FR2902955A1 - COMMUNICATION DEVICE BETWEEN SLAVED MODULES OF A TELECOMMUNICATION NETWORK - Google Patents

Abstract

Communication device (1A) of a telecommunication network (10), able to be connected, by a serial type link, to a first slave module (2A, 1), and, by an Ethernet type connection, to less a second communication device (1B) and a master module (8), said communication device comprising serial-Ethernet conversion means, characterized in that it comprises a memory (5A, 6A) able to store data transmitted by said first slave module and / or by said at least one second communication device, said transmitted data being exchanged independently of said master module (8).

Description

The subject of the present invention is a device and a method for

  communication between slave modules of a telecommunication network. In a telecommunication network using a master-slave protocol, the communication between the modules of the network is managed by a master module, which initiates communications with slave modules. The slave modules are not able to exchange data between them without passing through the master module. There are multi-master protocols that allow the coexistence of several master modules on the network. However, master modules do not usually exchange data with each other. The MODBUS protocol is a master-slave protocol based on a request-response system. This protocol defines the structure of the messages and their mode of exchange. It is implanted in the layer 7 (Application) of the ISO model (Open Systems Interconnection). The MODBUS protocol is used on serial links, for example of the RS232, RS285 or optical fiber type, and can be implemented in two forms, RTU (Remote Terminal Unit) and ASCII (American Standard Code for Information Interchange). With the MODBUS / RTU protocol, all the data is exchanged in binary, and, with the MODBUS / ASCII protocol, the data is exchanged in ASCII form. One of the recent evolutions of the MODBUS protocol is the implementation of this protocol on the Ethernet network. This new protocol, called the MODBUS / TCP protocol, operates similarly to the MODBUS protocol, uses the same function codes (read / write) and an equivalent frame format. The RTU frame data is encapsulated in the Ethernet frame at the Transmission Control Protocol / Internet Protocol (TCP / IP) TCP layer. The MODBUS / TCP protocol retains the master-slave concept and the request-response architecture. For a user, the MODBUS protocol has the advantage of being simple to implement, since it is sufficient to know the number of the slave module and the address of the data to be recovered. However, the master-slave structure is a limit to a more dynamic and efficient use of data exchanges. The object of the present invention is to propose a device and a method 10 for communication between slave modules of a telecommunications network using a master-slave protocol, for example the MODBUS protocol. For this purpose, the subject of the invention is a communication device of a telecommunication network, capable of being connected, by a serial type link, to a first slave module, and, by an Ethernet type connection, to at least one second communication device and to a master module, said communication device comprising serial-Ethernet conversion means, characterized in that it comprises a memory capable of storing data transmitted by said first slave module and / or by said at least one second communication device, said transmitted data being exchanged independently of said master module. Advantageously, a communication between said first communication device and said first slave module uses the MODBUS protocol.

  Preferably, a communication between said first communication device and said at least one second communication device uses the MODBUS / TCP protocol. According to one embodiment of the invention, a communication between said first communication device and said at least one second communication device is performed by sending a broadcast message on the Ethernet link, by said first communication device. . The subject of the invention is also a method of communication between a first slave module of a telecommunication network and at least a second slave module of said telecommunication network, said telecommunication network comprising a master module, said first slave module being connected to a first communication device of said telecommunication network, said at least one second slave module being connected to at least one second communication device of said telecommunication network, said first and at least one second communication devices being connected together, said method comprising the steps of: a) receiving and storing in said first communication device data to be transmitted from said first slave module to said second slave module, b) transmitting from said first communication device to said at least one second communication device said data to be transmitted stored in step a), c) storing in said at least one second communication device said data to be transmitted received in step b), and d) transmitting from said at least one second communication device to said at least one second slave module said data to be transmitted stored in step c), e) the steps a) to d) being performed independently of the master module. Advantageously, step a) comprises the sub-steps of: f) transmitting from said first communication device to said first slave module a data request to be transmitted, and, g) in said first communication device, storing as 10 data to transmit the data received from the first slave module in response to said request. According to one embodiment of the invention, step b) is performed automatically at predetermined time intervals. According to one embodiment of the invention, step b) is performed when new data to be transmitted are stored in said first communication device. The invention will be better understood, and other objects, details, features and advantages thereof will become more clearly apparent from the following detailed explanatory description of an embodiment of the invention given by way of purely illustrative and non-limiting example, with reference to the attached schematic drawing. In these drawings: FIG. 1 is a simplified schematic view of a telecommunication network comprising three communication devices 25 according to one embodiment of the invention; and FIG. 2 is a block diagram showing the steps of a communication method between slave modules of the telecommunications network of FIG. 1.

  FIG. 1 shows a telecommunication network 10 comprising a master module 8 and three communication devices 1A, 1B and 1C. It will be noted that the number of communication devices 1 is not limiting. The communication device 1A will now be described in more detail. The device 1A is connected by a cable 11 to a sub-network 10A of the network 10, via a communication port 3 of the serial link type. The serial link is for example of the RS232, RS485 or optical fiber type and uses the MODBUS protocol (ASCII or RTU). Subnet 10A comprises three slave modules 2A, 1, 2A, 2 and 2A, 3. Note that the number of slave modules 2A is not limiting. The slave modules 2A.1, 2A, 2 and 2A, 3 use the MODBUS protocol. The device 1A is connected by a cable 12 to an Ethernet network, via a communication port 4 of the Ethernet link type. The Ethernet network is represented in FIG. 1 by a communication bus 13.

  The Ethernet link uses the MODBUS / TCP protocol. It will be noted that the support of the Ethernet link may be of the radio, cable or optical fiber type, for example. The Ethernet link allows broadcast broadcast message transmission using, for example, User Datagram Protocol (UDP).

  A broadcast message, or broadcast message, is a message sent to the attention of several devices. In the example, a broadcast message sent by the communication device 1 A is sent to the attention of the communication devices 1B and 1c. This type of message does not require a response, the management of a non-reception being the responsibility of the recipient. The device 1 A comprises means of conversion between communications using the MODBUS protocol and communications using the MODBUS / TCP protocol. In other words, the device 1A performs a gateway function between the MODBUS / TCP communications of the Ethernet link and the MODBUS communications of the serial link.

  The devices 1 B and 1 c are identical to the device 1 A. The device 1 B is connected by a cable 14 to a sub-network 10B of the network 10, through a communication port 3 of the serial link type. The subnet 10B comprises four slave modules 2B, 1, 213,2, 213,3 and 2B, 4 using the MODBUS protocol. The device 113 is connected by a cable 15 to the Ethernet network, via a communication port 4 of the Ethernet link type. The device 1c is connected by a cable 16 to a sub-network 10c of the network 10, via a communication port 3 of the serial link type. The sub-network 10c comprises two slave modules 2c, 1 and 2c, 2 using the MODBUS protocol. The device 1c is connected by a cable 17 to the Ethernet network, via a communication port 4 of the Ethernet link type. The steps of the communication method between slave modules 2 belonging to different subnets will now be described.

  By way of example, consider a data transmission from the slave module 2A, 1 to the slave module 2B, 1 and a data transmission from the slave module 2A, 2 to the slave module 2c, 1. It is obvious that this method allows the transmission of data from any set of slave modules 2 to any set of slave modules 2, each data transmission being performed between two slave modules 2 belonging to sub-modules. different networks 10A, 10B, 10c. It will be noted that this method makes it possible to transmit data from a slave module 2 to a plurality of slave modules 2. This method also makes it possible to simultaneously carry out several data transmissions between several pairs of slave modules 2, respectively. This method is executed independently of the master module 8, that is to say without intervention of the master module 8, which may be in operation for other tasks. The synchronism of the master module 8, in particular, is not used. In step 100, the device 1A sends a data request to be transmitted to the slave module 2A, 1. In other words, the device lA asks the slave module 2A, 1 to communicate to it the data it wishes to transmit to another slave module, for example the slave module 2B, 1. Similarly, the device 1A sends a data request to be transmitted to each of the other slave modules of the subnet 10A, that is to say the slave modules 2A, 2 and 2A, 3. In step 101, the device 1A builds a local data table 6A from the responses sent by the slave modules 2A, 1, 2A, 2 and 2A, 3 in response to the requests and from a configuration table 5A of the device 1 A.

  The data table 6A, which is stored in the device 1A, contains in particular the data to be transmitted from the slave module 2A, 1 to the slave module 2B, 1 and the data to be transmitted from the slave module 2A, 2 to the slave module 2c, 1 At step 102, the device 1A transmits a broadcast message on the Ethernet network, the broadcast message containing all or part of the data table 6A. Step 102 can be performed automatically at predefined time intervals. Alternatively, step 102 may be performed when the contents of data table 6A are changed. In step 103, the broadcast message is received by the device 1B and the device 1c. The device 1B (respectively the device 1c) compares, using a decision system 7B of the device 1B (respectively of the device 1c), the received data and the data stored in the configuration table 5B of the device 1B (respectively of the device 1 c). The device 1B (respectively the device 1c) in particular checks the consistency of writing and reading data so as not to write on data defined in reading. When an association is possible between the received data and the data of the table 5B of the device 1B (respectively of the device 1c), the data are written in the local data table 6B of the device 1B (respectively of the device 1c). In step 104, the data stored in the table 613 of the device 1B are transmitted by the device 1 B to the slave module 2B, 1, through the serial communication port 3 of the device 1B and the MODBUS protocol. Similarly, the data stored in the table 6c of the device 1c are transmitted by the device 1c to the slave module 2c, 1, through the serial communication port 3 of the device 1c and the MODBUS protocol.

  The device 1A also allows data transmission from the slave module 2A, I to the slave module 2A, 2. Step 100 is similar to what has been described previously.

  In step 101, the data table 6A, which is stored in the device 1A, notably contains the data to be transmitted from the slave module 2A, 1 to the slave module 2A, 2. Steps 102 and 103 are deleted.

  In step 104, the data stored in the table 6A of the device 1A are transmitted by the device 1A to the slave module 2A, 2, through the serial communication port 3 of the device 1A and the MODBUS protocol. Thus, data can be exchanged between slave modules 2 without any intervention of the master module 8 of the network 10, which makes it possible to increase the speed of transmission of the data. Each communication device 1 allows several slaves 2 to which it is connected to exchange data with each other without requiring the presence of the master module 8 on the network 10.

  In other words, each communication device 1 behaves like a gateway having an additional function of communication between two slave modules 2. The installation cost of the network 10 can be reduced, in particular because it is no longer necessary to have a master module.

  The device 1 also has the advantage of not modifying the operation of the network 10, that is to say the communications between the master module 8 and the slave modules 2. With respect to the master module 8, the device 1 is has as a slave module. The local data tables 6A, 6B, 6c are accessible by the master module 8. Similarly, the data coming from the slave modules 2 are accessible to the master module 8 via the corresponding communication device 1 which in this case ensures a standard gateway function, namely the conversion of MODBUS / TCP protocol to MODBUS on serial line (ASCII or RTU). The transmission rate of the broadcast messages can be set independently for each communication device 1 A, 1 B and 1 c.

  In other words, a communication device 1A, 1B or 1C can frequently transmit broadcast messages while another communication device 1A, 113 or 1C rarely transmits. Each communication device 1A, 1B or 1C may be configured to initialize the data of its data table 6A, 6B, 6c when no message is received for a predefined time. This function makes it possible to put the device 1 in degraded mode when the communication between slave modules 2 connected to it is suspended. It should be noted that this method is well suited to a network using the MODBUS protocol, since it makes it possible to maintain the flexibility of the MODBUS protocol for the user. However, the communication method could be used on a network using another master-slave protocol. In this case, the communication devices must comprise links using the corresponding protocol.

Although the invention has been described in connection with a particular embodiment, it is quite obvious that it is in no way limited thereto and that it comprises all the technical equivalents of the means described as well as their combinations if these These are within the scope of the invention. 25

Claims (8)

  1. A communication device (1A) of a telecommunication network (10), connectable, by a serial type link, to a first slave module (2A ,,), and, by an Ethernet type connection, at least one second communication device (1 B) and a master module (8), said communication device comprising serial-Ethernet conversion means, characterized in that it comprises a memory (5A, 6A) adapted to storing data transmitted by said first slave module and / or by said at least one second communication device, said transmitted data being exchanged independently of said master module (8).   2. Device according to claim 1, characterized in that a communication between said first communication device (1A) and said first slave module (2A, 1) uses the MODBUS protocol.   3. Device according to claim 1 or 2, characterized in that a communication between said first communication device (1A) and said at least one second communication device (1B) uses the MODBUS / TCP protocol.   4. Device according to any one of claims 1 to 3, characterized in that a communication between said first communication device (1A) and said at least one second communication device (1B) is achieved by the transmission of a broadcast message on the Ethernet link, by said first communication device. 11   5. A method of communication between a first slave module (2A, 1) of a telecommunication network (10) and at least one second slave module (2B, 1) of said telecommunication network, said telecommunication network comprising a master module ( 8), said first slave module being connected to a first communication device (1A) of said telecommunications network, said at least one second slave module being connected to at least one second communication device (1 B) of said telecommunications network, said first and at least one second communication devices being connected to each other, said method comprising the steps of: a) receiving and storing in said first communication device data to be transmitted from said first slave module to said at least one second slave module, b) transmitting from said first communication device to said at least one u n second communication device said data to be transmitted stored in step a), c) storing in said at least one second communication device said data to be transmitted received in step b), and d) transmitting from said at least one second communication device to said at least one second slave module said data to be transmitted stored in step c), e) the steps a) to d) being performed independently of the master module (8).   The method according to claim 5, characterized in that step a) comprises the substeps of: f) transmitting from said first communication device (1A) to said first slave module (2A, 1) a data request to be transmitted, and, g) in said first communication device, storing as data to be transmitted the data received from the first slave module in response to said request.   7. The method of claim 5 or 6, characterized in that step b) is performed automatically at predetermined time intervals.   8. The method of claim 5 or 6, characterized in that step b) 1 o is performed when new data to be transmitted are stored in said first communication device.