NO333595B1 - Method and device for service management in a communication network - Google Patents

Abstract

Device and method for handling services in a communication network that is accessible in various component parts of the communication network, where services can be requested from a party of the network who does not normally use a requested service. A service request message is routed to an information processor, which identifies the requested service and consults with an information database containing a connection between the network components and the services provided by the network components. Once the network components that provide the requested service are identified, the information processor initiates a communication session between the party initiating the service request message and the component that can provide the service.

Description

The present invention is directed to a method and a device in a communication network comprising a number of sub-networks, where each of the sub-networks includes services that may be different from that of other sub-networks, comprising an information processor configured to receive a service request message from a first subnet, where the service request message includes information on a service to be performed, and where the information processor is configured to identify the service. The information processor is adapted to retrieve subnets available to provide the requested service based on the various services identified from a database, and to initiate a message to establish a communication link with at least one of the identified services capable of to produce the service, and the information database is connected to the information processor, where the information database is arranged to identify various services associated with the sub-networks.

From patent literature reference is made to, among other things, US 5905777 A which describes a system where a recipient gets a reminder sent to a pager unit when a new email has been received. The email is received by an email server, which checks the message against a database to find out what kind of message it is and what kind of service is to be activated. The server performs the service by sending the e-mail over that other network. EP 0213277 A shows a directory-based database system that includes service requests over a distributed network environment. Furthermore, reference is made to US 5848415 A which describes an information database which is a content-based server with access to several networks, with extended protocol support for several clients.

In the information age, communication services and infrastructure to produce communication have become a commodity. As the information age develops, significantly more communication services are offered in various forms, each with different characteristics and serving different niche groups. In most countries, communications infrastructure, at least for telephone, has been established at one time or another by state development, or state-controlled monopoly, at least on some major level telephone-based networks somewhat compatible. However, more services have become available, such as cable television, wireless satellite connection, locally owned wireless loops, the Internet and other terrestrial networks. Where there is an increasing number of protocols and physical components required to support these services. To the extent that it is possible for the various communication networks to produce and share the information between the various networks, perhaps as a request from a caller, or data messages sent from one network to the next, the responsibility lies with each of the various networks to produce an adapted connection to the other networks. This is illustrated in fig. 1, where it is seen that various networks such as GSM 1, ISDN 3, public telephone network (PSTN) 5, cable television 7, electrical services 9, Ethernet 11, and Internet protocol (IP) 13, are networks that each provide individual connections between themselves in a "spaghetti-like" manner. In order to create a connection between the respective networks, the network connections are therefore made directly, which thus requires many conversion devices and adapters for each network.

As understood today, a limitation of this point-to-point connection method for existing network services is that each time a connection is needed between the various networks, each network must be equipped with a new adapter to be compatible with the new network. Adding the adapter is a straight forward process from a planning perspective, but implementation is very difficult and costs increase significantly each time a new service is brought online. Furthermore, such a system creates an introduction barrier for smaller owned networks which may eventually have to bear the burden of financing the costs of updating the adapters for other existing communication systems.

Within the telecommunications world, there are operators who have long offered telecommunications services within limited geographical areas. However, there are also new telecommunications operators, and other operators that present an opportunity to provide telecommunications and other communication services that may be compatible, or even competitors, with conventional telecommunications networks. E.g. Some of the new telecommunications operators include electrical distributors, cable TV operators, ISPs, wireless services such as LMDS, etc. Originally, these various "networks" each served different purposes, and were not configured to cooperate with each other since their services were on different basic areas. However, due to the significant deregulation of the telecommunications market in the United States and a number of other countries, it is currently believed that a change will occur on a global scale regarding the use of "non-conventional" resources to provide communications services. It is currently believed that while these various services may be available, in order to have a commercially viable system that offers the end-user (i.e. the subscriber) more commercially available services that fully enable the subscriber to have worldwide freedom of communication regardless of where the subscriber current is and plans to be in the future) are point-to-point converters or gateways, considered the solution. According to the configuration shown in fig. 1, it is up to the various systems themselves to work out the differences in protocols and communication capacities in order to establish communication between "unconventional" communication providers, if at all a communication link can be established.

With a background in the development of communication networks in the current deregulated era, the present inventors have understood that the conventional point-to-point approach to connecting different networks will necessarily create an economic barrier for new services that are desired to be introduced in the communication arena, due to that as new services come online, additional conversion and adapter equipment is necessary for all the other systems.

Today, each of the various networks has one feature in common: each network communicates information from one point to the next. When it comes to communication between different networks, language barriers (protocol differences) emerge, which must be overcome in order to share available resources between the different networks. The communication protocols are not different for different European languages. E.g. more often than not incompatible "native" languages are not an absolute barrier due to the diversity of the language skills possessed by many peoples. As it is perceived today, it is e.g. possible that when a person approaches another person and starts communication in language A, the other person will immediately be able to understand and converse in that language so that effortless communication can be carried out. However, it is often the case that when the first person starts communication with the second person in language A, but the second person understands that communication is not possible and tries to respond in language B, hoping that the original person will be able to speak language B. Using this "ping-pong" approach, the two people will eventually reach a decision as to whether there is a common language that can be spoken between the two. Once a common language is identified the two can communicate directly, however if there is no common language between the two, it will then be necessary to use a translator (a third person) to enable the two to speak to each other. The present invention exploits this concept to a certain extent, and produces a central possibility that helps to simplify, in a fast and efficient way, different communication protocols that can be common between the two different networks so that these networks can be operated in a direct communication mode. However, when communication is not possible, the central facility creates an infrastructure for transformation between the two languages (a translator function). Furthermore, the central facility helps to train both the first network and the second network, for future communication sessions, by effectively imparting to the various communication networks attributes of specific subscribers and networks used in all communication systems.

Different networks offer different technical solutions that try to adapt to the different types of services that require a connection to an address list, client files and the like. Usually, however, these solutions are limited to a specific type of service, or group of services in a specific network environment, such as public telephone switching network (PSTN), GSM, ATM, Internet, Intranet, etc. However, as previously considered, as the infrastructure for a global communication network that includes various communication sub-components (e.g. sub-networks), the problem arises regarding how different services are to be managed when connecting between network boundaries to the networks that make up the global network. Ideally, from a user perspective and from an implementation perspective, a request for services that occurs in a network, which is still performed using the resources of another network, should occur independently of the environment in which the user/client application exists. Furthermore, the overlying global structure of the network must be free of understandable restrictions regarding a user's ability to register in one of the other various networks that make up the global network. Regarding the possibility to register, it would be advantageous for a user to be fully registered across all the boundaries that exist in the composite network components, in order to have universal access to all services offered by the various networks as part of the global network. Accordingly, an option to register would ideally include the adaptability necessary to produce object, node and network topology independence, and which still meets the various requirements for call intensity, quality, price and performance, accessibility, security, functionality and geographical distribution. Furthermore, the structure of the global network made up of composite networks must produce seamless transition between the separate components to produce a service provider with full freedom to choose sub-suppliers, design concept, operating system, computer system, carrier network and geographical location for individual functional modules. However, in order to tailor a service structure according to the needs of an individual, it is currently considered that an effective solution will include user-defined links and data sets to functional modules. A problem with conventional system networks and global networks is that seamless boundaries between the various composite parts of the networks prevent the free flow of information between the boundaries, including limitations arising from inefficient access possibilities of services from users of another network.

In accordance with the title of the present invention, specific properties of the present invention are described herein. However, the section regarding detailed description of preferred embodiments provides a more complete listing of the features of the present invention.

One purpose of the present invention is to address the above-mentioned limitations with conventional systems and devices.

The above-mentioned problems associated with conventional devices and methods are avoided with the device and method according to the present invention. The present invention benefits from the features of the inventions corresponding to the previously mentioned concurrent applications, which help to establish seamless and efficient communication between the various communication networks as part of an overlying constitutional global communication network. So that as soon as the barriers between different communication networks that are part of the global communication network are resolved, the present invention produces a mechanism by which user information is processed in resources of the various communication networks in order to thus use the various services and attributes associated with the various communication networks that make up the the overlying network. Until now, information from the information user has been transferred to an information processor which extracts relevant information and which uses the extracted information to search an information database connected to the information processor or other information processors, in order to identify services which can be accessed and which satisfy the service request from the user. The information transmitted by the user may be in the form of a "cable" connection or a radio-based connection as both types of connections and networks supporting the same are built-in components of the networks according to the present invention. The information processor also collects information regarding specific services via one or more of the information databases, services may be implemented in the calling network (ie the network in which the user initiates the service request). The information database also stores additional information such as telephone numbers, addresses, service availability, unique user information, users, etc.

By implementing the present invention, services located in different environments that would otherwise be largely unavailable for normal use with sister networks become generally available to users of any of the networks. The present invention can be implemented regardless of the transmission technology used by the user, but instead enables services in all parts of the global network to be available to the user, even via protocols used within the various existing networks which may otherwise be incompatible. By enabling efficient communication between the various existing networks, each individual information processor only needs to handle a limited number of functional areas, such as user requests and service requests are routed to the relevant information processor that can support that service.

More specifically, according to the invention, a device is produced in a communication network comprising a number of sub-networks, where each of the sub-networks includes services that may be different from it to other sub-networks, comprising: an information processor configured to receive a service request message from a first sub-network, where the service request message includes information on a service to be performed, and wherein the information processor is configured to identify the service, the information processor is configured to retrieve subnets available to provide the requested service based on the various services identified from a database, and to initiate a message to establish a communication connection with at least one of the identified services capable of producing the service, and the information database is connected to the information processor, where the information database is arranged to identify various services for with the sub-networks, characterized in that the various services include protocol conversion necessary to produce the requested service, which are accessible as part of the network, in which the information processor is configured to communicate at least part of said service request message to another information processor, and that the information processor is configured to perform a predetermined operation, if the other information processor does not respond within a predetermined time period.

The information processor may be configured to receive the service request message from at least one of a wireless communication connection and a cable connection.

The second information processor may be configured to receive information from another database, thus identifying subnets that perform the requested service based on the various services identified from the second database.

The information processor may be configured to receive the service request message from a telephone network comprising at least one of a mobile telephone network and a computer network.

The information database can further include a data record associated with a user which includes at least one of a telephone number, an address, a service, subscriber or user.

The information processor can identify a service and establishes a connection with another subnet that is different from the subnet from which the service request message is initiated.

The information processor may initiate a communication session with a subnet in which the service identified by the information processor is to be performed.

Furthermore, the predetermined operation may be to establish a connection with a predetermined telephone number when at least two telephone numbers are connected to a called party.

Furthermore, a method is provided for identifying a sub-network, in a network comprising a number of sub-networks, which is capable of providing a requested service, comprising the steps of initiating a service request message, wherein the service request message includes information about a service to be is performed, and to route the service request message to an information processor, and to search a database for components of the network capable of performing a service requested in the service request message, and to create access to the sub-network identified in the search of the database, where the sub-network is able to perform the requested service, and that the service of the service request message is identified by the information processor, where the method also includes the steps: that the services include protocol transformations necessary to produce the requested service, in which the information processor communicates at least part of said service request message lding to another information processor, and that the information processor performs a predetermined operation, if the other information processor does not respond within a predetermined time period.

A more complete understanding of the invention and many of its associated advantages will be readily understood as the same proceeds with reference to the following detailed description when considered in conjunction with the accompanying drawings, in which: Fig. 1 shows a sketch of a conventionally developed approach to establish communication links between existing services, Fig. 2 shows a block diagram of composite components that are included as part of the present invention, Fig. 3 shows a block diagram showing a connection between information processors and databases and used according to the present invention, Fig. 4 shows a block diagram of a

information processor according to the present invention,

Fig. 5A and 5B show data structures of entries included in respective databases connected to the information processor, and Fig. 6 shows a flow diagram of a method used according to the present invention.

As previously discussed, the present invention includes infrastructure for establishing communication between various composite networks as part of a constitutional network, where the features and mechanisms that establish the mechanism for enabling seamless communication between the networks are described in the corresponding, concurrent US application previously discussed . Referring then to fig. 2 where information users 20 can include user applications for e-mail, IP telephony, and electrical service information, address monitoring functions, number analysis functions used in telecommunications networks, etc. These different users can thus be included in parts of different networks, which can otherwise use incompatible protocols. However, when specific service requests are generated from the information user 20, the question arises as to where such services may be located. According to the present invention, a communication link is established from the information user 20, through the connection mechanism 22, which may be a wireless link or a wired link, to an information processor 24. The information processor 24 then extracts service request information from the message and consults an information database 26 to identify different networks that offers the requested service. As soon as the identification of the network that can support the requested service is identified, the information processor 24 optionally informs the information user 20 through the connection mechanism 22, or alternatively establishes the connection through the connection mechanism 22, directly with the network that can perform the service.

Regarding the connection mechanism 22, the present invention is not limited to a specific type of protocol, but instead can support various types of protocols including SIP, HTTP, HTTPS, INAP, MAP, etc. These various protocols are in turn supported by an underlying transport protocol, such as IP and SS7, and various types of physical connections, including wireless links as well as cable links. The information processors 24 are on hardware platforms capable of collecting and processing applications from the information database 26. According to the present invention, examples of information processors include mobile servers, SIP servers, mail servers, web servers and the like. So that separate discrete information processors 24 are not necessary for use exclusively according to the present invention, but can instead have a primary purpose, such as providing e-mail server function, where an underlying service is to act as information processor 24 as discussed herein.

The information database 26 comprising a computer readable medium need not be located in a single geographically unique location, but may instead be distributed if necessary among a number of different computer readable media. This computer-readable medium in the information database 26 will include information such as telephone numbers of subscribers, addresses of subscribers, services offered by various networks, user identifications, users, etc. Number directories such as DNS, ILS, etc, are also examples of such databases.

When a service request is initiated by an information user 20, the service request will be transferred to an information processor 24 which can attempt to handle the question by itself if the information processor determines that it has the sufficient information. However, it is also a feature of the present invention that an information processor, such as the information processor 24A in fig. 3, will consult with another information processor, the information processor 24B, which may be specialized in a different functional area. The conditions for when and where an interaction with a number of information processors occurs may be unique to specific consumers or users, especially if the service request offered by that particular user is adapted to produce such a request. When the information processor, e.g. the information processor 24A, consults its database 24B, to determine whether the database 24B includes identification of resources capable of performing the service, the information processor 24A may then consult the information processor 24B in the form of a service request message and then receive information from its database 26B, and thus identify resources available to perform the requested service.

As an example, suppose that a person intended as the recipient of a telephone call has been assigned a telephone number, but depending on the time of day, day of the week, etc., different telephone numbers are used at different times of the day. The database 26B will handle this information as part of the user profile so that the telephone call can be routed most efficiently directly to the specific called party. When calling that party, the information processor assigned to the particular party will be called upon to determine the user's profile. The information processor then receives the necessary information and conveys that information back to the network terminal from which the information user initiates the call. In the event that an information processor fails to return a response within a predetermined time frame, the calling information processor may choose to use the information currently available and arrange a connection to the telephone number originally indicated or to an address indicated without having the full amount of information available from the user's profile.

In other cases, the calling subscriber may request a service specified by a different indication in the message sent to its own information processor. At this point, the requested service may be to arrange a conference connection between various incoming parties. The information processor will then communicate with the other processors to thus identify another of the information processors that will be able to handle the request and determine exactly how the connection can occur to thus implement the requested service. Once identified, the connection can be established automatically with the help of the processors, or alternatively, through the signal proxy mechanism to thus handle protocol conversions between the various networks.

Another example is that different individuals can communicate with each other and information from different databases or an individual database can be transferred to different participants in different versions, depending on the connection of the particular individuals with the networks on which they currently communicate. The individual responsible for initiating the communication will provide the information processor with the necessary information regarding which components of the information can be communicated to which participants, for private reasons. Likewise, each of the other participants can also indicate limitations regarding information that is provided to the other participants.

Fig. 4 shows a block diagram of the information processor 24. A system bus 410 interconnects a central processing unit (CPU) 401, which provides the processing infrastructure for a primarily software-driven information processor 24. The CPU 401 communicates over the system bus 410 with ROM 403, and RAM 402 which produces permanent and read/write memory capacity respectively. ROM 403 houses the application software for implementing the functions of receiving and interpreting the service request messages, coordinating communications between other information processors, and managing the information stored in a local database 26. Although respective mechanisms shown in FIG. 4 is primarily performed in software, parts of the processes can be performed in hardware, using application-specific integrated circuits 404 and field-programmable port groups 405. An I/O controller 408 provides communication between other components of the network, to receive and send service requests -messages, and coordinate messages between other information processors. A local I/O controller 409 establishes a communication connection with the database 26 to control read/write and data request operations. Expansion slot 411 is in the information processor 24 so that as additional resources become available to the global network, additional hardware can be included to support future processing requirements.

Fig. 5A shows a data structure for a specific user profile stored in the database 26 (Fig. 2). The data structure comprises three data fields (which may be stored in separate entries in the database, but which are nevertheless connected to each other). The data field 501 includes information regarding the particular user's identification. Included with the user ID is payment information, personal information regarding name and the like. In addition, the user ID will include subscriber-specific information such as the subscriber number that is uniquely associated with the particular subscriber. Field 503 comprises an updated network number, which is a specific number at which the subscriber can be located at a specific time, either as identified by the user profile also stored in the database (in field 505 to be discussed), or also by means of user-specific registration, when the user knows that the user will deviate from the normal pre-programmed plan previously stored in the database. The updated network number is quickly identified in the database, as well as the location by which the particular subscriber will be located when establishing a communication session. The data field 505 includes specific associations associated with a given object for the specific subscriber. In other words, the data field 505 (which may be more than one word in the database entry) comprises a plan for a particular subscriber comprising connections with various network numbers for the subscriber according to the particular time frames, as well as protocol attributes associated with the various objects by which the subscriber is connected. Fig. 5B shows another data structure for storing information regarding which services are available for various networks and network resources as part of the global communication network. A first data field 507 identifies particular networks. The data field 509 identifies various available services that are connected to the particular network identified in the data field 507. The data field 511 includes various management data regarding attributes and service requirements associated with providing services for the various available services identified in the data field 509. Fig. 6 shows a flow diagram of a process used according to the present invention. The process begins in step Sl, where a user initiates a service request message that is sent to an information processor. The process then continues to step S2, where the service request message is routed to the information processor associated with the user, or possibly in a second step to another information processor associated with the first information processor. As soon as the correct information processor has been identified, the process continues to step S3, where a database associated with the active information processor is searched for components in the network that can perform the requested services. The process then continues to step S4, where user-unique information and service-unique information are optionally stored in the database to thus update the database. The process then continues to step S5, where access to the requested service in the network is performed.

The mechanism and process set forth in the present description can be implemented using a conventional conventional microprocessor programmed according to what is described in the present description, which will be understood by one skilled in the art. Correct software coding can be readily prepared by experienced programmers based on the teachings of the present disclosure, which will be apparent to one skilled in the art.

The present invention thus also includes a computer-based product that can be accommodated in a storage medium and includes instructions that can be used to program a computer to carry out a process according to the present invention. The storage medium may include, but is not limited to, any type of disk including a floppy disk, optical disks, CD-ROM, magneto-optical disks, ROM, RAM, EPROM, EEPROM, flash memory, magnetic or optical cards, or any type of media adapted to store electronic instructions.

Various modifications and variations of the present invention are of course possible based on the above description. It must therefore be understood that within the scope of the appended claims, the invention can be practiced differently from what is specifically described herein.

Claims (9)

1. Device in a communication network comprising a number of sub-networks, where each of the sub-networks includes services that may be different from it to other sub-networks, comprising: - an information processor (24) configured to receive a service request message from a first sub-network, where the service request message includes information on a service to be performed, and where the information processor (24) is configured to identify the service, - the information processor (24) is arranged to retrieve subnetworks that are available to provide the requested service based on the various services identified from a database (26), and to initiate a message to establish a communication connection (22) with at least one of the identified services capable of providing the service, and - the information database (26) is connected to the information processor (24), where the information database ( 26) is designed to identify various services prohibited end with the subnets, characterized in that - the various services include protocol conversion necessary to produce the requested service, which are accessible as part of the network, in which - the information processor (24) is configured to communicate at least part of said service request message to another information processor (24B) , and that the information processor (24) is configured to perform a predetermined operation, if the second information processor (24B) does not respond within a predetermined time period. 2. Device according to claim 1, characterized in that the information processor (24) is configured to receive the service request message from at least one of a wireless communication connection (22) and a cable connection (22). 3. Device in accordance with claim 1, characterized in that the second information processor (24B) is configured to receive information from another database (26B), so as to identify sub-networks that perform the requested service based on the various services identified from the other the database (26B). 4. Device according to claim 1, characterized in that the information processor (24) is configured to receive the service request message from a telephone network comprising at least one of a mobile telephone network and a computer network. 5. Device in accordance with claim 1, characterized in that the information database (26) comprises a data registration associated with a user which comprises at least one of a telephone number, an address, a service, subscriber or user. 6. Device in accordance with claim 1, characterized in that the information processor (24) identifies a service and establishes a connection with another sub-network which is different from the sub-network from which the service request message is initiated. 7. Device in accordance with claim 6, characterized in that the information processor (24) initiates a communication session with a sub-network in which the service identified by the information processor (24) is to be performed. 8. Device in accordance with claim 1, characterized in that the predetermined operation is to establish a connection with a predetermined telephone number when at least two telephone numbers are connected to a called party. 9. Method for identifying a sub-network, in a network comprising a number of sub-networks, capable of providing a requested service, comprising the steps of initiating a service request message, wherein the service request message includes information about a service to be performed, and routing the service request message to an information processor (24), as well as to search a database (26) for components in the network that can perform a service requested in the service request message, and to create access to the sub-network identified in the search of the database (26), where the sub-network is capable of performing the requested service and that the service of the service request message is identified by the information processor (24), characterized in that the method also includes the steps: - that the services include protocol transformations necessary to produce the requested service, in which - the information processor (24) communicates at least part of said service request message to another information processor (24B), and that the information processor (24) performs a predetermined operation, if the second information processor (24B) does not respond within a predetermined time period.