SE526983C2 - Communication device and method for resolving identity conflicts in a network - Google Patents

Abstract

A method and a device to connect a communication apparatus to at least one other node in a network. The device searches for and establishes contact with the at least one other node. The device and the node have locally exchangeable identities. When contact is established, the identity information comprising the current local identity of the device is sent to the at least one other node, identity information comprising at least one current local identity of the at least one other node is received, and it is decided whether an identity conflict between the current local identity of the device and the at least one other node exists. If an identity conflict exists, it is solved so that the first and the at least one other node have locally unique identities.

Description

25 30 35 526 98. . . . 030930 ua \\ cumnu'r \ nn \ p \ ssav The second carnusu fi szußsavooonosossëjišalïdfaffr.dm '- 2 o ad is based on linking via base stations thus requires very large investments to function satisfactorily. With increasingly higher frequency ranges that the systems use, more and more frequent placement of the base stations is also required. Furthermore, it is often not economically possible to expand base station-based communication networks in areas with low population density as the utilization rate will be too low.

A further disadvantage of previously known wireless communication systems is the central control of the communication. In mobile telephone communication systems, centrally located devices have control over the identities of the mobile terminals and where in the network they are located. This requires large routing tables and very complicated functions to transfer information from one node to another.

A further disadvantage of previously known wireless communication systems with central control is that nodes cannot communicate directly between each other even though they are within each other's coverage area. This also applies when the overall central control cannot be reached, e.g. in case of technical errors.

SUMMARY OF THE INVENTION It is an object of the invention to provide a method of communicating between at least two nodes in a network which does not require an externally located unit to administer the connection between the nodes or any base station to transmit the information between the end nodes. It is a further object of the invention to provide a method which enables adaptive and automatic connection of nodes to a network.

The above object is achieved by the method according to the invention for connecting a first node to a network with at least one second node. The method includes searching for and establishing contact with the at least one other n0 15 20 25 30 35 526 ess ososao is \\ clm1zzm \ nn \ v \ sss1 Anders carliusunss the current local identity of the first node to the at least one second node, receive identity information including at least one current local identity of the at least one second node, and determine whether an identity conflict exists between the first and the at least one second node local identity. If there is an identity conflict, the identity conflict is resolved so that the first and the at least one second node have locally unique identities.

This can be done by either the first and / or the second node, depending on how long they have had their respective identities, changing their current local identity to a new local identity and notifying the second node of their new local identity.

It is a further object of the invention to provide an apparatus for using the method.

This object is achieved by a device according to the invention for communicating with at least one node with a local identity in a network. Device comprises a communication unit arranged to search for and establish contact with the at least one node and an identity unit. The device has an interchangeable local identity. The communication unit is arranged to send identity information comprising the current local identity of the device to the at least one node and to receive identity information comprising the current local identity of the at least one node. arranged to determine whether an identity conflict between the Identity Unit is the current local identity of the device and said at least one node, and if so resolve the identity conflict so that the local identity of the device and said at least one node are locally unique identities.

Further embodiments of the invention are defined in the independent claims. 10 15 20 25 30 p a o oo I. '. It is an advantage of the invention that communication between nodes can take place without any intermediate base station and that connection between the nodes is possible. can happen automatically when they come in close proximity to each other. This makes a network according to the invention much cheaper to build and use than previously known communication systems.

It is an advantage of the invention that the communication between nodes takes place within a limited identity list. The unique identities are chosen so that the identity is close to the identity of the surrounding nodes. This shortens the identity lists for the own node for contact with nearby nodes and then requires only a few searches to find the correct identity. This means that a little processing power is needed to search the identity lists and the searches are thus fast and the energy access in the node is limited.

Brief Description of the Drawings Additional objects, features and advantages of the invention will become apparent from the following description of several embodiments of the invention, in which various aspects of the invention will be described in further detail with reference to the accompanying drawings, in which: Fig. 1 is a block diagram of a node according to the invention; Fig. 2 is a block diagram illustrating the establishment of a two-node network; Fig. 3 is a flow chart of a first embodiment of the method according to the invention; Figs. 4a-b are a block diagram illustrating the establishment of a merged network with a channel; Fig. 4c is a block diagram illustrating a two-channel merged network; II 0000 00 00 0 0 O O O 0 0 0 0 10 15 20 25 30 35 0 u n no nun-nu a oc n 0 ao n 0 o o n 1 p o nu 0 526 985. ..

I l I O 0 C. . . . . . '2 ".' .. '. Oaoaao Lß wcunnmrruaauussiv Anden; caz1ius \ x> \ s1 -: \ Pss: 1oooi_o9u3s0_f: nä1' arxraaov 5 on en 0 co nuc- vs.- 1 0 once u .ann n 0 0 U Fig. 5a-6b are block diagrams illustrating two separate networks and merging them; and Figs. 6a-6b are block diagrams illustrating the separation of a network; and Fig. 7 is a block diagram illustrating the transmission of information.

Detailed Description of Embodiments The present invention relates to a communication system in which two or more nodes establish a network adaptively as additional nodes come within the total coverage area of the network. All nodes have self-assigned identities that are unique in the local network. Communication between the nodes takes place with the self-assigned unique identities, even if the nodes cannot communicate directly with each other without another node forwarding the information to the correct receiving node.

Each node can also serve other nodes with services.

Each node can be contacted via globally unique identities or addresses. If the node is part of the network, it responds with its local identity, as will be described below.

The nodes can be stationary with a connection to a stationary power supply. The nodes can alternatively be portable and mobile with a limited available power reserve with battery or the like. The nodes can thus be both stationary and mobile communication devices.

The communication between nodes can be done with direct sequence or frequency hopping CDMA (Code Division Multiple Access) technology. A modulation for the design is with QPSK (Quadrature Phase Shift Keying). take place in the 400MHz band, however, another frequency band can be selected. The transmission can, depending on what is most suitable in each specific case.

The nodes are described as deciding on route selection or other dependence on local environmental factors. These I O CCI! lO 15 20 25 30 35 u av .. n nocoao 6 environmental factors can be, for example, the traffic load of individual nodes, power output in the own node, a shorter path (measured in number of jumps) through the local network, historical data on transmissions that have taken place in the network or data type to be transmitted.

The nodes can provide services to other nodes. These services can, for example, consist of: Entering the correct local time, distributing media (audio and / or image), indicating when the next bus leaves the central station, publishing news information.

Fig. 1 shows components included in a device or node according to the invention. The device can be fixed or portable.

The device according to the invention comprises a communication unit for communicating with other nodes in the network. The communication unit may comprise various means for wireless communication, such as an antenna 10, a transmitter / receiver 11, a signal decoder 12, a unit for power control 13, a signal processor 14, a filter. check and, if necessary, change the local identity of the device. whether identity conflicts exist, the Identity Unit 15 further identifies as will be described below. A routing unit 16 can when information is to be sent to other nodes in the network decide via which of several possible paths the information is to be sent e.g. according to the above criteria. The device also comprises one or more memories shown collectively as the memory 17.

These can include both read and write memories.

The device also comprises one or more processors shown as processor 18 in Fig. 1. The processor 18 may be overall responsible for the overall operation of the device, or be responsible for one or more of the above-mentioned units of the device. Said units can e.g. be IQ I III. I 0 O O 0 nu 9000 I 0 0 0 III I 0 n c l I I I 0 0000 IQ I! 0 lo OODO Ia oo IQ c I 0 0 II 0 OI c 0 0 c ll in 10 15 20 25 30 435 526 985 030930 LB \\ CU'RRENT \ DB \ P \ 5637 Anders Car1ius \ P \ SE \ P56370001_09033 ({ _íin§l 7 nun implemented with software running by said processor A18, Alternatively the units are implemented with one or more ASIC (Application Specific Integrated Circuit), logic hardware circuits, or the like.

The device may also include an input interface 20, which includes a keyboard or keypad, a mouse or a joystick, or a touch screen. The device may also comprise an output interface with a media processor connected to a display 22, a microphone, 23, a speaker 24 and a camera 25.

The unique local identity can also be called a local address. One and the same address should only exist within a local network. Therefore, when networks are merged, each identity conflict within the merged network must be resolved by one or more nodes changing identity so that each node's local identity is unique within its network.

Fig. 2a shows a first and a second node Node A, Node B. Node A is alone in the network where it is located as far as Node A can see. Node B is alone in the network it is in as far as Node B can see. Node A and node B have each chosen their identity, it can be the same identity as they see this identity as unique in their own network. In Fig. 1, Node A and Node B have the same identity id = l when they are in different networks. When nodes approach each other and finally when they reach the point where their coverage area overlaps, they come into contact with each other.

If Node A and Node B have each chosen a unique local network identity different from the other, a new network with locally unique identities between the nodes will emerge.

If Node A and Node B have chosen the same identity, the case according to Fig. 2a, either or both of the nodes Node as is A, Node B must change to new local identities. The choice of new local identity can be made randomly over the entire available address space, but should be selected within the 2 ~ bit 10 15 20 25 30 35 526 983. n 1 = ** ï ** fï "? ~ Efï {¥ '3 r .:: ÛÛ-: II _. O. Q Ü 9 IIICCIIQI:, - --- ux-n- ¿.n: usa”: : 030930 LB \\ CURRENT \ DB \ P \ 5637 Anders Car1ius \ P \ SE \ P56370001_090330_f1n år t.doc 8 .. dar address space already used by the nearby nodes, the selection can not be made within a 2-bit address space, the choice should be within the same 8, 24, 64 bit address space as nearby nodes.The selection can be made within all 256 bits of address bits.The selection is made in this way to make the routing table as compact as possible.With a smaller routing table, each search in the routing table for the correct identity is shorter and thus not as much energy needs to be put into searching the routing table.

When all the nodes in a local network, Node A and Node B according to Fig. 2b, have locally unique identities, Node A and Node B can send information between them. The addressing of information between the nodes takes place with the locally unique identities. However, the request for a particular node is made using a global identity, as will be described below.

Fig. 3 describes a method for connecting nodes that are in different networks in a common network. In step 100, node A assumes a local identity with number 1 at time T. Node B, which is alone in its current network, which is also alone in its current network, also selects number 1 at time T. In step l10, the node searches for Node A, Node B for new nodes that are not part of its network. When Node A and Node B get contact over a radio channel, e.g. by reaching a certain quality of the signal-to-noise ratio, or contact over other media (eg a wired network), they establish contact at OSI level 1, commonly referred to as the physical level. When the contact between Node A and Node B is established, both nodes send the identity information to the other in step 120. The identity information includes which current local unique identity the node has and how long the node has had this address measured in milliseconds. The transmission of the identity information takes place by sending a data packet with a 7-bit start flag, the length can vary depending on the application, since 10 15 20 25 30 35 526 983 u n a o: oo acc co a o nu n soon-o. . .. -. . . 030930 m \\ Cu11.REm \ nn \ P \ s637 Anden carlius \ v \ ss \ ssazvoooi_csdaaojinäi 'tirafc! Aoc "9 indication of the size of the address indication 2 bits, the own address of max 256 bits, indication of the size of the time indication 2 bits , the time since the node's address was changed to a maximum of 1024 bits. The packet is sent as soon as possible after contact has been established between the nodes. Both nodes can send and receive the information at the same time. the channel speed should be 56000baud.This channel speed can be varied to suit the application of the application by raising or lowering.

The identity transfer packet can look like this at 8 bit address space and 8 bit time: [lO10lOl I OO I 8 bits own address | OO In 8 bit time indication].

Below are tables of the respective codes for address indication and time indication: Bit code 2 bits Address indication number of bits OO 8 01 24 10 64 ll 256 Bit code 2 bits Time indication number of bits 00 24 01 64 10 256 ll 1024 When the contact as made above is determined if the respective node has a unique local identity in step 130.

According to the example in Fig. 2, Node A and Node B see that the other party has the same identity. Then the node that has had the identity chooses the shortest time to change in step 140. Since both nodes in this case have been running for the same length of time, choose 10 15 20 25 30 5 2 e, 9 g 3, __. ..: ¿_ få _: Il 000 'I g: - tfdoc ".. .N oaosso Ls \\ cunnsur \ na \ n \ ss: v Anaezg cari1u = \ v \ ss \ Pss: vooo1_090 fi20_! Xn% 1 fl rßf 10 both to change to a new unique local identity that is chosen randomly without colliding with previously known identities: Node A selects identity id = 2 and Node B identity id = 3. Nodes that have chosen to change identity send in step 150 a previously described identity information packet with the new information to the other node, in which case Node A sends a packet to Node B and Node B a packet to Node A. In step 160 it is determined if the identity conflict is resolved. step 140, trying to resolve the conflict again until there is no identity conflict.

The local network for Node A and Node B with the unique local identities id = 2 and id = 3, respectively, has been established, whereby the procedure for establishing the new network can be completed. If no identity conflict occurs in step 130, the new local network can be established immediately and the procedure terminated.

Figs. 4a-4b illustrate how a first local area network is connected to a second network. Node A and B are located in the first network where identity conflicts have already been resolved according to Fig. 2a, Fig. 2b and Fig. 3. The second network with Node C approaches the first network. When the first and second local area networks are within each other's coverage area and sufficient signal strength is achieved, the networks can be interconnected. In Fig. 4a-b, Node C reaches a point where Node B is reached.

If Node C has chosen a unique local identity that is already different from all the other identities in the first network, a connection between Node B and Node C will occur according to the method in Fig. 3.

If Node C and any other node in the first network have chosen the same identity, either or both of the nodes in this case change Node A, Node B and Node C, have unique identities can to new identities. When all the nodes in the network, 0 00 00 0000 0 0 0 I 0 0 000 0 0 0 0000 I 0 I 0 0 00 0000 00 00 0 0 O '0 0 0 10 15 20 25 30 35 526 983 §¶Üï5ff? ~ HW .. .v.

. . . '..'. H - - ~ 030930 L: \\ CumzN'z '\ Dß \ P \ 5637 Anden carliusunsßwsssvcoonosoäsojinàl fl rafcfåoc ll respective node send information with unique local addressing between them.

Connection of the first and the second network takes place according to the method in Fig. 3. A node C which alone takes a local identity with number 1 at time T. Node A and Node B are included in the first network established as described above with the unique identities 2 and 3 taken at time T. When Node B and Node C make contact over a radio channel, this is done by scanning the coverage area at given time intervals, eg every second, ie a certain quality of the signal-to-noise ratio is reached, or contact over other media they establish contact at OSI level 1, commonly referred to as the physical level. When the contact between Node B and Node C as established above is established, both nodes send over their identity information. This information transfer with its packet description takes place in the manner described above.

When the contact between Node B and Node C is established, the nodes see that they have unique identities, Node B has a local unique identity id = 3 and Node C has a locally unique identity id = 1.

Nodes that have chosen to change identity send a previously described information packet with the new information to a second node. If an identity conflict arises where both have the same identity, the conflict is resolved in the same way as described above.

A local network for Nodes A, B and C with the unique local identities id = 2, id = 3 and id = 1, respectively, has been established.

Fig. 4c illustrates how at least two communication channels can be used in the same network according to the invention. The number of channels is not limited to two but may be more depending on need. Node A, Node B and Node C are part of a network. Node A has contact with node B via a first channel. Node B has contact with Node A and Node C via the first channel. Node A and Node C are also directly connected via a second channel. 10 15 20 25 30 '35 I i I I _. . . . . 030930 u: \\ Cuunsm \ nn \ 1 = \ s631 Anders caziius \ P \ s2 \ P56310001_09ÛNÄIHOI 3135! Å ° C ° 526 983 of a I øoo 000.nu 12 Since node A and node C have at least two communication channels, they can have contact between each other via the other channel without node B having to be involved.

Communication between Node A and Node C can take place either via the first or the second channel. The local identities are not affected as all nodes are already part of a local network.

Figs. 5a ~ 5b illustrate the interconnection of a first network with a first number of nodes to a second network with a second number of nodes. The number of nodes in the first and second networks can be the same or different. Node A, Node B and Node C are in the first network with locally unique identities. Node D, Node E and Node F are in the second network with locally unique identities. The first and the second Network initially have no contact with each other. When two of the nodes, in this case Node C and Node D, come into contact with each other, they establish a connection between them with locally unique identities for the two nodes according to the method in Fig. 3.

If all nodes in the first and second networks already have unique network identities within the merged network, no identities change.

If two nodes in the merged network have selected the same identity, either or both of the nodes change to identities unique to the merged network. Local identities are changed for all identity conflicts until all nodes have locally unique identities. When all the nodes in the network have unique identities, the nodes can send information with unique addressing between them.

Merging of a first and a second local network can take place as follows. Node A, Node B and Node C constitute the first network with the locally unique identities id = 2, id = 3 and id = 1 established at time T as above. Node D, Node E and Node F form the second network with the locally unique identities id = 3, id = 7 and id = 4 10 15 20 25 30 5 2 6 9 ° 3 U. . n u u I. I. .. 030930 LB \\ CURRBNT \ DB \ P \ 56) 7 Anders CarliuS \ P \ SE \ P5637000l_090330_final drafLdo 13 n n n a 0 q n u nu Ino co oc: co C nu 0 nuonuø u. snuva-: n 1 n n | o n oo ca anno ..- nous established at time T. The first and second networks initially have no contact with each other. When two of the nodes, in this case Node C with identity id = 1 and Node D with identity id = 3, from the first and the second network respectively come into contact with each other, they establish a connection between them with their unique identities by exchanging identity information. . Node C, which is aware of the unique local addresses in the first network, identifies whether there are identity conflicts in the common network between its adjacent nodes Node B and Node D which both have local identity id = 3. Node C sends identity change information to both Node B and Node D that they will resolve their identity conflict. Since Node C already has contact with both Node B and Node D, this information is sent via already established links. the identity change packet is coded with information as follows: 4 bits indicating that it is an identity conflict, indicating the size of the identity declaration 2 bits, the identity conflict address of a maximum of 256 bits, indicating the size of the time indication 2 bits, the time since the transmitting node's identity was changed max 1024 bits in this case Cz's address.

The package example below uses 8-bit identity and 8-bit time. [ooio | oo [a bit; conflict identity | oo | s bit time indication].

Definition of the four bits that indicate identity conflict: 0010 Identity conflict Node B and Node D respond with an identity packet as when establishing a link between 2 nodes, described in Fig. 2, to Node C. 10 15 20 25 30.

. . I 0 OI 030910 Ls \\ cun.nsm \ oß \ v \ ssav Anders carlius \ x> \ sz \ PS6370001_09053Oifl flfl l ÉHHÅOC 5 2 6 9 8 3. 14 The identity packet looks as described before but over established links so only transmitting information is displayed: the size of the address indication 2 bits, the own address of max 256 bits, indication of the size of the time indication 2 bits, the time since the node address was changed max 1024 bits.

The packet can look like this at 8 bit address space and 8 bit time [00 I 8 bit own address | OO l 8 bit time indication.

The packet from Node B is forwarded by each intermediate node in a signal path to Node D and the packet from Node D is forwarded to Node B. Thereafter, the same identity conflict resolution as described in connection with Fig. 3 takes place.

If Node B and Node D have the same time indication, both choose a new identity. Node B selects id = 5 as the new identity and Node D selects id = 6 as the new identity. Node B sends an information packet to Node C with the new identity. Node D sends an information packet to Node C with the new identity. The information package is of the same type as the identity conflict package where the information pieces are changed to a change of address. When Node C no longer sees any identity conflict, it no longer responds to Node B or Node D. After waiting a predetermined period of time, eg 20ms, Node B sends the same information packet as the one previously sent to C to its adjacent Node A, to which B link established previously. After sending Node D, the same information packet as the one previously sent to Node C to which Node B a link connection expected a predetermined time period, eg 20ms, to its neighbor Node E, has already been established. All nodes adjacent to a node that has changed locally unique identity shall receive an information packet from the changing node. The waiting time for mailing can be varied depending on local environmental variables in the way described above. In the package example below for II .III Ill- o o o o Ü Ü I 'ÛÛÛ I 0 o 0 I oo oooo oo o. O; oooooooo II oooo ooo 0 ooooooaoo oo o oo oooo oo oo 10 15 20 25 30 35 '526 983 _ o no ooooo Û i OIIO 030930 LB \\ CURRBNT \ DB \ P \ 5S37 Other fl CBt1iuB \ P \ SE \ PS637000l_090; 30_f¶ n§l àraftlbC H '°' "l5 about oooo oooooooooo oo oo oo oo oo ooooo oo ooooouoo 0 I: transmission of new identity uses 8 bit address indication and 8 bit time indication. [oooi 1 oo | s bit new identity | oo | e bit time indication].

Definition of the four bits indicating change of address 0001 Change of address Fig. Ga-6b illustrates the division of a network.

Nodes A, B, C, D, E and F are part of a network with unique network identities. Node F only has contact with the network through Node E. If Node F is out of contact for the nearest node Node E, no change in the local identities takes place.

As soon as there is an opportunity to connect a local link between two nodes, this is done.

If the node F at a later time, when it still retains its identity from the time of disconnection, comes into contact with any of the nodes in the network Node F was disconnected from, a connection will be established to the network. If e.g. Node F comes close enough to Node C to establish a connection, Node C will connect a link to Node F. Since none of the nodes has had any reason to change local identity, no address conflicts arise.

Fig. 7 illustrates how information is sent between nodes in a network. Nodes A, B, and C are part of a common network. Node A and Node B as well as Node B and Node C can send information between them, but not Node A directly to Node C.

Node A and Node C do not need to know about each other's existence. If Node A wants to send information to Node C but does not know where or if Node C is located, Node A makes a request, by sending out the global identity of Node C to adjacent nodes, in this case Node B, if said adjacent node can reach Node C. Since Node B can reach Node C, Node B answers Node A with 10 15 20 25 30 35 526 983 II. 'q n n o o o o °. o nu a n I 0 I 0 I '030930 LB \\ cu1znzn'r \ oa \ x> \ ssav Anders carliusuwsmvss: vooo1_o9 16 oc. won a confirmation if and how it when Node C. Node A starts sending its information to Node B which forwards it to Node C.

If Node A had had contact with more nodes, A would have contacted all these nodes with a request for the path to C. The response from the surrounding nodes about possible paths to the target node is then received and a path through the network is determined by the locally transmitting node, in this case Node A. The path through the network that is finally selected is determined by the previously described local environmental variables. For example, the selection can be based on the shortest route through the local network or depending on the traffic load of individual nodes and its links. If no response to a request comes within a certain period of time, a period of time that can be determined by the individual nodes, then the network is not considered to contain this target node.

The contact for a request to reach a node is made with a packet with the following composition: 4-bit information indicating the contact request, two-bit address size indication, local unique address of receiving node, local unique address of sending node, six bits indicating number of link jumps up to now, four bit data size indication, raw data with length according to previous field.

In the package example below, 8-bit address information and 1 link jump are used and the data bits are indicated by xxx. Node A is transmitting and Node C is the target node in the address fields.

The data bits and the data size specification are irrelevant in this example. [o1oo | oo 1 oooo oo11} oooo oooi | oo oooi | oooo | XXX].

Definition of the four bits indicating the contact request 0100 Contact request OI IIII II II o OIII II 10 15 20 25 30 5 2 6 9 oo nu no .o anno u ao nu IIIIIIIII II III i 83 2 .. '! ..' 1. ' X i 'u 22 2.2 2 030930 LB \\ cumzrrr \ na \ 1> \ 5s37 Anders caz1ius \ P \ sE \ Pss: 7ooo1_o90J3o_gin; 1 qtafc fi gtc fi; No; to a value according to the amount of data to be transferred.

Node C processes the request and responds with a contact response package to node B. Node C could have chosen to respond to another node that had had a different path to node A.

The contact response package is similar to the contact request where the addresses are Node C as sender and Node A as target node. The data bits specify the addresses of the different nodes made to reach Node C from Node A. In this case, Node Bz's locally unique address is specified in the data field. The data bits and the data size specification are irrelevant in this example.

Contact response is done with a packet with the following composition: 4-bit information indicating contact response, two-bit address size indication, local unique address of receiving node, local unique address of sending node, six bits indicating number of link jumps up to now, four-bit data size indication, raw data with length according to the previous field.

Definition of the four bits that indicate the contact request 0101 Contact response to the request When Node B receives this contact response packet, it is forwarded to Node A with an enumeration of the link jump counter in the packet.

Node A receives the packet and knows that Node C has responded and can see the path to Node C by going through the addresses in the data part of the packet. 10 15 20 25 30 35 526 983. . . 1 nu nan nu II IOII 030930 us \\ cunam'r \ nn \ l> \ sesv Anders carliusuwsmvssavooonosofsojänäl ázafeàoc 18 »annan ~ ououun If node A has not received an answer within a predetermined time period e.g. 20ms, the road to C had been considered non-existent.

Node A can now start sending the information to Node C by sending the information to Node B and having Node B forward the information to Node C.

In addition to communication of speech between nodes according to the invention, various services can also be provided. A service request can be sent from one node to adjacent nodes instead of a request for a specific node. The node searching for a service sends out a request about which services are available to its network neighbors. The answer that comes back from the neighbors contains the job description and the local unique identity where the service is located. Services can be, for example: Enter the correct local time, distribute media (audio and / or image), indicate when the next bus leaves the central station, publish news information, etc.

The service request can be sent out in a network e.g. according to Fig. 2. Node A and Node B are in a network with the locally unique identities id = 1 and id = 2. If Node A wants to find out which services Node B can provide, Node A sends a service request to Node B. Node B responds to Node A with a service response package that specifies the services that Node B can provide Node A.

The service request and service response is made with a package with the following composition: 4 bit information indicating the service request / response, two bit address size indication, local unique address to receiving node, local unique address to sending node, until now, six bits indicating number of link jumps up to four bits data size indication, service specification data with length according to the previous field.

In the packet example below, 8 bit address indication and 1 link jump are used and the data bits are indicated by 0000 I 0 0 0000 0 0 0 00 0000 0 O I 0 050 10 15 20 25 30 35 o 0 .canon o n 0000qn 19 xxx. Node A is transmitting and node B is receiving in the address fields. The data bits and the data size specification are irrelevant in this example.

[Request for service I address size I Node A identity I Node B identity I data size I data field] [o111 I oo I oooo ooio I oooo oooi I oo oooi I oooo I XXX 1.

Definition of the four bits that indicate Service request / Service response 0111 Service request / Service response What distinguishes a service request from a service response package is the content of the data field. A service request package does not need to contain any data.

The service answer must contain a list of all the services that can be provided in the data field together with the locally unique address that each service provides.

To have a global identity, a local identity is linked to a global identity in each individual node that has a global identity. To find a node showing the global identity, a service request is made with the globally unique address of the nodes in the local network.

The node that has the globally unique identity responds with both its locally and globally unique identity.

The node that sends the request can send out multiple requests without having received a response to the previous requests. The answers to the queries, which contain both local and global identities, can be linked to the questions by including both the requested global and the locally unique identity in the answer.

If no response is received to a request for a global identity, it is assumed that the node is not on the network.

A global request can be made by e.g. Node A and Node B are in a network with the locally unique identities 00 act u I 0 0 o IC o 0 10 15 20 25 30 35 0 gqïggg; a "ß .zxa: ann 2 () 3 r ° rn ::: É.É '§í§ ~ §š 9, II. 030530 143 \\ CIIRRENT \ DB \ P \ SG37 Ãnd !!! CåI1iU8 \ P \ SÉ \ P56370001_090330_f1 fl äl ÖIaÜLÉOC ..' '' "'20 id = 1 och id = 2. Node A has the globally unique address F55 and Node B has the globally unique address F66. Node A wants to get in touch with the globally unique identity F66. Node A therefore sets a global identity request regarding the identity F66 to its nearest node, in this case Node B with id = 2. Node B, which has the globally unique identity F66, corresponds with its global and local identity, F66 and id = 2, to Node A. The answer gives Node A that it can use the locally unique address id = 2 to get in touch with F66.

GlobalID request and GlobalID response are made with a package with the following composition: 4 bit information indicating GlobalID request / response, two bit address size indication, local unique address to receiving node, local unique address to sending node, GlobalID to sending node l28bit, GlobalID to node requested 128bit , six bits indicating the number of link jumps up to now, four bits data size indication, service specification data with length according to the previous field.

In the package example below, 8-bit address information and 1 link jump are used and the data bits are indicated by xxx. Node A is transmitting and Node B is receiving in the address fields. The global identities F55 and F66 are considered to be 128 bits. The data bits and the data size specification are irrelevant in this example.

[Service Request 1 Address Size In Node A Identity | Node B identity In GlobalID A | GlobalID B | Link jump In data size In data field] [olio} oo | oooo oooi | oooo ooio | F55 | F66 | oo oooi | oooo | xxx 1.

Definition of the four bits that indicate the GlobalID Request and GlobalID Response: 0110 Global ID Request / Reply 00 0 0 I 0 00 00 0 0 0 0 0 0 0 00 0 0 0 0 00 00 0000 na 0 n O 00 10 15 20 21 The method according to the invention can be implemented with computer software, which can be executed by one or more processors in the node according to the invention. The invention furthermore also extends to computer programs, in particular computer programs on or in a carrier, which are arranged to apply the invention in practice. The program may be in the form of source code, object code, for use in implementing the method according to or other code suitable for the invention. The carrier can be any device or device capable of carrying the program. The carrier can e.g. be a recording medium, computer memory, read-only memory or an electrical carrier.

The present invention has been described above with reference to specific embodiments. However, embodiments other than those described above are possible within the scope of the invention. Different method steps than those described above, performing the method with hardware or software can be accomplished within the scope of the invention. The various features and steps of the invention may be combined in other combinations than those described above. The invention is limited only by the appended claims. ann-on

Claims (25)

10 15 20 25 30 050829 LB P: \ 7073 \ P \ 00l \ SE \ P56370001_050829_new claim 2 SE.dor '21 PATENT CLAIMS A method of connecting a first node (A) to a network with at least one second node (B), which method comprises searching for and establishing contact with the second node,: receiving identity information comprising at least one current local identity for the second node; determine whether there is an identity conflict between the current local identity of the first and second nodes; characterized in that the identity information includes address space information, which indicates an address space to which the current local identity of the other node belongs; and that the method comprises resolving identity conflict by selecting for at least one of the first node and the second node a new local identity from the address space, which is defined by the address space information, so that the first and the second node have locally unique identities. Method according to claim 1, characterized by the step of sending identity information comprising the current local identity of the first node to the second node; Method according to claim 2, characterized in that the sent identity information comprises information regarding how long the node has held its current local identity and the received identity information includes information regarding how long the other node has held its current local identity. A method according to claim 3, characterized by the steps of: determining which of the first and the second node has which: has the first and the second node having: had the current local identity for the longest period of time if there is an identity conflict; retain the current local identity of the first node if the first node has had its current local identity for the longest period of time; otherwise change the current local identity of the first node if the second node has had its local identity for the longest period of time. Method according to one of the preceding claims, characterized in that, if the first and the second node have had their current local identity during the same period of time, repeatedly performing, until there is no identity conflict in the local network, the steps of: switching to a new local identity for the first node; send the new local identity of the first node to the second node node; receive at least one new local identity for at least the second node; and determining whether an identity conflict exists between the new and second nodes' new local identities. Method according to claim 4 or 5, characterized by the step of: sending the new local identity of the first node to the node for which identity conflict arose. Method according to one of the preceding claims, characterized in that contact between the first and the second node is established via a first and / or at least a second channel. 10 15 20 25 30 35 526 983 050829 LB P: \ 7073 \ P \ 001 \ SE \ P56370001_050829_new requirements 2 SBÅOC 24 Method according to one of the preceding claims, characterized by the steps of: in the event of an identity conflict between the current local identity of the first node and at least a third node: receiving identity information comprising at least the current local identity of the third node; determine whether there is an identity conflict between the current local identity of the first node and the current local identity of the third node; and resolving the identity conflict between the new node of the first node and the current local identity of the third node according to any one of claims 2-5. Method according to one of the preceding claims, characterized by the steps of: asking which local unique identity a specific node with a global identity has; receiving information including at least one contact path to the specific node; and send information via the contact path. The method of claim 9, characterized in that the information comprising the contact path of the specific node comprises at least two contact paths, the method comprising the further step of: selecting the contact path. 11. ll. Method according to one of the preceding claims, characterized by the step of: sending a service request to obtain information about which services are available in the network; and receiving a service response including information about at least one service that can be provided by at least one specific node in the network and at least one contact path to said specific node. 10 15 20 25 30 35 526 983 050829 LB Px \ 7073 \ P \ 00l \ SE \ P5637000l__050829_new requirements 2 SE.doc QS Device for communicating with at least one node (A, B, C, D, E, F) with a local identity in a network, which device comprises: a communication unit for searching for and (A, B, C, D , E, F), which communication unit is arranged to receive establish contact with the at least one node identity information comprising the current local identity of said at least one node; an interchangeable local identity; and an identity unit (15) arranged to determine whether an identity conflict exists between the local identity of the device and the current local identity of at least one node, characterized in that the identity information comprises address space information, which indicates an address space to which the current local identity of at least one node belongs; and the identity unit is arranged to, if an identity conflict exists, resolve the identity conflict by selecting a new local identity for the device from the address space, which is defined by the address space information, so that the device identity and the current local identity of at least one node are locally unique identities. Device according to claim 12, characterized in that the communication unit is arranged to send identity information comprising the current local identity of the device to said at least one node. Device according to claim 13, characterized in that the identity unit (15) is arranged to incorporate in the identity information information regarding how long the new claim 2 SEJDC 26 for a long time. the device has held its current local identity, and that the identity information received from the at least one node includes information on how long said node has held its current local identity. Device according to claim 13, characterized in that: the identity unit (15) is arranged to, if there is an identity conflict, determine which of the device and said at least one node has had the current local identity for the longest period of time, retain the device's current local identity of the device. has had its current local identity for the longest period of time, otherwise change the current local identity of the device if the at least one node has had its current local identity for the longest period of time. Device according to any one of claims 12-15, characterized in that the identity unit (15), if the device and said at least one node have had their current local identity during the same time period, is arranged that, until there is no identity conflict in the local network , repeatedly: change the current local identity of the device to a new local identity; send the new local identity of the device to the at least one node; receiving at least one new local identity for said at least one node; and determining whether there is an identity conflict between the new local identity of the device and the at least one node. Device according to claim 15 or 16, characterized in that the identity unit (15) is arranged to send L 15 20 25 30 35 526 985 050829 L! P: \ 7073 \ P \ O01 \ SB \ P5637000l_050829_ny3 claim 2 83,600 2? the new local identity of the device to the node for which identity conflict arose. Device according to any one of claims 12-17, characterized in that the communication unit is arranged to establish contact with said at least one node over a first and / or at least a second channel. Device according to one of Claims 12 to 18, characterized in that the identity unit (15) is arranged to receive identity information comprising at least the current local identity of at least the second node of the at least one other node in the event of an identity conflict between the device and at least one current node in the network. ; determine whether there is an identity conflict between the local identity of the device and at least the other node; and resolving the identity conflict between the local identity of the device and the at least the second node according to any one of claims 2-5. Device according to one of Claims 12 to 19, characterized in that the identity unit (15) is arranged to: make a request as to which local unique identity has a specific node with a global identity; and receiving information including the local unique identity of the specific node and at least a first contact path to the specific node; the communication unit is arranged to send information via the at least first contact path. Device according to claim 20, characterized by a routing unit (16) which is arranged to select a contact path for the information comprising the at least first new claim 2 SlLdOC à? the contact path to the specific node includes at least two contact paths. Device according to any one of claims 12-21, characterized in that a processor (18) is arranged to make a service request in order to obtain information about which services are available in the network; and receiving a service response including information about at least one service that can be provided by at least one specific node in the network and at least one contact path to said specific node. Computer programs comprising computer program code means adapted to perform all the steps according to any one of claims 1-10. A computer program according to claim 23, comprising on a computer readable medium. Communication apparatus for communicating with nodes in a network, characterized by the device according to any one of claims 12-22.