DE10037151C2 - Network node in a ring bus and method for its operation - Google Patents

Description

The invention relates to a network node in a ring bus and a method for operating the network node according to the preamble of claims 1 and 8.

Bus systems for data processing systems are well known. Here has cross-linking in the form of a ring has proven to be particularly advantageous. The so-called MOST bus has established itself in the automotive industry. The MOST bus is an optical bus with a ring structure.

WO 98/39861 A1 describes a system for the bidirectional optical transmission of Diffuse light information known. The data is transferred between several electronic components with different Transmission links. There is a sheathing for the transmission links provided so that there is no interference between the data transmission he follows.

From EP-A-0 320 688 is a reflection transmitting and receiving device for a bidirectional optical fiber communication system known. This points preferably a laser, which acts as a light source only at one end of the Optical fiber is arranged. Behind one the optical fiber semi-transparent mirror of an electrically controllable, Integrated optical Fabry-Perot resonator is an optoelectronic converter intended.  

From DE-A-198 04 841 is an arrangement for generating a physical Control signal for transmitter control and / or receiver control in one bidirectional data stream of a bus line known. Here is a passive one Working resistance exists. Parallel to the passive load resistance is a arranged electronic switch, which is an electronic timer is acted upon.

From DE 198 32 039 A1 a node of a point-to-multipoint network is the includes a headquarters, known. Signals are sent from the head office at two nodes are transmitted, the two starting nodes being connected in series several nodes are connected to each other.

A node has a detector that selects the signal path from a preferred one Direction detected. As a result, only the preferred direction is monitored. If there is no signal from the preferred direction, the red will be red undante signal channel switched to the main channel.

WO 95/24087 A1 discloses a communication network with several stations. Here it is necessary that from a main center a controller for the inbe drive or to switch off the stations. The knots ar so far not self-sufficient.

DE 42 42 438 A1 describes a method for utilizing the redundancy in data ring known in double ring topology. This procedure also uses a Master station uses a centralized access method. The knots are working not self-sufficient, but controlled by a head unit. There is also a quit Tung telegram procedure implemented to control the individual sub-centers s.

From EP 0 170 336 A2 there is an arrangement for information transfer with reconfiguration ration known. Acknowledgment reports are sent to the individual sub to connect stations with each other.

In a ring structure known per se, as exemplified in FIG. 1, different network nodes K1, K0, K2 are present. These network nodes K1, K0, K2 are connected to one another as a ring structure. The result of this is that node K0 is connected to node K1 via the lines of bus B. The node K1 is in turn connected via the bus B to the node K0, which in turn is connected to the node K2. With a ring structure, it is a prerequisite that the data is routed in a ring, ie continuously in one direction. Therefore, a ring node has two inputs and two outputs, node K0 has inputs K0E1 and K0E2 and outputs K0A1 and K0A2, node K1 has inputs K1E1 and K1E2 and outputs K1A1 and K1A2 and node K2 Inputs K2E1 and K2E2 and outputs K2A1 and K2A2. The input K0E1 of the node K0 is connected to the output K2A1 node K2. The output K0A1 of the node K0 is connected to the input K1E1 of the node K1, etc.

The node K2 and the node K1 are so-called end nodes. d. H. Your Outputs K1A1 and K2A2 are each with their own inputs K1E2 and K2E2 connected. Otherwise bus B would not be a closed ring.

As already shown above, it is always necessary that the bus B as a ring is always closed, otherwise there can be no data between via bus B. the connected nodes are transported.  

The problem is now when the bus B with its ring structure in one of the Connection lines between the outputs K0A1, K0A2, K1A1, K1A2, K2A1, K2A2 and the inputs K0E1, K0E2, K1E1, K1E2, K2E1, K2E2 a Shows damage. Occurs z. B. a break in the connecting line between nodes K0 and K1, no more data will be in the ring via the bus transfer. It is then necessary to analyze the entire bus system to find out and fix the error.

Another difficulty is that bus B is not easily expandable. It bus B must always be terminated in a ring structure, in such a way that an output and an input are connected together.

The object of the invention is to provide a method and a device, which avoids the problems mentioned above and in a surprisingly simple way brings about a solution to the problem.

This object is achieved on the basis of the features of claims 1 and 4. Further Advantageous refinements and developments of the invention result from the the further description and the dependent claims and the associated Figure.

The method according to the invention works as follows:
The inputs of the network nodes are monitored by a detector unit. Furthermore, a switching unit is provided. If the detector unit detects no incoming signals, in particular no data at the respective input, the detector unit controls the switching unit in such a way that it switches the output to the input of the node.

Furthermore, the invention is explained in more detail with reference to FIG. 2, which represents an embodiment of a node according to the invention.

In Fig. 2 the network node K0 is shown in its expanded structure. The network node K0 consists of a network microcomputer μC and a first detector unit D1 and a first switching unit S1 and a second detector unit D2 and a second switching unit S2. The network node K0 has the inputs K0E1 and K0E2, and the outputs K0A1 and K0A2. In normal operation, the data are received via the first input K0E1 of the network node K0 and sent to the network microcomputer µC. This network microcomputer μC takes the data addressed to the network node K0 from the data stream and evaluates it. If data is placed on bus B by network node K0, then the network microcomputer µC also takes over this task and inserts the data into the data stream at free timeslots.

All data is routed through the network node K0, received via it first input K0E1 and sends via its first output K0A1. This Data is routed to the first input of the next network node and there processed and processed as described above.

Furthermore, there is a second input K0E2 and a second output K0A2 available. In this example, these inputs and outputs are only used for Returning the data and closing the ring of the bus B. Die Tasks and the wiring of the first and second inputs and outputs K0A1, K0A2, K0E1, K0E2 can also be interchanged.

If the network node K0 is now the last link in the bus B, the bus B in be concluded in such a way that that exit and that entrance of the network node K0, which is not connected to any other network node are interconnected. In the concrete example is now first output K0A1 and the second input K0E2 of network node K0 subsequent drawings. Therefore, between the first output K0A1 and the second input K0E2 of the network node K0 is laid a line and both are connected. If this were not done, it would be the ring of bus B is not closed and there could be no data in the ring of the B bus.  

In the embodiment according to the invention there is now a first detector D1 and a second detector D2 is arranged. The second detector D2 monitors the Signals which are routed to the network node K0 via the second input K0E2 become. If there are no data signals, i. H. no dates come on the second Input K0E2 of network node K0, so the second detector D2 detects this. In this case, it controls a second switching unit S2, which one Connection between the first output K0A1 of the network node K0 and the second input K0E2 of the network node K0 switches. This has the consequence that the data which the network microcomputer μC gives to bus B and the data, which arrive at the first input K0E1 via the second output K0A2 of the network node K0 are routed into bus B and bus B is functional, if bus B is not terminated correctly. In this way, the second detector D2 always switches an open line via the switching unit S2. Will now be at the network node K0 at its previous one completed side K0A1 and K0E2 another network node connected, the second detector now detects data on the second Input K0E2 of network node K0 and separates via second switching unit S2 the connection between the first output K0A1 and the second input K0E2 of the network node K0 again. The bus B is now over the new connected network nodes, closed in the manner described above.

In this simple way it is possible to expand a ring bus shape.

Another problem that often occurs with ring structures is caused by the Invention solved, as will be described in more detail below.

A first detector D1 is at the first input K0E1 of the network node K0 arranged. This also detects whether data at the first input K0E1 available. If this is not the case, the first detector D1 controls one first switching unit S1 and the first switching unit S1 closes one Connection between the first input K0E1 and the second output  K0A2 of the network node K0. In this way the bus B closed.

If one of the connecting cables between the individual is interrupted Nodes can now be a function of at least part of the bus B be maintained. Is, for example, between the node K0 and the Node K2 has an interruption in the line so the data can are no longer routed from K0 to K2, bus B is interrupted. The Network node K2 sends data to node K0. The node K0 receives this but not because this line is interrupted. Communication between the network node K0 and K1 could, however, continue to occur because of this Connection is in tact. However, since the data in bus B is routed in the ring with the interruption of a single line the entire bus B and the Communication on bus B interrupted.

No data arrives at the first input K0E1 of the network node K0. This the first detector D1 detects and closes via the first switching unit S1 the second output K0A2 and the first input K0E1 together, so that the bus B is closed again and the data on the bus, at least can run between the network nodes K0 and K1.

The node K2 then also no longer receives any data. But he can send own data to node K0, this is received by K0, forwarded via K1, but no longer get back to K2, because how described, the line is interrupted. Since the node K2 now no Receives data, a detector, as described above, the output and interconnect the corresponding input via a switching unit. This now has the consequence that the node K2, since it is the "last" network node in the Bus B is only communicated with itself. The now recognizes this Network microcomputer and carries out a corresponding signaling. hereby it is possible for a service technician to isolate the error in bus B.  

In this way it is now possible to determine at which point, that is between which nodes there must be an error. The nodes K0 and K1 can communicate with each other, node K2 cannot send data and received. As a result, an error must occur between nodes K2 and K0 to be available.

The network structure is both electrical and optical connecting lines. But with optical connections it is necessary that the data which are optically transmitted by electrical be converted into optical signals. That is why there are so-called optocouplers available. However, electrical signal processing takes place within the node. The only consequence of this is that one in front of the detectors D1 and D2 Implementation of optical data transmission in electrical data transmission too has taken place. In addition, transmit diodes must be present, which the convert electrical signals into optical signals. The signals are coupled each electrically, d. H. before optoelectronic implementation.

Claims (4)

1. Network node (K0), which is integrated in a bus (B) with a ring structure, with a first input (K0E1), a first output (K0A1), a second input (K0E2) and a second output (K0A2) for connection to a bus (B) with a network microcomputer (µC), with at the first input (K0E1) of the network node (K0) a first detector (D1) is arranged in the signal path, a first switching unit (S1) between the first input (K0E1) and the second output (K0A2) is arranged, which in response to the control signals of the first detector (D1) second output (K0A2) of the network node (K0) and the first input (K0E1) of the Network node (K0) and at the second input (K0E2) of the network node (K0) in the signal away a second detector (D2) is arranged, a second switching unit (S2) between between the second input (K0E2) and the first output (K0A1), which in response to the control signals of the second detector (D2) the first Output (K0A2) of the network node (K0) and the second input (K0E1) of the network node (K0) connects or disconnects, the first detector (D1) the first input (K0E1) of the network node (K0) on signals coming in via the bus (B1) and the second detector (D2) the second input (K0E2) of the network node (K0) to over the bus (B) incoming signals monitored and the first detector (D1) the first Switching unit (S1) controls such that it the first input (K0E1) and second output (K0A2) of the network node (K0) connects when the first detector (D1) no data signals at the first input for an adjustable period of time (K0E1) detected and the first detector (D1) controls the first switching unit (S1) in such a way that this the first input (K0E1) and the second output (K0A2) of the network node (K0) separates again as soon as the first detector (D1) data signals again first input (K0E1) is detected and the second detector (D2) detects the second switch Unit (S2) controls such that it the second input (K0E2) and the first off gang (K0A1) of the network node (K0) connects when the second detector (D2) over for an adjustable period of time, no data signals are detected at the second input (K0E2)  and the second detector (D2) controls the second switching unit (S2) such that the se the second input (K0E2) and the first output (K0A1) of the network node (K0) separates again as soon as the second detector (D2) again data signals of the second Input (K0E2) detected. 2. network node according to claim 1, characterized in that the microcomputer (µC) deactivates the second switching unit (S2) when the first Switching unit (S1) the first input (K0E1) and the second output (K0A2) of the Network node (K0) has connected. 3. Network node according to claim 1 or 2, characterized in that the bus (B) is an optical or electrical bus. 4. Procedure for operating the network node (K0) according to one of the before prospective claims, characterized in that the network node (K0) via the first and the second detector (D1, D2) detects whether Data is present at the first and second inputs (K0E1, K0E2) via the bus (B) and in the event that no data is sent to one of the Inputs (K0E1, K0E2) are present, the outputs opposite the inputs (K0A2, K0A1) is switched to the inputs (K0E1, K0E2).