FI103544B - Procedure for determining addresses in a data network node - Google Patents

Description

103544

The invention relates to a method for determining addresses in nodes of a topology-like communications network according to the preamble of claim 1.

In this disclosure, the junction device or node is used at the intersections of the communication system 10 transmission links. The node may be any device or apparatus capable of interfering with the clock, e.g. a branching or cross-coupling device.

The nodes in the telecommunication network must know their 15 addresses (i.e. their location) in the network, because the address depends on the role of the node in the network (configuration, etc.). Address information is also necessary for the node to route messages over the network.

Many modern communication protocols 20 use logical addresses that do not uniquely indicate the physical location of the device. For example, from the host part of an Internet address that identifies which device is on a single network, no physical location of the device can be deduced from that. online. The node device 25 must be given a logical address during the network setup phase and also when the node device is moved to a new location on the network. Address assignment typically occurs by manually configuring a logical address for each device. This can be done, for example, by means of the network management system 30 from the network operator workstation of the network operator, or each node device can first be given a centralized address corresponding to the intended location of the node in the network.

103544 2 The disadvantage of such methods is their high workload, especially when it comes to installing a large network (large number of nodes).

Another disadvantage associated with such procedures is the inelasticity of network changes, since all nodes that have changed their position in the network have to be manually configured with a new address.

It is an object of the present invention to provide an improvement to the above drawbacks by providing a new type of addressing method for addressing nodes in a tree-like, point-to-point communications network. This object is achieved by the method according to the invention, which is characterized in what is described in the characterizing part of the appended claim 1.

The idea of the invention is to generate node addresses in nodes of a tree-based network structure by automatically assigning unique identifiers in nodes to all (point-to-point) connections except the parent node 20, and sending to each node tag. Because the network root node does not have 25 parent nodes, it transmits either an address identifier consisting solely of the identifier assigned to the connection or an address identifier consisting of the root address identifier and the identifier assigned to the connection itself.

When using the method according to the invention, only the address assigned to the root node of the network is given. when installing the node device (or any other step). The other nodes (devices) on the network then automatically receive their position relative to the root node. The node address 35 is thus automatically determined in a predetermined manner based on the location of the node. Address changes are also avoided when replacing devices 103544 3 or installing new ones.

The solution according to the invention is very advantageous especially in networks where the nodes are physically located so that they are difficult to access.

In the following, the invention and its preferred embodiments will be described in more detail with reference to the accompanying drawings, in which FIG. 1 illustrates a basic principle of the method of the invention, FIGs. 2a ... 2f illustrate operation of the method of the invention in network change situations. 4, a high level block diagram of the parts of the node that are essential to the invention, and Figure 5 illustrates the parts of the node that are essential to the invention.

The starting point of the method according to the invention is that only the root node of the network is (manually) assigned the address. when installing the node. Instead, other individual node devices do not need to know their own address (i.e., their location) on the network when they are turned on. Other individual node devices only know that they have a specific set of point-to-point connections to other nodes. One of these connections is the connection in question. to the parent node of the node device in the tree structure, but in the initial state (when the node starts), 30 nodes need not know which of its connections is that connection.

The principle of the method according to the invention will now be described with reference to Figure 1. described in circles in the nodes form a tree-like hierarchical structure with a root node 35 is marked by reference mark R. Links between the nodes (i.e. transfer connections) is shown by the arrows 4 103 544 (the transfer connections are naturally bidirectional, the arrow direction representing transmission of address identifiers). It is essential for the invention that the mesh forms a tree-like hierarchical structure. In other words, the nodes of the network 5 and the connections between them form an acyclic graph (no loops are formed in the network).

The root node R identifies each connection, e.g. by numbering the connections from zero to forward using a particular method. Thereafter, the root node 10 transmits on each connection along the current node. connection identifier. In the example of the figure, integers denoted by 0 ... N are used as identifiers.

When any node other than the root node (i.e., node X) is started and connections are established, node 15 X waits for its location information over some connection.

Alternatively, the node may send the query to the neighboring nodes. When node X receives the location information, it registers that location. connection as the connection that leads to its father-sol-tree-like network structure. The resulting location information 20 consists of a series of identifiers, the first of which indicates which connection is reached from the root node of the network to the next node X. The next identifier indicates the connection through which said next node is closer to node X, etc.

Upon receiving the location information, the node X assigns identifiers (according to a predetermined method) to all connections except the one from which the location information was received. The node X then transmits, along each of the 30 nodes, location information consisting of the node's own location (the same one that node X previously received) plus the current location. connection label.

The length of the received location information thus depends on the level at which the receiving node is located in the tree. E.g.

In the example of Figure 1, where the identifiers are integers separated by a dot, the 103544 5 node A1 receives the location information 0 (zero) from the root node and the next level node B1 in turn receives the location information 0.0 from the node A1. The transmitted location information is indicated in the figure next to the corresponding link.

5 When new connections are then made to node X, the node distributes the identifiers (numbered them) to them and sends them location information. If a new location information is received from the parent node X, it will be forwarded over other connections, provided with that location.

10 connections labeled.

Figures 2a to 2f illustrate the operation of the method of the invention in a situation where nodes E, F and G are connected to a network that already has nodes A ... D in operation (Fig. 2a). In the figures, the dotted lines show those nodes that are not yet operational. Functioning nodes are represented by a solid line, and if an address tag is placed inside the node, the node also knows its address (i.e., its location on the network). Thus, empty nodes do not yet know their address. From the example it is found that method 20 works even if the nodes are started in arbitrary order.

In the situation of Fig. 2a, only the node F has started from the nodes to be added, but it is disconnected from the network. because its parent node (node E) has not yet started. In the situation of Fig. 2b, node E is triggered to receive address 0.1 from node B. Thus, node E knows that such a connection leads to its parent node in the network. Node E then numbers all other existing links starting from zero and sends 30 of its own addresses, followed by the corresponding one. linkin nume-ro. In this example, there is only one existing link, which will be given a zero and sent 0.1.0. This is illustrated in Figure 2c. The node F then knows its address (Fig. 35 2d). In the case of Fig. 2e, node G is triggered, whereby its parent node (E) notices that the link is "firing" and updates the list of active links 103544 6 by assigning it a number according to a predetermined numbering method (number one). Thereafter, node E sends the node G an identifier 0.1.1 (own address plus the identifier of said link). In the final situation 5 (Figure 2f), all nodes know their address (their location in the network).

Link tagging can be implemented in many different ways. It is not advisable to give the numbering in the order in which the links are started, since then the numbering 10 does not provide any useful additional information. The numbering could, for example, follow the directions of the air, for example, the north link may be numbered one and the south link zero. Another, in practice, more likely option is to perform the partitioning of the identifiers, e.g., such that when looking at the device from a particular direction, e.g., from the front, the identifiers change in the selected direction, e.g.

The flowchart of Figure 3 illustrates the operation of a single node. Once the node has started, it is in step 31 where it waits for an address message and a link event. The network nodes can send their address information continuously, so the node receives the address as soon as it starts up. In this context, a link event is a break or start of any link in a node. Step 31 is a start-up phase in which normal data transmission is not performed. When the node detects an address message (step 32), it stores the received address and the associated address. connection identifier, assigns identifiers to other links in use, and sends 30 addresses to its child nodes (step 34). Thereafter, the node «enters its normal mode (step 35), where it straightens out normal data transmission.

If the node detects a link event in step 32, it updates the link list it maintains (step 33) 35 and returns to step 31, which returns to normal mode only after the address has been received.

103544 7

While in normal mode (step 35), the node can detect: a) a child node link event (link to a child node is broken or a link to a new child node is broken) 5 b) a new address message if changes occur over the node (closer to root)

In case a), the node updates the link list and sends a new address if a link to the new child-10 node was created (step 37). In case b), the node goes to step 34 where it stores the received address and said address. connect tag, assign tags to other active links, and send addresses to their child nodes. In case c), the node goes back to boot step 15 (step 31) to wait for the new address from the parent node.

A node in a network using a method such as the one described above, which may be e.g. a digital crossover device, can be implemented in practice in many different ways. The embodiment may vary, for example, depending on where the control portion of the node 20 (that portion which operates the node device) is located. Figure 4 shows a high level block diagram of those parts of a node device that are relevant to the invention. In this case, the node (denoted by N) has four bidirectional connections (L1 ... L4) to 25 neighboring nodes. In this example case, the node control unit CTRL is a separate unit common to all interface units IF. The node connects to the network via interface units IF, the interface can be e.g. 2 Mbit / s PCM interface. The mode of transmission used between the nodes is not essential to the invention; For example, any frame-based method may be used as a transmission method.

It is essential for the node that the address processing unit (control unit CTRL) receives information from each of the 35 interface units whether or not the control unit is in operation. link in action (that is, the signal being received is valid). These 8,103,544 messages are denoted by the CR (carrier) in the figure. The DATA is used to denote bidirectional data transmission between each IF and the control unit.

Figure 5 illustrates in more detail the control parts of the CTRL part which are essential to the invention. The input of the control part is formed by a decoding unit 51, which receives, for example, a frame from the interface unit for which the checksum has been calculated in the interface unit. The decoding unit 10 extracts from the frames the protocol data unit (PDU) contained therein and forwards it to the switching unit 53. The information units include information on the type of received frame, the address contained in the frame and data contained in the frame.

If the type is, for example, normal (normal frame), the switching unit will further connect the data units either directly to another interface unit or to other parts of the node device. In the transmission direction, the encoding unit 52 forms an outgoing frame from the data units PDU.

If the received frame contained address information, the switching unit connects the information unit to the address processing unit 54, which stores the received address in a memory area M1 where the node's own address is maintained. In addition, the processing unit maintains the identifier of the 25 links to the parent node in the memory area M2 as well as the identifiers of the other links in the memory area M3, which may also include information on which link is active / inactive.

The invention has been described above in an embodiment in which the root node merely transmitted to its neighbor node the identifier of the transport link in question. However, the root node can • forward its own address in addition to the transfer identifier. Thus, if the address of the root node, for example, is zero in FIG. 1, it forwards the identifier 0.0 to the node Ai, which forwards the identifier 0.0.0 to the node B1. Thus, in these 35 cases, the transmitted address identifier becomes one level longer than before.

103544 9

While the invention has been described above with reference to the examples in the accompanying drawings, it is clear that the invention is not limited thereto, but may be modified within the scope of the inventive idea set forth above and in the appended claims. For example, it is possible that the address identifier received from the parent node is not directly used as the node's own address, but the node generates its own address according to the address identifier received from the parent node (by processing its host country address identifier

Claims (7)

A method for determining addresses in the nodes of a telecommunications network, which network comprises several nodes (A ... G) interconnected with transmission links, such that the network forms a tree-like structure, one of the nodes being the root node (A), according to which method the nodes transmit each other signals containing the address data used by the nodes, characterized in that the root node (A) of the network forms unique address identifiers for all transmission connections it uses and communicates each address identifier to its neighbor node along the respective transmission connection, and the other node's reception of the node. the address code (a) forms unique identifiers for all transmission connections they use, with the exception of the connection from which they received the address identifier, and (b) sends each of the relevant transmission connections an address identifier which includes the identifier node itself received and one identifier corresponding to that identifier, each node determining its own address by the * received address identifier. Method according to claim 1, characterized in that each node uses the received address identifier directly as its own address. Method according to claim 1, characterized in that the root node of the network, in addition to the address identifier of the transmission connection, also communicates its own address to the neighbor node. Method according to claim 1, characterized in that integers are used as identifiers. 35 5. A method according to claim 1, characterized in that the identifiers of the transfer compounds are formed according to a predetermined principle regardless of the order in which the transfer compounds are started. Method according to claim 5, characterized in that the identifiers are distributed according to their physical position in the node device. The method of claim 1, characterized in that one of a node's true address identifiers is set in serial form by separating the address identifier received by node 10 from the identifier of the transmission connection with a predetermined separator. «