NO329924B1 - Method and apparatus for managing data services - Google Patents

Description

The field of the invention

The present invention relates to a method for controlling data connections in a first digital cellular communication network between a user terminal and a long-distance network.

Background and state of the art

Several technologies are currently defined for data transmission via a digital cellular communication network, such as a GSM network. Examples of such technologies are High Speed Circuit Switched Data (HSCSD) and General Packet Radio Service (GPRS). The different technologies realize data transmission in different ways. HSCSD is a circuit-switched technology where the data transmission is carried out via a data connection with one or more guaranteed allocated time slots. GPRS is a packet-switched technology where the data transmission is carried out via packets with one or more allocated time slots. The number of mobile terminals from different terminal manufacturers that support data is also increasing.

In order to make data transmissions possible in a digital cellular network, it is necessary that these can be controlled in the network. For example, it may be necessary to allocate resources in the network, monitor utilized resources, etc. For an HSCSD service in a TDMA network, such as a GSM network, resource allocation is carried out, for example, in the form of allocating a number of time slots to a data connection over which the data transmission is to be carried out.

It is also necessary that the terminals, where the transmission is to be carried out, can process data transmissions via the technology used, such as HSCSD or GPRS, via an interface to the digital cellular

communication network.

Finally, it is also necessary that there is an interface between the user and the user terminal.

Various terminal manufacturers have provided terminal specific software to handle the data transmission in a digital cellular communication network. Due to the fact that the data transmission is carried out via a network operator's digital cellular communication network, these communication networks must be able to process data transmissions between several different types of terminals, which results in adaptation problems as new terminal-specific solutions are introduced. Furthermore, a user may have to use different interfaces for the one and the same service for terminals from different manufacturers.

A general and common problem with the technologies for the transmission of data is that users perceive them as expensive and difficult to use.

Reference is also made to WO 96/10305 A2 which deals with a data transmission method in a TDMA mobile communication system, and US 5708656 A which describes a method and an apparatus for packet data transmission.

Description of the invention

The purpose of the present invention is to remove the above-mentioned problems that communication networks have for processing transmissions of data between several different types of terminals, and that a user may be forced to use different interfaces for the one and the same service for terminals from different manufacturers, and to reduce the problem that users experience that the technologies are expensive and difficult to use.

A preferred embodiment of the method is stated in independent claim 1, while alternative embodiments are stated in respective non-independent claims.

These purposes are achieved, in accordance with the invention, with a method for controlling data connections in a digital cellular communication network where the need for data transmission between the user terminal and the long-distance network is detected. A data connection between the user terminal and the long-distance network is established and its characteristics are changed depending on the detected need.

The advantages of this method are that a data connection between the user terminal and the long-distance network is only set up when access to the long-distance network is necessary. Users thus do not need to be connected until this need exists, which results in a lower use of resources and thus also lower costs. The setup of the connection is performed without the user having to input commands to the terminal, which reduces the processing for the user.

In one embodiment of the method according to the invention, the data transmission need is detected as a need for transmission speed between the user terminal and the long-distance network. The characteristics of the data connection are then changed by increasing the transmission speed for the data connection, where there is a need for a transmission speed between the user terminal and the long-distance network that is greater than the current transmission speed for the data connection, and where the transmission speed for the data connection is reduced, as the need for transmission speed between the user terminal and the long-distance network is less than the current transmission speed for the data connection. An advantage of this method, where the transmission speed of the data connection that is established between the user terminal and the long-distance network is dynamically adapted in accordance with the transmission speed that is necessary at the moment, is that the transmission speed of the data connection never exceeds the need for transmission speed.

Consumption of resources can thus be reduced, and thus also costs, compared to a data connection with a fixed transmission speed. A further advantage is that the user does not need to change the transmission speed manually, which results in easier processing for the user.

In another embodiment of the method according to the invention, the data connection is disconnected when it is detected that there is no need for data transmission between the user terminal and the long-distance terminal during a predetermined time period. An advantage of this is that the method results in the data connection only being set up if there is a need for data transmission. The utilization of the resources is thus further reduced, and with it also the costs. A further advantage of this embodiment is that the user does not have to check whether there is a need for data transmission, which results in simpler processing for the user.

In a further embodiment of a method according to the invention, it is detected if a break occurs. If a break is detected, a data connection between the user terminal and the long-distance network will be set up depending on the need for data transmission between the user terminal and the long-distance network. An advantage of this is that the user does not have to initiate the setup of a connection manually if a break occurs. This results in simpler processing for the user.

In a further embodiment of a method according to the invention, where the data connection in the first digital cellular communication network is set up between the user terminal and the long-distance network via a second digital cellular communication network, information on accessible digital cellular communication networks is obtained, depending on a request controlled by the user, such as accessible digital cellular communication networks and billing conditions for the use of the resources in different communication networks. Depending on the information about accessible digital cellular communication networks, together with advance-determined criteria, one network out of the accessible digital cellular communication networks is used. For example, the network that gives the lowest costs can be used. An advantage of this approach is that it gives the user the opportunity to always use the network that offers the lowest cost when the user is outside the area of the first network that is accessible to the user, where he/she is a subscriber, and where the user thus has to use a second network for access to the first network, so-called network switching ("roaming").

In a further embodiment of the method according to the invention, an application is detected which has a periodic need for data transmission between user terminals and the long-distance network. Data transmissions for this application between the user terminal and the long distance network are then filtered. An advantage of this is that applications that make regular attempts to access the long-distance network can be controlled so that unnecessary set-ups of connections are avoided. This will reduce costs for the user.

In an embodiment of the method according to the invention, depending on input from a user, information related to the data connection is collected, such as debiting terms/conditions, error handling tables and costs for data connections since the last billing. A number of parameters for the data connection, such as the transmission speed of the data connection for each time, and the time the data connection has the same transmission speed, are measured. Depending on data connection-related information, characteristics of the data connection, such as transmission speed, costs so far for the current data connection, and costs so far foi a predetermined time period are calculated, and its characteristic data is displayed to the user on a status screen to be used as base data for a decision by the user. An advantage of this embodiment is that the user will have a better basis for making a decision, such as deciding that the data connection should be disconnected when the costs exceed a certain level.

Brief description of the figures

The present invention will now be described in detail in what follows, with reference to the accompanying schematic figures, which for the purpose of exemplifying the invention show preferred embodiments of the invention.

Fig. 1 is a schematic figure of an environment in which the invention can be used. Fig. 2 is a schematic figure of another environment in which the invention can be used. Fig. 3 shows a flow diagram of an embodiment of a device according to the invention. Fig. 4 shows a flow diagram of a method according to the invention.

Preferred designs

In fig. 1 shows an environment in which an embodiment of the invention can be used. A user terminal 1 which includes a computer 2 is connected to a mobile terminal 3. The mobile terminal 3 is then connected to a first GSM network 4. Different types of long distance networks are connected to the GSM network. The figure shows two examples, Internet 5 and LAN 6. Connections can be set up via the GSM network 4 from user terminal 1 to these long-distance networks. Fig. 2 shows another environment in which the invention can be used. In this figure, user terminal 1 is connected to a second GSM network 7, which is then connected to the first GSM network 7, which is then connected to the first GSM network 4 This environment can be encountered, for example, when a user is located outside the area where the first GSM network 4 is accessible, where he/she is a subscriber, and where the user thus has to use a second GSM network 7 for access to the first network 4, so-called roaming. Fig. 3 shows an embodiment of a device 8 in accordance with the invention. The device 8 controls data connections in a GSM network 4, between a user terminal 1 and a long-distance network, in this case the Internet 5 and a LAN 6. The device includes a connection/disconnection device 9 located in the mobile terminal (3 in Fig. 1 and 2). The device 8 also comprises a need detection device 10, a control device 11, a break detection device 12, and an interface processing device 13, which is located in the computer 2 (2 in Fig. 1 and 2). The computer 2 also includes applications 14, some of which need data connections to some of the long-distance networks.

When the user starts the user terminal, the need detection device 10 detects the need for data transmission speed for the applications 14 in the user terminal. If the need detection device 10 detects that some of the applications 14 in the user terminal 1 have a data transmission need between the user terminal 1 and a long-distance network, it will inform the control device about this, which controls the connection/disconnection device 9 via the interface device 13 to set up a data connection. When a data connection is established, the need detection device 10 detects the need for transmission speed for the application 14 and informs the control device 11 about this, which increases, respectively reduces, the transmission speed for the data connection if the need for transmission speed is greater, respectively less, than the current speed for the data connection. The control device 11 uses hysteresis levels and delay in the increase, respectively the decrease, of transmission rates of the data connection, which means that the need for transmission speed of the application 14 must exceed, respectively fall below the transmission rate of the data connection during a predetermined period of time, in order to perform the increase, respectively the decrease . If the demand detection device 10 detects an absence of data transmission demand during a predetermined time period, it will inform the control device 11 about this, which controls the connection/disconnection device 9 to disconnect the data connection. Break detection device 12 detects whether a break has occurred and, if this is the case, informs about this to the control device 11 which, given that the need detection device 10 has informed that there is a need for data transmission, controls the connection/disconnection device 9 to set up a new data connection from the user terminal 1 to a long-distance network via the GSM network 3.

In fig. 4 describes a method in accordance with the invention for controlling data connections in a GSM network 4 between a user terminal 1 and a long-distance network (see Fig. 1). When a user connects to the user terminal, the method starts, and a detection step 15 detects the need for data transmission between the user terminal and the long-distance network, and informs about this need to a route selection step 16, which directs the method back to the detection step 15 if a lack of need for data transmission is detected, and forwards the procedure to a setup step 17 if a need for data transmission has been detected. The need for data transmission is detected as the need for transmission speed between the user terminal and the long distance network, for applications in the user terminal. In setup step 17, a data connection is set up between the user terminal and the long-distance network via the GSM network.

In a need detection step 18, the need for transmission speed, between the user terminal and the long-distance network, for the applications in the user terminal is then detected, and this need is informed to a route selection step 19.

The route selection stage 19 informs whether the need for transmission speed is higher than the current transmission speed to a demand increase stage 20, which will increase the transmission speed for the data connection. If the need for transmission speed is not higher than the transmission speed for the data connection, the route selection step 19 will forward the method to another route selection step 21. The route selection step 21 informs whether the need for transmission speed is lower than the current transmission speed for the data connection to the route selection step 21, which will forward the method to an interruption step 23 The increase, respectively the reduction, of transmission speed in the data connection in the need for in the demand search step 20, respectively the demand reduction step 22, is carried out by signaling to the GSM network that more, respectively fewer, allocations of time slots to the data connection. Hysteresis levels and delay are used when increasing or decreasing transmission speed for the data connection in the demand search step 20 or the demand reduction step 22. This means that the need for transmission speed for the application must exceed or fall below the transmission speed for the data connection during a predetermined time period, so that the increase or decrease must be performed.

In the break step 23, a break in the data connection is detected. If a break is detected, the procedure is forwarded to the detection step 15, where the need for data transmission is detected. If a need for data transmission is detected, a new data connection is established between the user terminal and the long-distance network.

Finally, in the route selection step 24, it is detected whether the need for data transmission has been missing for a predetermined time period which can be adjusted by the user. In case of such a lack, the data connection is disconnected in a disconnection step 25. If the need is still detected, maintain the connection and the procedure is directed to the need detection step 18, where the procedure continues until a lack of need for data transmission during a predetermined time period is detected, and data connections are disconnected.

Although a number of specific embodiments have been described above, experts in the field will realize that a number of modifications of the above described embodiments of the invention are possible within the framework of the invention, as defined by the accompanying patent claims. For example, here a device has been described where the various devices have been implemented in a computer and a mobile terminal. These devices can of course be implemented in only one computer, only in one mobile terminal, or in a combination of these.

Furthermore, the designs are described for GSM technology. The invention can of course also be implemented for any other time-multiplexed cellular technology, such as the American technologies D-AMPS (Digital-Advanced Mobile Phone System) and PCS (Personal Communication Services), or the Japanese PDC (Personal Digital Cellular).

Claims (23)

1. Method for managing data connections in a first digital cellular communication network (4) between a user terminal (1) and a long-distance network (5,6), characterized in that the method comprises the steps: detecting (15) the need for data transmission between the user terminal (1) and a long distance network (5,6), setting up (17) a data connection between the user terminal (1) and the long distance network (5,6) depending on the detected need for data transmission between the user terminal (1) and the long distance network (5,6), and to change (20,22) characteristics of the data connection depending on the detected need for data transmission between the user terminal (1) and the long distance network (5,6), the data connection in the first digital cellular communication network between the user terminal (1) and the long distance network (5,6) is set up via a second digital cellular communication network (7), where the method also includes the steps: depending on input from a user, to gather learning information about accessible cellular communication networks, and depending on information about accessible digital cellular networks, together with predetermined criteria, utilizing a network among the accessible digital cellular communication networks. 2. Method according to claim 1, characterized in that the step for detecting the need for transmission includes the step: detecting the need for transmission speed between the user terminal (1) and the long-distance network (5,6), where the step for changing the characteristics of the data connection includes the steps: to increase (20) the transmission speed of the data connection as the need for transmission speed between the user terminal (1) and the long distance network (5,6) is greater than the current transmission speed of the data connection, and to reduce (22) the transmission speed of the data connection as the need for transmission speed between the user terminal (1) and the long distance network (5,6) is less than the current transmission speed of the data connection. 3. Method in accordance with claim 2, characterized in that the steps (20, 22) to increase, respectively to decrease, the transmission speed of the data connection are carried out by means of hysteresis levels and by a delay reading in order to limit the number of changes in transmission speed. 4. Method in accordance with claim 1, characterized in that the step for changing the characteristics of the data connection includes the steps: disconnecting the data connection as an absence of need for data transmission between the user terminal (1) and the long-distance network (5,6) is detected during a predetermined time period. 5. Method in accordance with claim 1, characterized in that the method also comprises the steps: detecting a break in the data connection, and setting up a data connection as a break has been detected between the user terminal (19) and the long-distance network (5,6), depending on detected need for data transmission between the user terminal and the long distance network (5,6). 6. Method in accordance with claim 1, characterized in that the need for data transmission between the user terminal (1) and the long-distance network (5,6) is detected as a need located in the user terminal (1) for transmission speed for at least one application (14) between the user terminal (1) and the long-distance network (5,6) . 7. Method in accordance with claim 2, characterized by the need for transmission speed between the user terminal (1) and the long distance network (5,6) is detected as a need for transmission speed located in the user terminal for at least one application (14) between the user terminal (1) and the long distance network (5) ,6). 8. Method in accordance with claim 1, characterized in that information about accessible digital cellular communication networks includes accessible digital cellular communication networks and debiting terms/conditions for utilization of resources in the various communication networks. 9. Method in accordance with one of the claims 1-8, characterized in that the network that gives the lowest costs is used. 10. Method according to claim 1, characterized in that it also comprises the steps: detecting an application that has a periodic need for data transmission between the user terminal (1) and the long-distance network (5,6), to filter the transmissions for this application between the user terminal ( 1) and the long-distance network (5,6). 11. Method in accordance with claim 1, characterized in that it also includes the steps depending on an input from a user, to collect data connection-related information, measure parameters of the data connection, depending on the data connection-related information, to calculate characteristic data for the data connection, and to display this characteristic data to the user on a status screen for use as base data for decision by the user. 12. Method in accordance with claim 11, characterized in that the measured parameters for the data connection include transmission speed for the data connection at each point in time, and the time that the data connection has the same data transmission speed. 13. Method in accordance with claim 11, characterized in that data connection-related information includes debiting conditions or error processing tables. 14. Method in accordance with claim 11, characterized in that the characteristic data for the data connection includes at least one of; transmission speed, costs so far for the current data connection, and costs so far for a predetermined period of time. 15. Method in accordance with claim 11, characterized in that it also includes the steps: collecting current debit data from the first communication network (4) and displaying this debit data to the user for use as basic information for decisions by the user. 16. Method in accordance with claim 15, characterized in that the relevant debiting data includes accumulated data connection costs after the last invoicing. 17. Method in accordance with claim 1, characterized in that the data connection is set up in a digital cellular communication network with time-divided multiplex access. 18. Method in accordance with claim 2, characterized in that the data connection is set up in a digital cellular communication network with time-division multiplex access, and that the steps (20,22) to increase, respectively decrease, transmission speed for the data connection, are performed by increasing, respectively decreasing , the number of time slots allocated to the data connection. 19. Method according to one of claims 17 or 18, characterized in that the digital cellular network is any one of a GSM network, D-AMPS network, a PCS network or a PDC network. 20. Method in accordance with claim 1, characterized in that the data connection is set up via a separate terminal for digital cellular communication. 21. Method in accordance with claim 20, characterized in that the separate terminal is selected from a GSM terminal, D-AMPS terminal, a PCS terminal or a PDC terminal. 22. Method in accordance with claim 1, characterized in that the data connection is set up over an HSCSD service. 23. Method in accordance with claim 1, characterized in that application without the need for manual changes and adjustments in the user terminal (1) exists.