command requires an argument of eight hexadecimal digits to describe four bytes of setup information. Command: $1SU31070007 Response: * Command: #1SU31070007 Response: *1SU3107000795 Set Time Delay 1 (T1) T1 is a programmable time delay used to control the RTS output.
Command Set 4-15 T2 is specified in units of milliseconds with a range of 0 to 2000ms. The time data must be formatted as a plus sign, five decimal digits, a decimal point, and two additional digits: Command: $1T2+00350.00 (Set T2 to 350 ms.) Response: * Command: #1T2+00350.
Command Set 4-16 Short Prompt (SP) The Short Prompt command allows the user to specify a desired short prompt ASCII character. A two character hexadecimal value is used to define the desired ASCII character prompt. Note: Short Prompt command may be sent to the module in either normal addressing or Extended Addressing mode.
Command Set 4-17 Command: }01WE Response: *01WE27 If a module is write enabled and the execution of a command results in an error message other than WRITE PROTECTED, the module will remain write enabled until a command is successfully completed resulting in an ‘*’ prompt.
Command Set 4-18 COMMAND ERROR This error occurs when a command is not recognized by the module. Often this error results when a command is sent with lowercase letters. All valid commands use uppercase characters. PARITY ERROR A parity error can only occur if the module is setup with parity on.
Chapter 5 Setup Information/SetUp Command The A2400 features a wide choice of user configurable options which gives them the flexibility to operate on virtually any radio or leased-line modem. The user options include a choice of baud rate, parity, address, and many other parameters.
SetUp Command 5-2 A typical SetUp command would look like: $1SU31070102 Notice that each byte is represented by its two-character ASCII equivalent. In this example, byte 1 is described by the ASCII characters ‘31’ which is the equivalent of binary 0011 0001 (31 hex).
SetUp Command 5-3 to communicate with a module with an unknown address is with the Default Mode. The most significant bit of byte 1 (bit 7) must be set to ‘0’.
SetUp Command 5-4 Byte 2 Byte 2 is used to configure some of the characteristics of the communica- tions channel; linefeeds, parity, and baud rate. Linefeeds The most significant bit of byte 2 (bit 7) controls linefeed generation by the module. This option can be useful when using the module with a dumb terminal.
SetUp Command 5-5 changed, a module reset must occur. A reset is performed by sending a Remote Reset (RR) command or powering down. This extra level of write protection is necessary to ensure that communications to the module is not accidentally lost.
SetUp Command 5-6 Command: $1RR Response: * Up to this point all communications have been sent at 300 baud. The module will not respond to any further communications at 300 baud because it is now running at 9600 baud. At this point the host computer or terminal must be set to 9600 baud to continue operation.
SetUp Command 5-7 Byte 3 This byte contains determines which addressing mode will be used. The default value for this byte is ‘00’. Normal addressing The normal addressing mode refers to the D series protocol of using a single ASCII character for a channel address.
Chapter 6 Delay Time Programming Each A2400 contains user-programmable delays to properly sequence the transmission of data from a remote radio modem to a host computer. The delays are required to sequence an external transmit enable signal required by most radio modems.
Delay Time Programming 6-2 Figure 6.1 Programmable delay times. As described in figure 6.1 the communications sequence assumes a host computer communicating with a module on the RS-485 bus through the A2400.
Delay Time Programming 6-3 the data over the RS-485 bus. This data is normally command data being sent to a module on the bus. When the RS-232 command data is complete, the A2400 immediately turns its RS-485 transceiver back to receive mode and monitors the RS-485 bus.
Delay Time Programming 6-4 Command: $1T3+00050.00 (set T3 to 50 ms.) Response: * Time may be set to 1 ms. resolution. The T1, T2, T3 commands are write-protected and must be preceded by a Write Enable (WE) command. The delay times are stored in nonvolatile memory.
Chapter 7 Power Supply A2400 modules may be powered with an unregulated +10 to +30Vdc. Power-supply ripple must be limited to 5V peak-to-peak, and the instanta- neous ripple voltage must be maintained between the 10 and 30 volt limits at all times.
Chapter 8 Troubleshooting Symptom: RS-232 Module is not responding to commands 1 Using a voltmeter, measure the power supply voltage at the +Vs and GND terminals to verify the power supply voltage is between +10 and +30Vdc. 2 Verify using an ohmmeter that there are no breaks in the communica- tions data lines.
Chapter 9 Extended Addressing The A2400 may be configured to a special command format called Extended Addressing. This mode uses a different prompt, either ‘{‘ or ‘}’ to distinguish it from the regular command syntax. The major difference in syntax for the Extended Addressing mode is that it uses a two-character address.
Extended Addressing 9-2 Figure 7.1 Typical system overview..
Extended Addressing 9-3 When the system is initially powered up, the A2400’s are set to the Close Channel condition. This means that no data received by the radio modems will pass to the RS-485 bus at either site.
Extended Addressing 9-4 Figure 7.1 shows a very simple system but the same addressing methodmay be used to construct very large systems. Each RS-485 string may handle up to 122 addresses, and up to 14884 A2400’s may have unique addresses.
Extended Addressing 9-5 All commands that are available with single-byte addressing may be accessed with Extended Addressing, and vice-versa; the only exceptions being the OC and CC commands, which can be used only with Extended Addressing.
Extended Addressing 9-6 This command will close the channel at A2400 #01 and open the channel at A2400 #02. This is the quickest method of opening and closing A2400 channels. It also offers the least amount of data security. A2400 #01 was closed solely upon detecting the ‘{‘ character.
Extended Addressing 9-7 To explicitly close the channel of A2400 #01: Command: {01CC Response: * The response message is a confirmation that the channel has been closed.
Chapter 10 Transparent Mode The A2400 is an RS-232/RS-485 converter designed to provide interface virtually any product to a radio and leased telephone line modems. In normal operation the A2400 is configured to work on the D series protocol, but it may be configured to a special communications mode called the transparent mode.
Transparent Mode 10-2 The following examples 1 through 4 illustrate the application of the A2400 in the extended mode of operation. The A2400 in transparent mode allows equipment from various sources to be added to a network of D series modules. However the following rules must apply: 1.
Transparent Mode 10-3 Example 2. A2400 networking several RS-232 devices to a host com- puter. Figure 10.2 A2400 networking several RS-232 devices to a host computer.
Transparent Mode 10-4 Example 3. A2400 interfacing a device with a string of modules. Figure 10.3 A2400 interfacing a laboratory instrument with modules.
Transparent Mode 10-5 Example 4. A2400 interfacing several instruments with a string of modules..
Transparent Mode 10-6 Figure 10.5 Adding secondary control using A2400 modules..
Transparent Mode 10-7 Figure 10.5 shows an application where the user was able to add a back-up or secondary control supervision using the A2400 modules. The original installation of the flow computers and PLC’s were controlled by the control station using Modbus protocol with RS-485.
WARRANTY / DISCLAIMER OMEGA ENGINEERING, INC. warrants this unit to be free of defects in materials and workmanship for a period of 13 months from date of purchase. OMEGA’s WARRANTY adds an additional one (1) month grace period to the normal one (1) year product warranty to cover handling and shipping time.
Where Do I Find Ever ything I Need for Pr ocess Measurement and Contr ol? OM EGA…Of Course! Shop online at omega.com TEMPERA TURE 䡺 ⻬ Thermocouple, RTD & Thermistor Probes, Connectors, Panel.
Ein wichtiger Punkt beim Kauf des Geräts Omega A2400 (oder sogar vor seinem Kauf) ist das durchlesen seiner Bedienungsanleitung. Dies sollten wir wegen ein paar einfacher Gründe machen:
Wenn Sie Omega A2400 noch nicht gekauft haben, ist jetzt ein guter Moment, um sich mit den grundliegenden Daten des Produkts bekannt zu machen. Schauen Sie zuerst die ersten Seiten der Anleitung durch, die Sie oben finden. Dort finden Sie die wichtigsten technischen Daten für Omega A2400 - auf diese Weise prüfen Sie, ob das Gerät Ihren Wünschen entspricht. Wenn Sie tiefer in die Benutzeranleitung von Omega A2400 reinschauen, lernen Sie alle zugänglichen Produktfunktionen kennen, sowie erhalten Informationen über die Nutzung. Die Informationen, die Sie über Omega A2400 erhalten, werden Ihnen bestimmt bei der Kaufentscheidung helfen.
Wenn Sie aber schon Omega A2400 besitzen, und noch keine Gelegenheit dazu hatten, die Bedienungsanleitung zu lesen, sollten Sie es aufgrund der oben beschriebenen Gründe machen. Sie erfahren dann, ob Sie die zugänglichen Funktionen richtig genutzt haben, aber auch, ob Sie keine Fehler begangen haben, die den Nutzungszeitraum von Omega A2400 verkürzen könnten.
Jedoch ist die eine der wichtigsten Rollen, die eine Bedienungsanleitung für den Nutzer spielt, die Hilfe bei der Lösung von Problemen mit Omega A2400. Sie finden dort fast immer Troubleshooting, also die am häufigsten auftauchenden Störungen und Mängel bei Omega A2400 gemeinsam mit Hinweisen bezüglich der Arten ihrer Lösung. Sogar wenn es Ihnen nicht gelingen sollte das Problem alleine zu bewältigen, die Anleitung zeigt Ihnen die weitere Vorgehensweise – den Kontakt zur Kundenberatung oder dem naheliegenden Service.