FI111321B - Implementation of site-dependent services in a data communication system - Google Patents

Description

111321 IMPLEMENTATION OF LOCAL DEPENDENT SERVICES IN THE COMMUNICATION SYSTEM

FIELD OF THE INVENTION The invention relates to the provision of services in a mobile communication system. In particular, the invention relates to a method and system for implementing location dependent services, i.e. services utilizing the location of a mobile station in providing a service.

Background of the Invention

The rapid growth in the number of Internet users and the services offered on the Internet has been one of the most noticeable phenomena in telecommunications in recent years. Another current trend is the rapidly increasing use of wireless terminals. Wireless terminals include handheld roadmaps, PDAs (Personal Digital Assistant), and smart phones.

These two rapidly evolving network technologies, wireless communications and the Internet, are gradually converging, with the result that packet switched data services provided over the Internet are becoming available to mobile users. Many future services require the geographical location of a wireless 20-bit terminal in the network area.

Mobile network structure and mobility management in such a ver-v; BRIEF DESCRIPTION OF THE DRAWINGS With reference to Figure 1. The example of Figure 1 relates to a public GSM network, but other digital mobile communication systems have similar network elements. The data transmission between the network and the mobile station (MS) in the cell is handled by a radio path through a Base Tranceiver Station (BTS). The base stations are connected to a Base Station Controller (BSC). Usually, the base station controller controls a plurality of base stations, which can be chained to one another or directly connected to the base station controller, as shown in the figure. The geographic area covered by these base stations is called the si-30 Location Area (LA), and calls intended for mobile stations within that area are transmitted through these base stations. The mobile station can move within the location area without having to update the location information of the mobile phone.

A plurality of base station controllers are connected to a single Mobile Switching Center (MSC), which mainly handles the switching functionality of the mobile station 35. It also connects the mobile network to external networks. The combination of location areas 2111321 controlled by the mobile switching center is called a Switching Center Area (SCA). All calls that begin or end in the switching center area are routed through the same mobile switching center. If the mobile communication network includes multiple mobile switching centers, their SCAs together form the network domain of the mobile communication system, i.e., the geographic area covered by the network. The network is almost always operated by one organization (operator).

The mobile communication system still includes several databases. Subscriber information is permanently stored in the Home Location Register (HLR), regardless of the user's current location. If the network is large and there are 10 users, several HLRs are used. The number space is shared between these registers, which makes retrieving user information faster. The Visitor Location Register (VLR) is now integrated into each MSC, and user information retrieved from the HLR is stored in the VLR when the user visits the VLR area, i.e. the switching center area.

15 A location update is performed each time the user connects to the network. When the subscriber, for example in cell 1, Figure 1, turns on his mobile station, it signals a location update request to BTS 2, which request is routed via BSC 3 to MSC 1 and further to VLR 5. The registry requests the subscriber to send its subscriber ID from which VLR recognizes ti-20 broad HLR. The VLR then requests the subscriber's HLR to send the authentication parameters needed to identify the subscriber and encrypt the connection. When the subscriber has been successfully authenticated, the subscriber's HLR knows the VLR area, i.e. the MSC in which the subscriber is located, and sends the subscriber information to the VLR in question. The subscriber's location is now updated, i.e. the subscriber's HLR knows the address of the visited 25 VLRs, and the visited VLR knows the location area where the mobile station is located.

Location updates are also made each time the user moves from one location area to another. The location update initiative is initiated by the mobile station, which informs the VLR of the changed location area. If the location area is within the same 30 Central Areas (SCAs), i.e., managing the same VLR, there is no need to change the VLR address stored in the subscriber's HLR. The address is changed only when the subscriber moves to another central area, whereby the VLR of the visited area communicates its address to the HLR, and the HLR transmits the subscriber information to said VLR.

The location update can also be done periodically at certain intervals 35 (Periodic Location Update). Here, the location update is triggered when the timer threshold on the mobile station is reached.

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As discussed above, the location area is the largest area in which the MS can move without location update, and it is also the area in which the network calls a particular mobile station, i.e., the network knows the location of the mobile station with accuracy of the location area. The Location Area Identity (LAI) is used to indicate the 5 location areas that the mobile station has at any given time.

In addition to the LAI, the system has a single cell identifier called a Cell Global Identity (CGI). The network uses this identifier to differentiate between neighboring cells, i.e. it is not used in the traditional network to indicate the current location of a mobile station. The CGI structures are shown in Figure 2. The CGI consists of a mobile country code (Mobile Country Code, MCC, e.g., 244 in Finland), a mobile network code (MNC, which is an operator-specific parameter), a location area code, LAC) and Cell Identity (Cl).

However, as the geographic location of a mobile station has recently become more important for a wide range of applications, CGI can be utilized to locate a mobile station with a single cell resolution. In ISUP signaling (ISDN User Part), which is widely used in mobile networks, the base station signals to the CGI network when a connection between the mobile station and the 20 networks is established. The system can then use CG to determine the cell in which the mobile station is located.

Positioning accuracy may be better than a single cell if neighbor cell transmissions are utilized. Such a system is disclosed as a precursor in U.S. Patent No. 6,088,594. Said patent specification describes a system for graphically displaying the location of a mobile station on a terminal display. The system requires a browser on the terminal for the mobile to communicate with the web-based positioning application. The application sends a position request from the mobile station to the Mobile Positioning Center (MPC), which forwards the request to the 30 mobile switching centers serving the location area in which the mobile station is. Once at least three base stations have completed a position measurement, the measurement data is transmitted to a positioning center, where the position of the mobile station is determined using a triangular measurement algorithm. This geographical location (i.e., latitude and longitude) is transmitted to a positioning application which converts the pi-35 incentive information to the desired format and forwards it to the mobile station.

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Known positioning methods can also be used for continuous tracking of a terminal. International patent application WO 99/34611 describes a tracing method based on a location area table which describes a location area symbol as a geographical area. The location 5 of the terminal may be queried at desired intervals, and the results of each query may be stored in a tracking file.

The operation of the invention disclosed in this application is based on positioning methods such as the above, which improve the positioning accuracy of the conventional network so that the geographical location of the terminal is determined with the desired accuracy better than one location area.

For location-based services designed for wireless networks, the usual thinking is that customers want location-specific information such as bus or train schedules, local weather reports, directions, local advertising, and more. Thus, the basic premise of service design 15 and network implementation has been that the services are one-off, that is, the client downloads certain site-specific content.

The object of the present invention is to eliminate this limitation and to improve location-dependent services.

Brief Description of the Invention

It is an object of the invention to provide a method and system which enable the implementation of location-dependent services in a telecommunication system.

This object is achieved by the solution defined in the independent claims.

The starting point of the invention is to locate the user terminal using known positioning methods in order to determine the geographical location of the user. The idea of the invention is to associate a predetermined feature with certain specified geographical locations and maintain a database of user-specific records 30, the content of which is updated according to the features associated with the geographical locations in which the presence of the user has been successfully registered. Further, a predetermined condition is attached to the contents of the record, and the provision of the service to the user terminal depends on said content. More specifically, the service or service-related function is started when the content of the subscriber-specific record meets a predetermined condition.

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By utilizing the mechanism of the invention, service providers can design more versatile services because the range of services can now be expanded to include services that no longer depend not only on the user's current location but also on the user's behavior over a longer period.

5 In one preferred embodiment, the predefined geographic locations are service points of the service provider, and the attribute associated with each of the points may be, for example, credit.

The solution according to the invention can be used to create independent services, or the solution can be combined with a more traditional one-time service, whereby a value-added service is introduced.

List of figures

In the following, the invention and its preferred embodiments will be described in more detail with reference to the examples of Figures 3-6 in the accompanying drawings, in which Figure 1 illustrates a conventional mobile network, Figure 2 illustrates the structure of a CGI parameter used in conventional mobile networks; of the preferred embodiment of the system, Figure 4 is a flowchart illustrating a basic embodiment of the invention, Figure 5 illustrates the contents of a (service) point database used in the system, and Figure 6 illustrates the contents of a registration database used in the system.

Detailed Description of the Invention

Figure 3 is a schematic representation of the architecture of a system according to an embodiment 30 of the invention. According to the invention, a predetermined geographical location, indicated by the symbols A, B and C in the figure, is associated with a particular feature. Locations may be, for example, service points of a service provider, and the attribute associated with each location may be, for example, credit. The value of the credit assigned to each location indicates how much the user 35 will be credited if the system detects that the subscriber is located in an acceptable location near the point.

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As mentioned above, the method of the invention requires that the geographical location of the mobile station be first determined. The system of Figure 3 assumes that the mobile system location center 30 provides the geographical coordinates upon which the service is based. As the determination of coordinates is done in a manner known per se, it is not discussed in detail here. As noted above, several known mechanisms can be used to obtain said coordinates. The positioning center of a mobile communication system may be similar to the positioning centers of, for example, the aforementioned US 6,088,594.

10 The coordinates are submitted to the Geographical Information System (GIS) 31, which performs the analysis based on these coordinates. The GIS includes a metadata database 32 that contains the information needed to perform the analysis.

The system further includes a registration server 33 which includes a database 34 for subscriber-specific records. Each record contains information that depends on the properties associated with the locations where the user was successfully registered.

The registration server updates the contents of the user-specific record according to the result of the analysis in GSI, i.e. the registration information-20 strain is controlled by GIS. In addition, the registration server monitors the contents of a record for the purpose of detecting when the record meets a predetermined condition set for its content. When this occurs, the registration server sends a request to start a service or other action associated with the location-dependent service to the location-serving server 35.

Figure 4 is a flowchart illustrating the main steps of the process of the invention. Because the process is preferably initiated by the user, the location registration request is first obtained from the mobile station (step 40). In response to this user-initiated request, the location of the mobile terminal is measured. The measurement is preferably made by the mobile communication network, and the coordinates of the terminal 30 are calculated (step 41) at the positioning center of the mobile communication system. The GIS database contains a variety of information about the geographic locations associated with the service (that is, A, B, and C), which also includes the coordinates of those locations. Typically, the GIS performs proximity analysis (step 42) on the coordinates 35 received from the mobile system location center. This analysis determines whether the mobile terminal is in the immediate vicinity of the service points. The user may also provide additional information in connection with the registration request, specifying, for example, the point at which he wishes to register his location. This way, the GIS does not have to go through all the points, but can only analyze one point.

Based on the analysis, the GIS decides whether or not registration can be accepted (step 43). If the GIS detects that the mobile terminal is near the point and that all other conditions for acceptance of the registration are met, the GIS concludes that the mobile terminal is at an acceptable point. The GIS forwards the proximity analysis result to the registration server 33. In response, the subscriber-specific record contents in database 10 34 are updated (step 45). On the other hand, if the GIS detects that not all the conditions for registration approval are met, the location of the mobile station will be rejected. In this case, the GIS server may transmit the negative result information to the registration server and / or send a response to the mobile station (step 44). The message to the registration server is sent at least whenever the service is such that the contents of the record are updated in response to the location being rejected. This may be possible for some services, although for most services the upgrade is only in response to an approved location.

After updating the subscriber-specific record, the registration server examines whether the new contents of the record meet a predetermined condition (step 46). If so, the registration server sends a request to a service or service-related function to the location-serving server 35 (step 47). If the content does not meet the condition, the registration server may send a message to the mobile station informing the user of the successful registration and possibly also of the current contents of the record (step 46a). This message can be sent to the mobile station directly or via a content server.

Thus, the functional architecture of the system is based on the following processes: 1. determination of the geographical location of the mobile station; 2. analysis based on the geographical location in which; 30 deciding whether or not to accept the location of the mobile station; and 3. updating and monitoring the subscriber-specific record, wherein the service or service-related function is triggered based on the content of the record.

Figure 3 assumes that a user with a WAP-compatible terminal MS1 requests registration of his location from a server 35 that provides a location-35 dependent service and is typically an Internet node. As is known, the WAP architecture includes a gateway with encoders and decoders. In order to reduce the amount of data to be transmitted over the radio to the terminal, the encoder encodes the content received from the server into a compact coded form. Similarly, the decoder decodes the encoded data received from the radio channel before the data is transmitted to the server. The connections between the terminal and the Gateway 5 typically use WSP (Wireless Session Protocol), while the connections between the Gateway and the server typically use HTTP. Therefore, the gateway performs conversions from the WAP protocol stack (WSP, WTP, WTLS and WDP) to the WWW protocol stack (HTTP and TCP / IP). Gateway can also perform content conversions. If the server provides web content (such as HTML), the gateway can convert the web content to WAP content (WML).

When the user wants to register, the browser contacts the gateway server and sends a URL (URL) in the GET request that refers to the location-dependent service on the server 35. In response to the request, gate-15 way opens an HTTP connection to server 35 and sends an HTTP GET request to server 35. The server processes the registration request and starts location determination. The cellular network location center 30 is preferably, though not necessarily, located on the WAP gateway. In this case, the server 35 transmits to the gate-way server a standard HTTP GET message containing a location reference URL for the location update service 20. In response to this message, the WAP gateway requests location from the MSC. This request contains the MSISDN (Mobile Subscriber ISDN number) known to the gateway. The server may also send an HTTP GET message to the mobile system location center, which may request location either through the Gateway or directly from the MSC. However, handling traffic from the gateway to the 25 mobile networks is a better way in the sense that the gateway is an operator-controlled network element that in any case has a connection to the mobile network.

As a result of the location process, the cellular network location center 30 obtains location information from the mobile network. This information may simply be the identifier (CGI) of the cell in which the mobile station is currently located, or may comprise measurement information obtained from a plurality of base stations. Based on the information received from the mobile communication network, the location system of the mobile communication system can determine, using a known algorithm, the geographical location of the mobile station, i.e. its latitude and longitude.

35 If the cell identifier provides the location with sufficient accuracy, the system may use the location database 9111321 described in Finnish Patent Application FI-20002050 (the application is not public on the filing date of this application). Said database, referred to as 36 in Figure 3, is formed by routing call attempts through an intelligent network (IN) and storing location information in call data of call attempts to the IN database. From this database 5, a replicated database is made available to the services as a location database 36. In this case, the original message from the mobile station refers to the content on the content server. In response to this message, the content server or WAP gateway instructs the GIS to retrieve the current cell identifier of the mobile station from the location database and perform an analysis of the cell location-10 coordinates by comparing them with the coordinates of the service point (s).

Figure 5 is a simplified representation of the exemplary contents of database 32. The database includes, for example, service-specific tables 50 containing service points associated with a particular service. For each service point 15, the database contains at least the point identifier, the coordinates of the point, and the criteria needed to obtain the result of the analysis. The criterion field contains at least the maximum deviation allowed from the nominal coordinates of a point in proximity analysis. As mentioned above, each point can be associated with various additional location registration approval criteria, which may be 20 temporal (such as service point opening hours), point / user ID, etc. The table may also include data fields describing properties associated with each service point, such as credit. However, this field is optional because all points can have the same property, such as common credit, which is stored in separate GIS memory. Information about the features associated with each service point 25 may also be stored with the registration server. A simple application that leverages common credit is a system where each service point has a single credit value. The subscriber has a target value for the number of visits to one or more of the service points, whereupon the registration server examines whether this target value has been reached.

Figure 6 shows a simple example of the contents of subscriber-specific records. The figure assumes that the feature associated with the service points is a credit value, and that the condition set on the content of the record is that the accumulated credit must exceed the threshold for accumulated credit. In this case, the database 34 has subscriber-specific records SR, each containing credit already accumulated for a particular subscriber-35. Records may also include a threshold value for each subscriber, provided that a common value is not used for all subscribers. Each subscriber may have only one record, whereby the record contains the above information for all the services that the subscriber subscribes to, or each service may have a table containing a record for each subscriber of the service.

The content of subscriber records can also be examined if desired, generating various reports describing subscriber behavior. Instead of calculating a credit value for each location, the system can utilize more sophisticated statistical methods. For example, various peak detection or curve fitting methods can be used, such as Gaussian clock curve fitting to collected data. When the system receives enough data, a report can be generated which shows the user's habits. To avoid interference, statistical measures such as χ2 (Chi square) can be calculated. In addition, predefined conditions can be set, for example, that the value of χ must be close to one.

The method of the invention can be used in a variety of services, which may be either stand-alone services or a value-added service over another service. Here are some typical service drafts. First, the service provider can provide additional benefits to their customers who are registered with the service points often enough. For this purpose, the feature attached to the service points may be a credit such as the one described above, where the check-20 handles the credit values accrued to each subscriber. When the threshold is reached, a certain benefit is delivered to the subscriber or posted to the subscriber's account. By assigning different credits to different service points, the service provider can monitor subscriber usage. Secondly, the mechanism can be used to monitor work at different geographical points. Once the task has been successfully completed in one of the 25 points, the employee or his / her local supervisor can apply for registration and possibly provide additional information such as the job ID. The personal record can then influence the amount of compensation paid to the employee.

The service may also be combined with other services. For example, if said second service 30 is located on server 35, the server may initiate location registration when the subscriber downloads information from the server. In response, the subscriber will receive an additional bonus to their own record. When the bonus reaches a predetermined level, the subscriber is awarded a prize.

The feature that can be attached to each service point can also be data 35. Once the subscriber has collected enough information in his own record, the service provider can give him an advantage.

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Although the invention has been illustrated by the examples in the accompanying drawings, it is obvious that the invention is not limited thereto, but that one skilled in the art can modify the invention without departing from its scope and spirit. For example, database 32 does not have to be connected to the GIS or database registration server 34, but may be located elsewhere on the network.

Claims (10)

111321 A method for implementing location-dependent services to a mobile station connected to your wireless cellular network, the method comprising: 5. determining the location of the mobile station, characterized by: - associating a predetermined feature with the predetermined locations; in response to the analysis step, updating the subscriber-specific record with a feature attached to said predetermined location, - monitoring the contents of the record, and - triggering a service-related function when the content meets the predetermined condition. Method according to claim 1, characterized in that the updating step includes updating the parameter of the record. A method according to claim 2, characterized in that when the mobile station is in an acceptable position relative to a predetermined location, the value of the parameter is incremented by the credit value associated with said predetermined location. The method of claim 3, characterized in that said parameter is reset in response to the service being started. A method according to claim 1, characterized in that the step of analyzing determines whether the location of the mobile station corresponds to said predetermined position with a predetermined accuracy. 6. A method according to claim 1, characterized in that the step of analyzing determines whether another condition for a predetermined location is satisfied. A method according to claim 1, characterized in that said condition is related to the time of day. 8. A system for providing location dependent services to a mobile station, comprising: 35 positioning elements for determining the location of a mobile station, characterized in that the system further includes: 111321 - first means for attaching third bodies responsive to said other bodies for updating a subscriber-specific record by means of a feature attached to a predetermined location; and - third bodies responsive to third bodies for initiating a service-related function when the contents of the record meet a predetermined condition. System according to claim 8, characterized in that the other elements include a Geographical Information System. The system of claim 8, characterized in that the record includes a parameter and third members are adapted to update said parameter. 111321