FI114954B - Transmission of data packets in telecommunications networks - Google Patents

Description

114954

Field of the Invention

The invention relates generally to the transmission of data packets in a telecommunications network. In particular, the invention relates to the transmission of data packets to a subscriber terminal of a wireless communication network.

Technology background

The GPRS (General Packet 10 Radio System) or UMTS (Universal Terrestrial Radio Access) terminal equipment of a packet switched data service network can connect, for example, to Internet Layer-Based Routing Data Protocol (IP) Internet networks or X.25 packet networks. When transmitting data over an IP-based network, the IP one-to-15 protocol is used. It includes a number of transport protocols, the most significant of which are Transmission Control Protocol (TCP), User Datacram Protocol (UDP) and IP routing between networks. There are IPv4 and IPv6 versions of the IP protocol. IPv4 network addresses are four bytes long and are represented as N.N.N.N, where N is an integer from 0 to 255. IPv6 addresses are 16-20 bytes long and are represented as X: X: X: X: X: X: X: X, where X is hexadecimal * · '; integer from 0-FFFF.

«». ···. GPRS and UMTS terminals cannot be assigned in significant · 1 /: fixed IP outside the mobile network in current applications! address. Outside a mobile network, they may be granted either [. 25 IP address, or a combination of an IP address and a TCP or UDP port. Commonly used methods in IP-based networks are 'Network Address Translation (NAT), which, for example, converts a public IP address into an internal IP (· address) of a mobile network, and NAPT (Network Address 30 Port Transformation). address conversions are needed due to the inadequacy of public IPv4 _ _. t addresses, and in particular to increase the security of the private network ii., and the external network is undergoing constant changes in network topology, which must be taken into account when routing packets to the correct destination.

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35 In situations where the GPRS and UMTS terminal does not have a fixed • · IP address, the fixed network terminal cannot send the packet directly to such a 2 114954 terminal. In current solutions, the fixed network device must first somehow request the mobile network terminal to establish a connection to the fixed network device. The request may be sent, for example, as a Short Message Service (SMS) or alternatively from a fixed network device to a mobile station. Also, current solutions are not directly applicable to the Internet environment because existing server solution standards cannot be used as such. Your wired device must have an application program that allows you to connect.

One way to resolve the above disadvantage is to install a server behind a GPRS or UMTS connection. However, this is difficult if not impossible. The operator should provide each mobile subscription with its own fixed public IP address. The number of IP addresses needed would be enormous and would consume the addresses of the current IPv4 address space to the extent that implementation is not economically or technically meaningful.

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BRIEF SUMMARY OF THE INVENTION

The object is to provide a method and system that enables communication from outside the wireless network to a wireless subscriber terminal or a server connected to the subscriber terminal. It should be possible for a wireless terminal with a temporary IP address to establish a data connection from outside a mobile network, such as IP, · * ·, based network, utilizing existing IP network standards and practices.

! The object is achieved as described in the independent claims. 25 ways.

': The basic elements of the invention are a fixed network address: ···' a first server, a second server associated with a wireless terminal, and a destination server associated with a second server.

* ·, '·; The wireless terminal, the second server, and the destination server can all be on the same device or on two or three different devices. The other # server is able to communicate via the wireless terminal first »» · ;;; and handle packets arriving from and sent to the first server. The destination server is able to communicate with another server. The client terminal is able to communicate with the first 35 servers. The data connection between the client terminal and the wireless terminal is established through the first server.

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The first server has a fixed IP address on the networks that you want to connect to the destination server and on the wireless network. It also has a plurality of ports, each of which is associated with a table of static and dynamic data for a particular terminal. When the first server 5 receives a packet transmitted from a non-second server to a particular port, it retrieves a table corresponding to the port, based on which information may be sent to the wireless terminal.

According to the invention, a connection is established between the first and second servers. The connection is established through the wireless terminal from the second server to the first server. At the beginning of the connection, the connection-specific dynamic data associated with the terminal is stored in a table available to the first server, containing previously stored static data of the wireless terminal and associated with a particular port of the first server. Dynamic information is the temporary IP address and port number assigned by the network to the first server and the secondary server. Static data is information that identifies a terminal, another server, and a destination service, such as a telephone number.

The functions of the first server include processing packets addressed to a particular terminal in the mobile network so that they are routed to the terminal in question in the mobile network. When the first server receives a packet received from a client terminal to a particular port, it will not. ". you will find out in the table associated with that port what is the public IP address and port of the other server that is being packaged. The first server then encapsulates its received packet with its headers. . 25 to one or more packets to be transmitted to the network, to which it also adds the necessary wireless terminal IP address and port information it has taken from the table. The original packet is the payload of the packet being transmitted now. The packet is sent to the wireless terminal according to the information added, i It is either the task of the first or the second server to observe that a connection exists between the first and the second server in order to be leased. possibly transmitted from another wireless network to another server; packages can be delivered. If the connection is lost for one reason or another, the second server may automatically open the connection to the first server or the first server will communicate to the second server that it must open the connection to the first server. After communication, the second server opens the connection to the first server. Communication can be done using various 4,114,554 technologies such as phone call or SMS short message. At the beginning of each connection, dynamic data is stored in a table associated with that terminal of the first server. Dynamic data is only valid for the duration of the connection.

5 The tasks of the second server also include receiving incoming packets from the first server, performing the necessary actions on them (including deleting data added by the first server), and routing the packet to the destination port of the destination server.

The functions of the second server also include handling packets addressed to the client terminal by the destination server 10 so that their payload is directed to the first server. The second server encapsulates in the payload, the client terminal IP address, and the destination port on one or more packets sent to the first server. The second server then sends the packet or packets to the first server.

15 When a first server receives a packet received from a second server to a particular port, it first determines the contents of the packet, which is the public IP address of the destination client terminal and the port to which the payload of the packet is to be delivered. The first server then sends the received packet payload to the client terminal.

20 The operations of the first and second servers are for both the sending terminal and the receiving application of the original '·' packet ···. transparent. From the sender of the packet, it looks like the packet would go · ": directly to the destination server application on the first server, and from the destination server application it looks like the packet. 25 would have come directly from the sender of the packet on the second server.

According to another embodiment of the invention, more than one port on the first server may be allocated to a single wireless terminal. The first server database then stores a number of tables containing information corresponding to the ports.

Alternatively, only one table can be created for a given terminal device .. per multiple port reserved for it.

;;; According to a third embodiment of the invention, one or more first servers may be reserved for at least a portion of the wireless terminals, wherein all the ports of the first 35 dedicated servers may be allocated to the terminal. In this case, the first servers act as a router.

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According to a fourth embodiment of the invention, at least some of the wireless terminals may be provided with a dedicated first server network interface, whereby all the ports of the dedicated network connector may be allocated to the terminal. The first server then acts as a router.

The method and system according to the invention are particularly suitable for moving objects and devices where, for example, the location of the object is difficult or uneconomic to install a fixed connection.

A further advantage of the invention is that even if the connection between the terminal and the external network is lost, it looks outward continuous. The invention 10 makes it possible, inter alia, to maintain a WWW service (World Wide Web) on a subscriber terminal.

List of figures

The invention will now be described in more detail with reference to the accompanying diagrammatic figures 15, of which Figure 1 illustrates an embodiment of the invention in a telecommunications network, Figure 2 illustrates a process of the invention by flowchart 20 in which a wireless terminal transmits data packets to an IP process according to the invention by means of a flow chart, *,; wherein the fixed IP based network terminal transmits the data packet and the wireless network to the subscriber terminal, and. . Figure 4 illustrates: a data packet received and processed by a first server.

DETAILED DESCRIPTION OF THE INVENTION With reference to Figs. However, the invention is not limited to implementation in a GPRS network, but may also be implemented in another type of network, such as a third generation UMTS mobile network. The subscriber terminals (100, 111, 112) used may be portable terminals, in-vehicle terminals or stationary terminals.

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Figure 1 shows the following network elements most important for explaining the invention from a GPRS network: a GPRS subscriber terminal 100, a base transceiver station (BTS) 102, a base station controller (BCS) 103 comprising a packet control unit (PCU), GPRS Serving GPRS Support Node 104, GPRS GGSN 105, and APN Router 106.

The basic elements of the invention are a new type of server 108 in the fixed network, hereinafter referred to as the first server 10, the server 101 associated with the GPRS terminal 100, hereinafter referred to as the second server and the destination server 107 associated with the second server.

The first server connects to both an IP-based network such as the Internet 109 and the GPRS APN router 106. The first server has a fixed IP address. The first server is connected to the client terminal 110 over the IP network 15. The client terminal can be any communication device, such as a computer, a mobile station, or a server associated with a mobile station. The client terminal may have a fixed IP address, a temporary IP address, or an IP address and port.

As is known, the GPRS terminal may be assigned a temporary IP-20 address or a combination of IP address and port. The client terminal 110 may connect to the GPRS terminal having a temporary IP address through the first server, regardless of where that terminal is at that moment; this is it.

! For the client terminal, the GPRS terminal in question has a global IP address, '25. This is possible by using the global IP address of the first server as the global IP address of the GPRS terminal. Visit-. in fact, many GPRS subscriber terminals may have the same global IP address. Despite this same global address, thanks to the first server, each GPRS network subscriber terminal is routed · [': 30 packets of the current subscriber terminal's temporary IP address and port. in accordance with.

The first server comprises a plurality of ports (e.g., several t / hundreds of thousands). At least a portion of the ports is associated with a table storing at least one static identifier of 35 subscriber terminals, another server or destination service associated with a particular GPRS subscriber terminal and dynamic information provided by the GPRS network. The static data may be a subscriber telephone number and a dynamic data IP address or IP address and port pair. According to a first embodiment of the invention, there is always one table associated with a particular subscriber terminal per port.

The first server also has processing means for encapsulating a packet received in a particular 5 port into a packet to be transmitted to the GPRS terminal, to which the first server also adds the dynamic information retrieved from a table associated with said port.

The second server includes monitoring means for monitoring the status of the connection between the GPRS terminal and the first server, and connection establishing means for establishing a connection to the first server. The first connection can be established, for example, as a result of some action taken by the user. Later, another server can connect automatically when it detects that the connection has been lost.

The second server also includes processing and interpreting means for processing and interpreting the packet received from the first server and control means for directing the packet to the correct service. In addition to the foregoing, the second server maintains a table of dynamic information, in which it stores information about the IP packets it receives from the first server. The information to be stored is at least a pair consisting of the IP address and port of the client terminal that sent the original packet. In addition to this . Stores information about which port on the other server the packet was sent to •. lee and what the target server is. Dynamic table. lun data is maintained according to a certain algorithm. The information may be exemplified; why disposed of after a predetermined period of time.

The second server also has processing means for encapsulating a received packet from the destination server into one or more packets to be sent to the first server.

In addition to the foregoing, the first and second servers are provided with communication means for communication between said servers.

30 The destination server comprises a destination service to which messages are sent by a client terminal on the same network or another network. The target; the remote server can send a response message to the client terminal via another server;

The destination server and the second server have communication facilities: · 35 lines for communication between said servers.

I · 8 114954

There may be multiple target servers associated with another server. The second server may also be associated with several first servers. On the other hand, the first server can also have multiple second servers connected.

The following describes packet transmission in a GPRS network to which the first, second and destination servers are connected as described above. Packet transmission in the GPRS network via the known GPRS network elements described above follows prior art packet transmission. In the example, the destination server associated with the GPRS phone is the taxi terminal, the destination service is on the TCP port 88 of the destination server, the second server is integrated with the terminal 10 of the taxi, the IP network client is the taxi terminal and the server according to the invention.

The example first describes the process by which a second server contacts the first server. When describing the process, reference is made to Figures 1 and 2 of Ku-15.

In the first step 200 of Figure 2, a taxi terminal, e.g., a handheld computer 115, opens a local connection to a GPRS phone 100. A local connection is, for example, a bluetooth connection. Bluetooth is a standardized wireless device-independent connection method used in the 1.4 GHz rear-20 band to communicate between a mobile phone and a computer. Olete-V; It is understood that the taxi terminal, i.e., the handheld computer 115, comprises both a destination server. the second server 101. When the connection to the GPRS phone is; established, the PDA requests the GPRS telephone to open a connection to the first server 108 having a fixed IP address.

In step 201, the connection to the APN router 106 is established through a support station 102, a base station controller 103, a GPRS network operating node SGSN 104, and a gateway node GGSN 105. The APN router name is given as one parameter when opening the GPRS context.

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: j Tasks of the SGSN 104 node include: • 30 pages on network access, security related functions, and knowing the location of the terminal device. The operating node SGSN is connected to a GPRS gateway node; via the other GGSN 105 IP-based GPRS backbone network. The Gateway GGSN enables data transmission between the GPRS network and external data networks. One or more gateway gateway nodes GGSN may be associated with one operating node SGSN. GPRS subscriber data and routing information are stored in the GPRS home directory (not shown).

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Each gateway node is associated with at least one APN router 106 that can listen to a particular TCP and UDP port space. In practice, there may be more than one APN router and may be located, for example, over the Internet or LAN. The GGSN register of the gateway node stores information about the 5 APN routers associated with it and information on how to access each APN router.

When the connection from the handheld to the APN router is opened, the TCP (or UDP) connection from the handheld is opened through the above network elements to the first server 108, step 202. The TCP-10 connection carries TCP packets according to the IP protocol. It is known that the header of a TCP / IP packet contains the IP address of the destination, as well as information about the source port and the target port.

Assume that the GPRS network has provided the taxi terminal with a temporary source IP address of 9.10.11.12, and a source port with TCP 80. These tie-15s are provided to the terminal on a per-connection basis. The fixed IP address of the target, the first server, is 1.2.3.4. In step 203, the first server stores the source IP address and source port number in its database table 113 and compares the terminal ID information such as the GPRS telephone call number 050 123 with the information previously stored in the table. If the ID information does not match the stored information, the connection will not be accepted and the dy mentioned. ·. mask information to save.

* ·. An ID can be defined as any terminal, another! '*. The unique identifier of the server or destination server. The IP address and port number are *; dynamic connection information, that is, it is created for each '| 25 for each connection. The call number is static information. In practice, it '*' · is already stored in the database when the subscriber contract is made. This creates a table associated with a particular port on the first server.

In this example, Table 113 is associated with port 1 of the first server.

; The table defines what the * 30 task for the packet received from said port is. The information in the table will be updated as necessary.

The taxi terminal (second server 101) checks at regular intervals whether the connection to the first server is open, step 204. If the connection is open, · 'checks the situation again after a certain time. If the connection is broken for one reason or another, steps 200-204 are repeated. In the latter case .j 35, the IP address and port number of the new connection are written to table 113 of the first server database. The 10 114954 IP address and port associated with the previous connection are either destroyed immediately upon disconnection, or alternatively the new information is overwritten on the old information.

The following describes a process whereby a fixed IP based network terminal transmits data packets to a taxi terminal. Referring to FIGS. 1 and 3, the process of FIG.

The flowchart of Fig. 3 illustrates a process in which taxi center 110 wishes to contact a taxi terminal to notify of a new taxi order. Table 114 of the taxi center database contains information on which first server it connects to a particular taxi and what is the port number referring to a particular taxi of the first 10 servers, for example '' taxi 1, port 108 of server 108 ''. Since the first server has a fixed IP address, packets can be sent to the wireless terminal 100 via the first server regardless of where that terminal is located.

15 The taxi center can use existing standards. It does not need any separate program or functionality to make the connection, and does not need to send a connection opening request, for example as a short message to the wireless terminal. This is possible when packets are routed to the terminal via the first server 108 of the invention.

20 It is known that GPRS network terminals cannot be assigned their own global IPv4 address because of the huge number of terminals required because of the large number of terminals. However, according to the invention, each GPRS terminal can be assigned a "" own "global IP address or! IP address and port pair. This is done so that the global IP address and port of the first server j '25 represent the global IP address and port of the GPRS terminal, i.e. the taxi 1 terminal / GPRS telephone in this example.

· 'Generally, a GPRS terminal can be contacted from the IP network direction, for example, by typing in a destination address in a browser on a computer or by clicking on a link on a web page. The address is in the form: • '30 http //: 1.2.3.4:1, where http (Hypertext Transfer Protocol) is an Internet-based application layer protocol. It is known to operate on the basis of user requests and server responses. The four ··· * integers 1.2.3.4 separated by dots define the first server's four-byte fixed IP network address independent of the global network. Chapter 1 is the TCP port of the en-35 first server to which the packet is sent from a computer in the • IP network.

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In step 300, the taxi exchange terminal 110 transmits the TCP packet to the first server 108. The destination address of the TCP packet is the IP address of the first server 1.2.3.4 and port 1. The first server listens to its own TCP and UDP ports from a particular network adapter. When the en-5 first server detects a packet from port taxi center 110 on port 1, it retrieves from the database a table 113 associated with port 1 and determines where the packet should be sent, step 301. Based on this table, the first server knows that the packet is destined for the number is 050 123. The table stores the IP address 9.10.11.12 and port TCP 80 issued during the current connection of the 10 terminals as dynamic data.

Once the first server has retrieved the IP address and destination port of the taxi terminal from the database table, it encapsulates the TCP packet received by the IP-based network from the computer into the payload of the TCP packet sent to the terminal 1 of the taxi. At the beginning of this packet, it adds a new TCP / IP header, which indicates that the destination address of the packet is the address that the taxi terminal last contacted, which is the dynamic information obtained from Table 113.

The TCP / IP header is standard, including e.g. source port, which here is the source port of the first server. In addition, the destination gateway to which the packet is addressed is indicated. The source port of the original payload packet header is the source port of the taxi terminal.

If necessary, the first server adds a TCP / IP header and a port; in addition to the 'own title'. The first server can also process the original message as needed, for example, by encrypting or compressing the message. Similarly, the second server can interpret packets handled by the first server.

The TCP packet can now be transmitted from the first server to the taxi terminal 115 in accordance with normal network practice. The TCP packet 30 is transmitted through the APN router 106, the gateway node GGSN 105, and the operative node SGSN 104 to the base station 102, which transmits the TCP packet II-> ·; over the interface via the GPRS telephone 100 to the taxi terminal 115, step: 302.

After receiving the TCP packet, the taxi terminal (more specifically, 35 min, said second server 101) removes the first part added by the first server from the packet and sends the remaining original TCP packet sent by the taxi center 12 114954 to the destination server 107 on the TCP port 88 of the destination service. , step 303.

The taxi terminal (more particularly the second server 101) may also include an authentication and / or encryption function that identifies that the packet 5 in question has come from an approved source. From the viewpoint of the second server of the taxi terminal, the packet appears to come from the first server 108, since the source IP address and source port associated with the header of the original packet (Figure 4, 400) are associated with said taxi terminal. The taxi terminal (another server 101) interprets the contents of the packet and redirects the packet to the right server. In this example, the taxi terminal, for example, displays a new customer address on the terminal screen.

Figure 4 illustrates a data packet received and processed by a first server from a taxi center.

The TCP packet received by the first server is in accordance with the standard practice of IP network 15, comprising the header portion 400 and the payload portion 401. In the header portion, the source address is the taxi terminal's IP address 5.6.7.8 and the destination address is the first server's IP address 1.2.3.4.

The first server encapsulates the TCP packet header 400 and the payload 201 of the payload 201 into the payload 402 of the TCP packet to be sent to the second server. This packet comprises a TCP / IP header 403 whose destination address is a taxi, ···. the IP address of the terminal on 9.10.11.12 and the source server's IP address as the source address 1.2.3.4. The package also includes the first server's own • - · · *! a pin 404 where information relating to the processing of, for example, a packet * 25 may be transmitted to another terminal. In addition to the above, the packet comprises TCP port 405 of object '· * ·'.

In the following, with reference to Figure 1, one embodiment is described in which a destination server operating in a taxi terminal responds to a notification from a taxi center about a new client. This taxi, for example, announces that it is • accepting a new customer, but wants more information at.

Assume that, when the destination server 107 at the taxi terminal receives the IP packet at TCP port 88, the destination server's destination · · service sends a response message to the taxi center 110. The destination service sees the message from another TCP / IP header message; 35,101 TCP port, so the destination server sends a response message to this TCP port.

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When the second server receives a response message to the TCP port from which it previously sent the TCP packet received from the first server to the destination server, it retrieves a dynamic data table associated with that TCP port. In the table, the second server-5 calculates which client terminal and which client terminal port the incoming messages from this destination TCP port are to be delivered to. In this example, the client terminal is a taxi center.

The second server 101 then encapsulates the response message in the packet to be sent to the first server 108 and attaches to the packet 10 the IP address 1.2.3.4 and the TCP port of the taxi terminal 110 received by it from Table 10.

The package may also include other necessary information and may be processed, for example, by encryption or compression. The second server sends the message to the first server.

The first server 108 receives the packet received from the second server 101, opens a message encapsulated in the packet, performs any other necessary action, and transmits the payload contained in the packet to the IP address and TCP port of the taxi terminal 110 associated with the packet.

20 A functionality as described above, wherein the wireless network; kon terminal sending a response to the client terminal is not necessary, ·. cat applications. In other words, functionality can be omitted if there is no need for a response from the terminal. On the other hand, the terminal can only-! in some cases, using a known * 25 method, if necessary.

When it is desired to send packets from the wireless terminal 100 to the client terminal 110, the role of the second server 101 between the target server 107 and the first server 108 is important for two reasons. First, ·· The routing between the target server and the client through a network or, in practice, multiple networks may not be transparent. In other words, network elements such as routers and firewalls along the route t '.t may block connections * · ;;; places that have not previously been contacted by a particular client terminal. This would be the case, for example, when the client terminal is a terminal on a LAN or mobile network that does not have a fixed IP address. On the other; 35, the client terminal may not understand that the destination terminal response is associated with a request previously sent by the client terminal if the response packet 14 114954 arrives from a device other than the one to which the query is sent. The drawbacks described above are eliminated in the arrangement of the invention, in which the client terminal sends a query message to the first server, from which it also receives a response to its query message.

According to a second embodiment of the invention, more than one port of the first server may be reserved for a single wireless terminal. Tens of thousands of TCP and UDP ports (for example 65536) can be attached to a single IP address.

According to a third embodiment of the invention, at least 10 of the wireless terminals may be provided with a dedicated first server. In practice, the wireless terminal server then acts as a router with respect to TCP and UDP protocols, such as a server with a fixed IP address and a first server arranged on a fixed network.

According to a fourth embodiment of the invention, at least 15 wireless terminals may be provided with a dedicated first server network interface. In practice, the wireless terminal server then acts as a router with respect to TCP and UDP protocols, such as a server with a fixed IP address and a first server arranged on a fixed network.

It should be noted that the above example illustrating the communication between a taxi terminal and a taxi terminal 20 is only one embodiment of the invention. The detailed measures disclosed herein are not to be construed as limiting the invention. It will be apparent to one skilled in the art that the invention may be implemented in a variety of ways, depending on the application.

! The solution according to the invention has numerous application possibilities. To give some examples, it is possible to apply / implement the solution in other public transport such as buses or trains. For example, photographs of the vehicle could be transmitted. Alternatively, the solution may be applied to a public transport payment terminal system capable of sending and receiving data. The solution is also applicable for example in a truck logistics system. Then the control center could contact the truck and get »· '! find information about the car in real time, as needed; · 'inform the driver of any change of route, provide detailed information about the destination or any other necessary information.

·: 35 In one embodiment of the invention, the first server monitors that a connection exists between it and the terminal. If the 15 114954 connection has been lost, the first server can notify the terminal of the connection being disconnected, for example, by signaling.

The connection between the wireless terminal and the other server can be wireless or wired.

The invention does not limit the terminal used. It can be a telephone, a computer with a network card, etc. The wireless network terminal does not have to be mobile either, but it can be built into, for example, a soft drink vending machine or some other vending machine. It is important to the invention that the terminal device together with the other server connected to it has a wireless data communication feature, an IP server feature and the ability to execute a client program capable of keeping the connection between the wireless terminal device and the device in the same or another network. It is also important that the terminal is able to automatically call back to the same location if the connection is lost for one reason or another. In addition, it is important that the terminal is able to send a response to the message it receives from the client terminal, if necessary. This allows for example applications where, for example, a vending machine selling food or other products informs the Control Center about its availability situation.

The ports used can be either physical ports and / or software 20 and. A server that manages and shares ports can be any number as long as it is capable of communicating with a wireless terminal. The information stored by said server relating to a particular terminal may be. : saves to multiple files or spreadsheets as needed. · Dynamic and static data stored by the server can be. 25 define the application.

Claims (21)

A method of transmitting data packets between a fixed network switched terminal (110) and a terminal (100) in a wireless network, characterized in that a connection from the terminal (100) in the wireless network to a first server ( 108) and that the connection is maintained from the fixed network to a first packet addressed to one of the first server of the terminal (100) in the wireless network reserved port addressed to the terminal, it is read in a table (113) and port data on the connection between the terminal (100) of the wireless network and the first server (108), the first packet being encapsulated to a tili terminal of the wireless network addressed to the second packet payload (402) and to the head of the second packet is added at least with the information in the table Iästä, and the second packet is sent to the terminal in the wireless network over that of the terminal (100) in the wireless network. t the first server (108) previously opened the connection. Method according to claim 1, characterized in that the first server has a fixed network address. Method according to claim 1, characterized in that: * * each opened connection, temporary address and port information about the connection is stored in a table. Method according to claim 1, characterized in that the connection is monitored and that a new connection is automatically opened if the connection has been interrupted, the temporary address and port information in the table (113) above that of the terminal (100) in the connection. wireless network reserved gate is replaced with new: ·. temporary address and port information given to the new connection. * 30 ' Method according to claim 1, characterized in that at least one port is reserved for the terminal of the wireless network, v. Method according to claim 1, characterized in that the temporary address information is an IP (Internet Protocol) address and that the port information is one of the wireless network assigned TCP (Transmission Control Protocol) or UDP. (User Datacram Protocol) port. I · 21 114954 Method according to claim 6, characterized in that one or more TCP or UDP ports join the first server to the IP address. Method according to claim 1, characterized in that upon opening a connection, an identifier received together with the temporary address and port information is compared which identifies the terminal in the wireless network with a corresponding identifier previously stored in the table. the connection is allowed only if the table identifies a task corresponding to the identifying identifier. Method according to claim 4, characterized in that the monitoring of the connection is carried out by a second server (101) connected to the terminal (100) in the wireless network. Method according to claim 1, characterized in that the connection is monitored from the first server (108) and in that case the connection has been interrupted, the terminal in the wireless network is requested to open the connection. Method according to claim 1, characterized in that the second server (101) connected to the terminal (100) in the wireless network (101) processes the second packet payload (402) on the basis of the port information. 20 Method according to claim 1, characterized by storing at least the sender's address and port information from the payload head • * ·,; * and the port on the second server from which the payload (402) is forwarded; ·· * according to the payload port information in a table of the tili terminal (100) in the second server (101) connected to the wireless network. ': 25 The method according to claim 12, characterized in that a response message is received in response to a transmitted payload 0 (402), the response message is encapsulated into a payload to the first server (108) and the address and port information stored in the table. · *. The information is appended as the address information of the reply message. A method according to any of the preceding claims, characterized in that the port information and / or the port refers to a software:; and / or a physical port. Λ .. 15. First server (108) in a fixed network, with which server is connected 3. a connection from a terminal (100) in a wireless network for transmission and reception of packets between the terminal in question and a device in the fixed network, characterized by the first server (108) comprising several ports and tables (113) over the ports, storage means for storing a temporary address and port information on the connection of the terminal (100) to a certain port reserved for the terminal table containing information on the terminal in question, processing means for encapsulating a first packet received to the terminal in the wireless network at the payload (402) of a second packet to be sent to the terminal in the wireless network to add at least the temporary address and port information for the second packet head and for sending the second packet over that of the terminal (100) in the wireless network against the first server (108) previously opened the connection to the terminal in question. 15 The first server according to claim 15, characterized in that the table (113) contains static data, at least one of which is an identifier that identifies the terminal (100) in the wireless network, with which the identifier is compared to a corresponding identifier received on connection of a connection, the connection being allowed in response to approval, and dynamic data comprising at least the address and port information, the dynamic data being stored only for the time that is allowed; > ·] Connection is pegged and replaced with new when opening a new connection. 17. Connect to a terminal (100) in a second network connected to a wireless network: (101), characterized in that the second server is arranged to: • communicate with a first server (108) via the terminal in the wireless network, monitor the connection state and in response to an observation that the connection has been interrupted ask the terminal in question open. 30 again. The second server according to claim 17, characterized in that: the second server (101) is further arranged to separate a packet encapsulated in a packet received from the first server (108) and to select the path for it according to a its main part ported task. 23 114954 The second server according to claim 17, characterized in that the second server (101) is further arranged to communicate with a target server (107) connected to the connected server (107), separate a packet 5 encapsulated in a packet received from the first server (108) and according to a port task attached to its main part directs it to the message server (107), stores in a table at least the sender's address and port information from said encapsulated packet head, the identification server's identification information and the port on the other server (101) from which the packet is to be sent message server (107), and in response to a transmitted packet encapsulate a response message received from the message server (107) to the payload of a packet to be sent to the first server (108) and to attach the address and port information stored in the table as the reply message's address information. Second server according to claim 17, characterized in that the second server (101) is integrated in the terminal (100) of the wireless network. A second server according to claim 17, characterized in that several template servers (107) are connected to the second server (101). 20 * ·? - 1 t · »·) · t · 'I I ·» · »* · 7 · I · I I * * * * t