JP3571632B2 - Semantic information network, semantic information switch, semantic information router, semantic information gateway, event routing method, and event routing device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention means that an end user can specify optimal information from among a huge amount of information distributed on a network, and that an information provider can specify an optimal user to distribute information. The present invention relates to an information network, a semantic information switch, a semantic information router, a semantic information gateway, an event routing method, and an event routing device.
[0002]
[Prior art]
The conventional network is conceptually represented by a network model shown in FIG. In FIG. 16, each terminal registers a terminal address (for example, a network address and a host address) in the network as its own identifier. On the other hand, the transmitting terminal sends an event composed of the destination address (transmission destination terminal address) and data shown in FIG. 17 to the network. That is, the basic concept of the conventional information network is to correctly deliver an event to a destination based on a destination address.
[0003]
A case will be considered in which a proposal type service (a personalized information proposal service for proposing personalized information for each user, and a yellow page service such as a search service) is realized using this network. Conventionally, in order to realize a personalized information proposal service, a centralized server system (broker) as shown in FIG. 18 must always be interposed. Similarly, the yellow page service also needs to assume a broker called a search service. Such a centralized business model via a broker is generally called a broker model. In this broker model, a broker (intermediary) plays a role of linking an information provider and a user. That is, the user and the information provider can only meet via the broker.
[0004]
[Problems to be solved by the invention]
By the way, distributed processing technologies such as WWW (World Wide Web) and CORBA provide an environment in which contents distributed on a heterogeneous distributed system can be easily obtained while being distributed, and anyone can easily provide contents. Made it possible to become a person. On the other hand, it is not easy for an end user to find desired content from a vast amount of content that is flooding the world, and it is desired to quickly establish a technology for realizing the content.
[0005]
The present invention has been made in view of such circumstances, and allows an end user to specify optimal information from among a huge amount of information distributed on a network, and to distribute information by an information provider. A semantic information network, a semantic information switch, a semantic information router, capable of directly searching, discovering, and specifying an entity to be communicated without going through a broker. An object of the present invention is to provide a semantic information gateway, an event routing method, and an event routing device.
[0006]
[Means for Solving the Problems]
The invention according to claim 1 isData and semantic information that is meta information of the dataInformation Network for Event DeliverysystemAndFor each event place that is a place for matching the event from the event sending entity to the filter that the event receiving entity has set the semantic information of the event desired to be received as the event acquisition condition, one or more semantic information switches A plurality of semantic information routers, wherein the semantic information switch matches the semantic information registered in advance as the filter with the semantic information included in the event, based on the matching result. Event transmitting means for notifying the event receiving entity corresponding to the filter of the event, the semantic information router, the semantic information switch between the semantic information switches belonging to the same event place, the event selection, the This is performed based on the contents of the semantic information, and between the semantic information switches. Having means for transferring definitive the eventIt is characterized by the following.
The invention according to claim 2, wherein the semantic information router requests the semantic information switch, which is the transfer source of the event, to register a filter, and receives the event from the semantic information switch as a result that matches the filter. Transferring the event to the other semantic information switch serving as a transfer destination, thereby realizing path selection of the event and transfer of the event..
The invention according to claim 3 is characterized in that only the name of the event type that is an event template is set in the filter for which the semantic information router requests registration..
[0007]
The invention according to claim 4, wherein the matching means of the semantic information switch, when a plurality of filters are registered, performs a matching process with a filter corresponding to the semantic information router, a filter corresponding to the event receiving entity. Is performed prior to the matching process with.
The invention according to claim 5, wherein the identifier of the semantic information switch that has passed as control information for an event to be transferred is held in the latest two identifiers, and the control information is referenced to prevent infinite transfer of the event. Characterized by further having.
According to a sixth aspect of the present invention, there is provided data and semantic information which is meta information of the data.Deliver an event consisting ofIn order to match the event from the event sending entity to a filter that the event receiving entity wants to receive the semantic information of the event you want to receive as an event acquisition condition, the event place,An event routing apparatus that determines an event delivery route based on semantic information included in an event,A plurality of event place objects that compare the semantic information registered in advance as the filter with the semantic information included in the event and transmit a matched event to the event receiving entity corresponding to the filter based on the result. Establishing a shared link that is a logical link for transferring events between the event place objects based on the physical link information of the event place object, and transferring the event between the event place objects.A shared link object generating means for generating a shared link object,When the one event place object (hereinafter, “EPO1”) registers the filter with itself, the event is transferred to the EPO1 from another adjacent event place object (hereinafter, “EPO2”) as the shared link. Notifying the shared link object of the fact, and requesting the EPO2 to register the filter when the shared link object receives the notification.Event path setting means.
[0008]
According to a seventh aspect of the present invention, when the shared link corresponding to event transfer from one event place object (hereinafter, “EPOj”) to another event place object (hereinafter, “EPOi”) is established. The shared link object generating means generates the shared link object on the same site as EPOi, and the shared link object establishes a session for receiving an event with EPOj and transmits an event to EPOi. Characterized by establishing a session for.
In the invention according to claim 8, in order to deliver an event consisting of data and semantic information which is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as the event acquisition condition. In the event place, which is a place for matching the event from the event sending entity to the filter, the semantic information registered in advance as the filter and the semantic information included in the event are matched based on the matching result. In a semantic information network system having a plurality of semantic information switches that notify the event to an event receiving entity corresponding to the filter, a semantic information router that performs a route selection of the event between the semantic information switches belonging to the same event place. Based on the content of the semantic information There are, performs routing of the events between the semantic information switch, characterized in that it comprises means for transferring said event between the semantic information switch.
The invention according to claim 9 is a semantic information network system that performs delivery of an event including data and semantic information that is meta information of the data, wherein the event receiving entity transmits the semantic information of the event desired to be received. For each event place that is a place for matching the event from the event sending entity to the filter set as the event acquisition condition, one or more semantic information switches and the event A semantic information gateway for performing forwarding, wherein the semantic information switch compares semantic information registered in advance as the filter with semantic information included in the event, and matches the event that matches based on the result of the matching. Means for notifying the event receiving entity corresponding to the filter The semantic information gateway includes means for holding a difference of ontology information between the event places as ontology conversion information, means for receiving the event from the semantic information switch belonging to a transfer source event place, and the ontology conversion information. Means for converting the received event into the ontology of the destination event place, and means for transferring the converted event to the semantic information switch belonging to the destination event place. To be.
[0009]
According to the tenth aspect of the present invention, in order to deliver an event including data and semantic information that is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as an event acquisition condition. A semantic information network system having a plurality of event places having a semantic information switch for notifying an event receiving entity corresponding to the filter of the matched event based on the matching result with respect to the event from the event transmitting entity against the set filter A semantic information gateway for transferring the event between different event places, wherein the means for holding a difference of ontology information between the event places as ontology conversion information; and meaning Means for receiving the event from the information switch, means for converting the received event into an ontology of an event place of a transfer destination using the ontology conversion information, and converting the converted event to an event place of the transfer destination. Means for transferring to the semantic information switch to which it belongs..
In the invention according to claim 11, in order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as an event acquisition condition. A semantic information switch on a semantic information network system having an event place, which is a place for matching an event from an event transmitting entity to a filter, wherein the semantic information switch is the semantic information registered in advance as the filter. Matching means for matching semantic information included in the event; means for notifying the event receiving entity corresponding to the filter based on the matching result to an event receiving entity corresponding to the filter; The filter is classified into Means for finely classifying and managing each session for event reception between the event receiving entity and the semantic information switch, wherein the matching means has a plurality of filters registered in the same session. In this case, the matching is sequentially performed on the plurality of filters, and if the matching result of one of the filters matches, the matching is not performed on the subsequent filters among the plurality of filters..
According to the twelfth aspect of the present invention, in order to deliver an event including data and semantic information which is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as an event acquisition condition. An event delivery method in a semantic information network system having a plurality of semantic information switches and one or more semantic information routers for each event place that is a place for matching an event from an event transmitting entity to a filter, The semantic information switch performs a matching process of comparing the semantic information registered as the filter in advance with the semantic information included in the event, and receives an event corresponding to the filter based on the matching result. Sending an event to notify the entity, The taste information router performs a process of selecting the route of the event between the semantic information switches belonging to the same event place based on the content of the semantic information and performing the transfer of the event between the semantic information switches. Characterized by having.
[0010]
According to a thirteenth aspect of the present invention, there is provided data and semantic information which is meta information of the data.Deliver an event consisting ofIn order to match the event from the event sending entity to a filter that the event receiving entity wants to receive the semantic information of the event you want to receive as an event acquisition condition, the event place,An event routing method in an event routing device that determines an event delivery route based on semantic information included in an event,A plurality of event place objects for comparing the semantic information registered as the filter in advance with the semantic information included in the event, and transmitting an event that matches based on the result to the event receiving entity corresponding to the filter. A shared link that is a logical link for event transfer between the event place objects based on physical link information between the event place objects, and transfers the event between the event place objectsA shared link object generation process for generating a shared link object,When the one event place object (hereinafter, “EPO1”) registers the filter with itself, the event is transferred to the EPO1 from another adjacent event place object (hereinafter, “EPO2”) as the shared link. Notifying the shared link object of the fact, and requesting the EPO2 to register the filter when the shared link object receives the notification.And an event path setting step.
In the invention according to claim 14, in order to deliver an event consisting of data and semantic information which is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as the event acquisition condition. In the event place, which is a place for matching the event from the event sending entity to the filter, the semantic information registered in advance as the filter and the semantic information included in the event are matched based on the matching result. In a semantic information network system having a plurality of semantic information switches for notifying the event to an event receiving entity corresponding to the filter, a routing method for selecting a route of the event between the semantic information switches belonging to the same event place. The contents of the semantic information Based on, performs routing of the events between the semantic information switch, characterized by having a process for transferring said event between the semantic information switch.
The invention according to claim 15, wherein in order to perform delivery of an event including data and semantic information that is meta information of the data, an event receiving entity sets the semantic information of the event desired to be received to the event acquisition condition. For each event place that is a place for matching the event from the event sending entity to the filter set as, one or more semantic information switches and semantic information for transferring the event between different event places An event delivery method in a semantic information network system having a gateway, wherein the semantic information switch matches semantic information registered in advance as the filter with semantic information included in the event, and matches based on the matching result. The received event corresponding to the filter Notifying an entity, the semantic information gateway includes a step of retaining a difference of ontology information between the event places as ontology conversion information, and a step of transferring the event from the semantic information switch belonging to a transfer source event place. Receiving, using the ontology conversion information, converting the received event into an ontology of a destination event place, and transmitting the converted event to the semantic information switch belonging to the destination event place. And a step of transferring..
[0011]
In the invention according to claim 16, in order to deliver an event composed of data and semantic information that is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as an event acquisition condition. A semantic information network system having a plurality of event places having a semantic information switch for notifying an event receiving entity corresponding to the filter of the matched event based on the matching result with respect to the event from the event transmitting entity against the set filter In the event transfer method for transferring the event between the different event places, a step of holding a difference of ontology information between the event places as ontology conversion information, and the method belonging to a transfer source event place. Semantic information Receiving the event from the switch, converting the received event to the ontology of the destination event place using the ontology conversion information, and belonging to the event place of the destination. Transferring to the semantic information switch..
In the invention according to claim 17, in order to deliver an event consisting of data and semantic information which is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as an event acquisition condition. An event delivery method on a semantic information network system having an event place, which is a place for matching an event from an event transmitting entity to a filter, wherein the semantic information registered in advance as the filter and the semantic information included in the event are included. A matching process for matching the semantic information to be performed, a process of notifying the event receiving entity corresponding to the filter based on the matching result to the event receiving entity corresponding to the filter, and classifying the filter for each event type that is a template of the semantic information. And the event receiving entity Subdividing and managing each session for receiving an event between the semantic information switch and the semantic information switch. In the case where a plurality of filters are registered in the same session, The filter is sequentially collated, and if the result of the collation matches one of the filters, the collation is not performed for the subsequent filters of the plurality of filters..
In the invention according to claim 18, in order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as the event acquisition condition. An event delivery program that performs event delivery in a semantic information network system having a plurality of semantic information switches and one or a plurality of semantic information routers for each event place that is a place for matching an event from an event transmitting entity to a filter. A recorded computer-readable recording medium, wherein the semantic information switch compares the semantic information pre-registered as the filter with the semantic information included in the event. Filter the matched events based on the filter And causing the computer to perform an event transmission process of notifying a corresponding event receiving entity, and in the semantic information router, select the route of the event between the semantic information switches belonging to the same event place, by using the content of the semantic information. And causing the computer to perform a process of transferring the event between the semantic information switches..
[0012]
In the invention according to claim 19, in order to deliver an event including data and semantic information that is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as an event acquisition condition. An event routing program that determines a route in an event routing device that determines a route of event delivery based on semantic information included in the event in an event place that is a place for matching an event from an event transmitting entity to a filter. A recorded computer-readable recording medium, wherein the semantic information registered in advance as the filter is compared with the semantic information included in the event, and an event matched based on the result is associated with the filter. The event reception entertainment A shared link, which is a logical link for event transfer between the event place objects, based on physical link information between the plurality of event place objects to be transmitted to the event place object, and transfers the event between the event place objects. When a shared link object generation process for generating a shared link object and the one event place object (hereinafter, “EPO1”) registers the filter in itself, the other event place object (hereinafter, “EPO1”) adjacent as the shared link is registered. "EPO2") to the shared link object which forwards the event to the EPO1, and notifies the shared link object of the event when the shared link object receives the notification. Characterized in that to perform the event path setting process in a computer for requesting registration of the data.
According to the twentieth aspect of the present invention, in order to deliver an event including data and semantic information that is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as the event acquisition condition. In the event place, which is a place for matching the event from the event sending entity to the filter, the semantic information registered in advance as the filter and the semantic information included in the event are matched based on the matching result. In a semantic information network system having a plurality of semantic information switches for notifying the event to an event receiving entity corresponding to the filter, a routing program for selecting a route of the event between the semantic information switches belonging to the same event place is recorded. Computer A recording medium capable of reading the event, based on the content of the semantic information, performing a process of selecting the route of the event between the semantic information switches and transferring the event between the semantic information switches to a computer. Characterized by.
The invention according to claim 21, wherein in order to perform delivery of an event including data and semantic information that is meta information of the data, an event receiving entity sets the semantic information of the event desired to be received to the event acquisition condition. For each event place that is a place for matching the event from the event sending entity to the filter set as, one or more semantic information switches and semantic information for transferring the event between different event places A computer-readable recording medium recording an event delivery program for delivering an event in a semantic information network system having a gateway, wherein the semantic information switch includes semantic information registered in advance as the filter and included in the event. See semantic information And causing the computer to perform a process of notifying the event receiving entity corresponding to the filter of the matched event based on the collation result. In the semantic information gateway, a difference of the ontology information between the event places is converted into ontology conversion information. Holding the event, receiving the event from the semantic information switch belonging to the transfer source event place, and converting the received event into an ontology of the transfer destination event place using the ontology conversion information. And processing for transferring the converted event to the semantic information switch belonging to the event place of the transfer destination..
In the invention according to claim 22, in order to deliver an event consisting of data and semantic information which is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as an event acquisition condition. Is the event sending entity for the filtered filter In the semantic information network system having a plurality of event places having a semantic information switch for notifying the event receiving entity corresponding to the filter of the event matched based on the matching result, A computer-readable recording medium on which an event transfer program for transferring the event between the event places is stored, wherein a difference between ontology information between the event places is stored as ontology conversion information; A process of receiving the event from the semantic information switch to which the event belongs, a process of using the ontology conversion information to convert the received event into an ontology of a destination event place, and a process of converting the converted event into the ontology of the destination. Ive Characterized in that to perform the processing to be transferred to the semantic information switch belonging to Topuresu the computer.
In the invention according to claim 23, in order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sets the semantic information of the event desired to be received as an event acquisition condition. A computer-readable recording medium recording an event delivery program for delivering an event in a semantic information network system having an event place which is a place for matching an event from an event transmitting entity to a filter, wherein A matching process of matching the registered semantic information with the semantic information included in the event, a process of notifying the event receiving entity corresponding to the filter of the matched event based on the matching result, Eventta that is a template Classifying the filter for each event, further subdividing and managing each session for receiving an event between the event receiving entity and the semantic information switch, and performing the collation process. If a plurality of filters are registered in the same session, the matching is performed sequentially for the plurality of filters, and if the result of the matching is the same for one of the filters, the matching is performed for the subsequent filters of the plurality of filters. Is not performed.
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
First, an outline of a Semantic Information-Oriented Network (hereinafter, referred to as a SION) will be described. The SION is a network that can deliver an event to a destination based on semantic information. FIG. 1 shows a conceptual model of the SION. In FIG. 1, each terminal 2 registers semantic information (Semantic Information: SI) in the SION 1. On the other hand, the terminal 2 transmitting the event sends an event composed of semantic information and data (Data) shown in FIG. Here, the semantic information describes the characteristics of the data included in the event, and is positioned as meta information of the data. For example, the semantic information is
・ Deliver the data to “Tokyo residents”.
・ Deliver the data to "people interested in classics".
-Deliver the data to "people who have a communication environment of 1 Mbps or more".
・ Deliver the data to "people who are passing through Mejiro Street".
Distribute the data to "content providers with content that matches the keyword (eg, travel)".
Is used.
[0014]
The SION dynamically determines a target (terminal, person, software, etc.) to which data should be delivered based on the semantic information as described above, and sends the data delivery and notification to the specified target person. It is an autonomous distributed meta-network that can be performed. By using the SION, it is possible to directly propose own information only to a user who is appropriate for the information provider to provide without using a broker. In this case, a business model capable of peer-to-peer information proposal in a broker non-intervening type (non-broker model) is referred to as a patronage model (or a patronage type information proposal model or a non-broker model). Call. Similarly, a real-time information search that allows a user to directly search for desired information without using a search service (broker) is also possible. In addition, it is possible to apply to the following services and the like as a request-for-listening information proposal service. .
(1) Manufacturing company: I want to send product information mainly to customers who are likely to be interested in their products.
(2) Advertiser: I want to send a personalized advertisement for each customer.
(3) Barter: I want to buy or sell or exchange products based on agreement between users.
[0015]
Note that what information is set in the data part of the event depends on the service. For example, various usage forms such as the entity of information, a reference to information (URL, distributed object identifier, etc.), a proxy (Jini proxy, etc.), a mobile agent, etc. are possible.
[0016]
Next, the details of the SION will be described.
<SION architecture>
First, the network architecture of the SION will be described. FIG. 3 shows a network model of the SION. Here, for convenience of explanation, the terminal 2 is separately described as a transmitting terminal 21 of the event sender and a receiving terminal 22 of the event receiver. The event receiver registers the semantic information (the type of the received event and the acquisition condition) of the event that the user wants to receive using the receiving terminal 22 as metadata in the SION1. This is called a filter. On the other hand, the event sender gives a stimulus (Incentive) to the SION by sending an event to the SION 1 using the transmission terminal 21. This event is composed of semantic information and data describing the characteristics of the event, as shown in FIG. FIG. 4 shows the definition of the semantic information. The semantic information is event metadata and is an instance of a semantic information type (event type).
[0017]
The ION 1 is an autonomous distributed collation network for collating (filtering) an event sent by an event sender with a filter registered by an event recipient. As a result of the comparison, the filter through which the event has passed (in response to the event) fires (Ignition), and the receiving terminal 22 of the corresponding event receiver starts autonomously. With this mechanism, it becomes possible to search and find the target terminal 2 in a scalable and real-time manner from an unspecified number of terminals 2.
[0018]
Next, the event type will be described. FIG. 5 shows an example of defining an event type which is an event template. As shown in FIG. 5, the event type includes an event type name (Event type name), a condition name (in FIG. 5, “Service” and “CPU power” correspond to each other), and a data type for each condition name ( And the conditional expressions (corresponding to == and> =) are defined. The event type name is a name for uniquely identifying the event type.
Note that the parent type of the event type can be inherited.
[0019]
As shown in FIG. 6, an event is created according to the data structure of the event type. An event includes an event type name, a combination of a condition name and a condition value, and a data part. If the condition name, condition expression, and condition value defined in the event do not match the event type, an error will occur. However, the condition names used in the event may be a subset of the event type.
[0020]
FIG. 7 shows a definition example of the filter. The filter includes an event type name (Event type name), an attribute name (corresponding to “CPU power” or “Age” in FIG. 7) and an attribute value (200 or 25 in FIG. 7). Consists of a pair. Only events belonging to the event type defined by the event type name to be accepted are subject to filtering. Here, a plurality of event type names can be defined, and by specifying a wild card (*. *), All events can be targeted. If the attribute name defined by the filter does not exist in the condition name of the event type defined by the event type name to be accepted, an error occurs. However, a subset of the event type may be used.
[0021]
Next, the configuration of the SION 1 will be described. FIG. 8 is a diagram showing a configuration of the SION1. As shown in FIG. 8, SION 1 is a semantic information switch (Semantic Information-Switch, shown as SI-SW in the drawing), a semantic information router (Semantic Information-Router, shown as SI-R in the drawing), a semantic information gateway. (Semantic Information-Getaway, shown as SI-GW in the drawing).
[0022]
The semantic information switch (SI-SW) collates the semantic information registered as a filter with the semantic information given to the event, and as a result, provides a switching mechanism for activating the terminal 2 of the event receiver who fired. The semantic information switch (SI-SW) and each terminal 2 are connected in a star type.
[0023]
The semantic information router (SI-R) plays a role of selecting an event route between the semantic information switches and transferring an event sent from the terminal 2 to the semantic information switch to another semantic information switch. This is achieved by dynamic event routing based on semantic information.
[0024]
The semantic information gateway (SI-GW) transfers an event between event places. Here, the event place is a minimum unit (ontology domain) that guarantees a common semantic information space. In the event place, the uniqueness of the ontology system such as the name, concept, vocabulary, meaning, and association of the event type is guaranteed, and semantic information is described based on a common ontology. Basically, an event sent from the terminal 2 of the event sender is distributed only within the event place, but is transmitted between event places having different ontology systems through the semantic information gateway (SI-GW). Can be mutually distributed. At this time, the semantic information gateway (SI-GW) transfers the event to a different event place after performing the ontology conversion of the event.
[0025]
<Operation mechanism and interface specifications>
As an example of a method of implementing the SION1, an implementation method using a distributed object technology will be described. Here, the SI-SW, SI-R, and SI-GW are implemented as distributed objects called event place objects (EPO), shared link objects (SLO), and federation agents (FA), respectively. The operation mechanism and control interface of the ION 1 will be described in detail with reference to FIG. Further, the network interface of the ION 1 can be used by using a MAN-Tool (Management Tool) or an ION interface. In addition, with the use of MT, withdrawal / increase / decrease of EPO, dynamic change of physical link information, PO migration (dynamic change of EPO to which PO is bound), collection of fire rate, It is possible to easily collect statistical information of existing information.
[0026]
・ Startup and initialization of Event Place Factory (Fig. 9 (1))
First, the SION operator activates an event place factory (EPF) on an arbitrary host, and subsequently initializes the EPF. At this time, a host name capable of generating an event place (EP) and a storage location of an executable file of the EP are given to the EPF. These are called EP generation information.
[0027]
-Event place generation request (Fig. 9 (2))
Next, the EP operator requests the EPF to generate an EP. At this time, an EP name and an EP attribute are given. Here, the EP attribute indicates whether the generated EP is used for a purpose-built model or an inquiry model, and indicates the direction of the flow of the event.
[0028]
・ Generation of event place (Fig. 9 (3))
Next, the EPF that has received the EP generation request generates an EP. Specifically, at this time, an event place management object (EPMO) for managing the EP is generated. That is, a processing request to the EP is synonymous with a processing request to the EPMO. The EPF returns the identifier of the generated EP (ie, EPMO) to the generation request source. The EPMO is generated for a dynamically determined host from among the hosts capable of generating an EP specified in (1) of FIG. As a method of determining a boot destination host of the EPMO, a method of cyclically determining a boot destination, determining according to traffic, explicitly specifying a boot destination host, or the like can be selected.
[0029]
• Event place initialization request (Fig. 9 (4))
Next, the EP operator requests EPMO to initialize the EP. At this time, a single event place object or a multiple event place object is designated. When a multiple event place object is specified, it is necessary to provide physical link information (topology) of the event place object (EPO) together. Here, the physical link information of the EPO expresses which other EPO knows which other EPO exists.
[0030]
For example, as shown in FIG. 10, EPO2.32 knows the existence of EPO1.31, EPO3.33, and EPO4.34, but expresses that EPO3.33 knows only the existence of EPO2.32. I have. As described above, the multiple EPO aims at improving the scalability by distributing the load of the event matching process in the EP.
[0031]
The EPMO dynamically determines a host that generates an EPO from a list of hosts that can generate an EP specified in (1) of FIG. 9 and generates an EPO there. At this time, each EPO is always accompanied by one filter factory (FF) and a statistical information collection object (SO), and these correspond to SI-SW. Further, a shared link object (SLO) is generated accompanying each EPO according to the number of physical links. For example, three SLOs are generated for the EPOs 2 and 32 (corresponding to SLOs 2, 1, SLOs 2, 3, and SLOs 2, 4 in the figure), and these correspond to SI-R. The method of determining the activation destination of EPO is the same as that of EPMO, but it is also possible to fix the EPO to be used for each event type. The EPMO generates an event type factory (ETF) in the EP. Within the EP, a centralized event type namespace is guaranteed by the ETF.
[0032]
A session establishment request for event transmission to the event place (Fig. 9 (5))
Next, it requests the EP to establish a session. EPMO generates a proxy object (PO) for each session request. The session identifier, which is the identifier of the PO, is returned to the request source.
Note that the EPMO instructs the PO which PO to use (to bind with which EPO) when the PO is generated. This instruction is required in the multiple EPO, but the method of determining the EPO to be bound is the same as that of the EPMO. When a session establishment request is made to the EP, it is necessary to specify whether the session is a session for transmitting an event or a session for receiving an event. In this example, a session for event transmission is specified.
[0033]
・ Registration of event type (Fig. 9 (6))
Next, the PO is requested to register the event type. At this time, the PO requests the ETF to generate an event type object (ETO). Further, the event type is stored in the generated ETO. On the other hand, an event type registration can be requested from the EP. At this time, the EPMO requests the ETF to generate an ETO, and stores the event type in the generated ETO. Generally, an event sender registers an event type via a PO. On the other hand, the EP operator registers an event type in the EP. Note that registering an event type with the same name will result in an error.
[0034]
-Session establishment request for event reception for event place (Fig. 9 (7))
Next, it requests the EP to establish a session for event reception. At this time, the requester of the session establishment (event receiving object) specifies the identifier of the event receiving object to which the event is to be notified and the event notification method (firing type, look-in type) as parameters. Give as.
Subsequently, the EPMO generates a PO for each session request. The session identifier is returned to the request source. The EPMO instructs the PO to use the EPO when the PO is generated. This instruction is required in the multiple EPO, but the method of determining the EPO to be bound is the same as that of the EPMO.
[0035]
-Filter object generation request (Fig. 9 (8))
Next, the PO is requested to generate a filter object (FO). At this time, the PO requests the FF to generate the FO. At this time, the FF attached to the EPO bound to the PO is used. The identifier of the generated FO is returned to the FO generation request source via the PO.
[0036]
Setting of filter value (Fig. 9 (9))
Next, the PO is requested to set a filter value in the FO using the FO identifier as a parameter. The ETO checks whether the data structure (filter value) of the FO is correct, using the event type name stored in the filter object (that is, the event type name to be filtered) as a key. Requesting is optional. If not, an error occurs. However, when a wild card is specified, this check processing is not performed at all.
[0037]
・ Filter registration (Fig. 9 (10))
Next, after setting the filter value in the FO, the PO is requested to register the filter using the filter identifier of the F as a parameter. At this time, the filter identifier is returned to the registration request source. With this, the event can be received. Note that a plurality of filters can be registered through one PO. (For this, a plurality of different FOs are registered as filters through one PO, or the same FO is registered as a filter a plurality of times.) However, all filters registered for one PO have an “OR relationship”.
[0038]
・ Event transmission (Fig. 9 (A))
Next, the event sender sends an event to the PO. At this time, the PO can selectively request the ETO to check whether the data structure of the event is correct, using the event type name stored in the event as a key. When this check process is selected, if it is correct, the process proceeds to the next process (FIG. 9B), and if it is not correct, an error occurs.
[0039]
-Event collation request (Fig. 9 (B))
Next, the PO forwards the event to the EPO. At this time, the EPO generates a thread. Note that a thread is generated for each event, and each thread performs multiplex processing of the event.
[0040]
-Collation with filter (Fig. 9 (C))
Next, the thread (EPO) performs a filtering process by comparing the event with the filter. This includes a perfect match, a partial match, a weighted match, etc., which can be specified when setting the filter value.
[0041]
-Start proxy object (Fig. 9 (D))
Next, when the event passes the filter as a result of matching with the filter, the corresponding PO is activated and receives this event. At this time, the PO can selectively register the received event type, value, event ID, and the like in the SO. From this information, the SO can measure the firing rate of the event (for each event type and each event) and the highly reputed events that are prevalent in the EP.
[0042]
-Activation of the event receiving object (Fig. 9 (E))
Next, the PO activates the event receiving object and passes the event to the event receiving object. This corresponds to the firing type (interrupt type) event notification.
[0043]
・ Look-in type event notification (Fig. 9 (F))
On the other hand, instead of the PO activating the event receiving object, the event receiving object itself can retrieve the event spooled in the PO corresponding to the event receiving object. This corresponds to a look-in type event notification. There are various triggers for activating the event receiving object depending on the service form. As a typical example, a case in which an end user issues a content proposal request to the event receiving object is considered.
[0044]
<How to manage filters>
Next, a method of managing a filter in each EPO will be described.
First, a session for receiving an event is established. At this time, one PO is generated for each session request, and this PO is bound to any one EPO. Each EPO is accompanied by one FF. As a result, the EPO used by the PO is uniquely determined, and all subsequent processing is performed via the PO (session for event reception).
[0045]
Next, an FO is generated, and a filter value (a type of an event to be received and its acquisition condition) is set for the FO. Subsequently, a filter is registered using the FO identifier as a parameter. At this time, the FO identifier is stored in each filter. Each EPO manages the filters registered via the PO based on the following rules.
First, using the FO identifier stored in the filter, the “type of event to be received” set in the FO is referred to. Subsequently, the filters are classified for each type of event to be received, and the filters classified for each event type are further classified and managed for each PO.
[0046]
Referring to FIG. 11, a description will be given of a case where a filter is registered via PO1 with respect to this management rule. Here, it is assumed that “event type X” is set in the FO specified at the time of filter registration as the type of event to be received. At this time, the filter registered in the EPO corresponds to the filter 1 in FIG. 11, and similarly, the filter registered via the PO2 corresponds to the filter 2. In each PO, a plurality of filters can be registered, but the registered filters have an “OR relationship”.
[0047]
First, when an event of the event type X arrives at the EPO, the matching with the filter 1 is performed. As a result, when the filter 1 fires, the PO1 is activated. Next, matching with filter 2 is performed, and as a result, when filter 2 fires, PO2 is activated. At this time, since the filters 2 and 3 have an “OR relationship”, the matching with the filter 3 is not performed. By using such a filter management method, the number of times of collation processing in each EPO for one event can be basically equal to or less than the number of POs (the number of reception sessions).
[0048]
<Event routing method>
Next, an event routing method will be described.
The EPO (SI-SW) accommodates event senders and receivers (entities such as terminals) in a star format via a session. Further, the EPO (SI-SW) checks the filter registered by the event receiver (event receiving object) against the event sent by the event sender, and as a result, only the event receiver corresponding to the fired filter receives the event. (Delivery of the event only to the matching event receiver).
[0049]
Therefore, as the number of event senders (the number of events) and the number of event receivers (the number of filters) increase, the processing capacity of the EPO becomes saturated in proportion thereto. Therefore, the SION architecture provides a multiple EPO as a means for realizing an EP having high scalability. The multiple EPO aims at scalably improving the total processing capacity of the EP compared to the number of EPOs, and specifically achieves high scalability of the EP from the following two viewpoints.
[0050]
The first point is load distribution and autonomous distribution. This is to distribute the load of event filtering processing by distributing event senders and receivers to a plurality of EPOs, so as to prevent a bottleneck factor accompanying processing concentration. . Furthermore, each EPO achieves distributed coordination by a mechanism that can operate autonomously without being affected by other EPOs.
[0051]
The second point is reduction of network traffic and optimization of the filtering process. This is to minimize the amount of communication by not transferring unnecessary events between EPOs, and to reduce unnecessary filtering processing.
[0052]
In FIG. 10, it is assumed that a filter of event type X is registered as a type of an event to be received in EPO3 • 33. Here, when an event of event type X is sent to EPO4, it is necessary to transfer this event to EPO3 via EPO2. At this time, the event must not be transferred to EPO1 in which the filter of the event type X is not registered. What controls such event routing between EPOs is a shared link object (SLO), which corresponds to the SI-R described above.
[0053]
Hereinafter, the SI-R will be described in detail.
First, at the time of EP initialization, an SLO is generated accompanying each EPO based on physical link information (EPO topology). For example, in FIG. 9, three SLOs are generated for EPO2. These correspond to SLO2,1, SLO2,3, SLO2,4 in the figure. This SLOi, j is from EPOjEPO iEstablish a shared link (SLi, j) for transferring an event to the server. That is, as shown in FIGS. 9 and 12, SLOi, j establishes an event reception session with EPOj, and establishes an event transmission session with EPOi, thereby establishing an event transfer session. A shared link SLi, j that is a logical link is established (a shared link means a session established by an SLO at the time of initializing an EP, and does not include a filter registration process).
[0054]
After initialization of the EP, event recipients can establish a session to the EP and register filters through the session. At this time, an event path is set according to the established shared link. For example, in FIG. 12, when the event receiver (Event Receiver) 3 registers a filter for performing event reception of the event type X in the EPO 3 via the PO 3, the PO 3 transmits the event type X filter to the EPO 3. In addition to the registration, the SLO3, j (here, SLO3, 2) notifies the fact to the SLO3, j.The SLO3, 2 registers the filter of the event type X with respect to the EPO2 by using SL3, 2. As described above, this is performed via the PO of the receiving session allocated to the SLOs 3 and 2. Similarly, this PO notifies the SLOs 2 and j other than the SLOs 2 and 3 of that fact. SLO2, j (j ≠ 3) registers the filters in the EPO using SL2, j. Path to the event X is until the set is repeated.
[0055]
A series of paths established for the event type X is called an event path. In this case, the filter registration via the PO3 is triggered, and the event path setting request for each event type is sequentially and autonomously transmitted to all EPOs. That is, each EPO needs to recognize only the adjacent EPO. For this reason, it is possible to establish the event path with a simple and unified autonomous logic as compared with the method of setting and managing the event path by centralized management or broadcasting of the event path.
[0056]
FIG. 13 shows the registration status of the filter in EPO1 at this time. As a result of the event receiver 3 registering the filter via the PO3, the filter 1 is registered in the EPO1. Setting an event path refers to registering a filter for event transfer in a series of EPOs based on shared link information. Further, only the event type name to be received is set in the filter registered by the SLO, the acquisition condition is not set, and filtering is performed only on the event type name.
[0057]
In this situation, when the event receiver 2 registers the filter of the event type X to the EPO2 via the PO2, the setting of the new event path spreads to all the EPOs as described above. 2 is registered in the EPO 1, and a filter is registered for each event path setting request.
[0058]
At this time, when an event of the event type X is sent to the EPO1, the filter 1 is fired and the SLOs 2, 1 are activated. SLO2,1 sends this event to EPO2, so that SLO3,2 is activated. Further, the event is transferred to the EPO 3 via the SLOs 3 and 2. In order to prevent infinite transfer of events between SL2,3 and SL3,2, the event holds, as one of the control information, a maximum of two identifiers of the passed EPO in the latest order.
[0059]
As described above, since the filter 1 and the filter 2 have an OR relationship, if the filter 1 fires, the filter 1 and the filter 2 are not collated. Therefore, it is possible to prevent the redundant overhead of the filtering process caused by newly registering the filter 2 even though the filter 1 exists. This means that when an event path is set, there is no need to rebuild all event paths including the existing event path, and simple and unified event path autonomous setting becomes possible. .
[0060]
If there is a session established by the event receiver and a filter registration via the session in the EPO 1 (corresponding to the filter 3 of POn), the filtering of POn is completed after all the filtering processes of SLO are completed. Processing is performed. In other words, the event transfer process to another EPO is performed with priority, and then the collation process in the own EPO is started.
[0061]
A further effect of the event routing method described above is that it is not necessary to reconstruct an event path when deregistering a filter. For example, when the event receiver 3 cancels the registration of the registered filter via the PO3, the cancellation request sequentially and autonomously spreads, similarly to the case of the registration. As a result, only the registration of the filter 1 is canceled in the EPO1, but the filter 2 survives (hereinafter, the filter 2 transfers the event instead of the filter 1), and thus the event path is reconstructed. Without it, the consistency of all existing event paths is guaranteed.
[0062]
By using such an autonomous distributed routing control method, it is possible to easily realize interconnection and distributed coordination of EPO. Accordingly, a transition from a small network to a large network, a transition from a local network to a global network, and the like can be smoothly performed. In addition, global networking by a bottom-up approach can be easily achieved with common logic.
[0063]
<Federation method>
Next, a federation method will be described with reference to FIG. The federation agent (FA) is an agent that establishes a federation between event places, and corresponds to the above-described SI-GW. For example, consider a case where event place (Event Place) A establishes a federation with event place (Event Place) B. First, an FA belonging to event place A registers a filter for event place B. At this time, the event sender belonging to the event place B sends an event, and as a result, when this filter fires, the FA autonomously starts. This may regard the FA as one event recipient belonging to event place B. Next, the FA retransmits the acquired event to the event place A to which the FA belongs. This can regard the FA as one event sender belonging to event place A.
[0064]
As described above, it is possible to easily realize the federation between the event places by using the FA having both roles. That is, it is possible to realize the federation between the event places with the same control logic as that of the single event place. By interconnecting event places, which are the basic constituent units of SION1, using this mechanism, it is possible to construct a global collation network from a bottom-up approach, and realize sharing of events across event places. Can be. When the event place A and the event place B have different ontologies, the FA belonging to the event place A converts the event acquired from the event place B into the ontology of the event place A, and then sends out the event place A. .
[0065]
When performing event transfer across different ontology systems, ontology conversion is required. As a conventional technique for performing this conversion, when a standard ontology is defined and an event is transferred to another event place, a method of transferring the event after temporarily converting the event into a format conforming to the standard ontology, an event place There are methods such as preparing an ontology conversion table for the number of combinations in advance.
[0066]
However, the conventional method lacks flexibility to support dynamic federation of event places (dynamic start and release of federation). Therefore, in the present invention, as shown in FIG. 14, only the difference (conversion information) from the ontology information of the event place adjacent to the FA is stored in the ontology conversion table. In other words, this is a method in which each FA stores the conversion information in a distributed manner, and assures the consistency of the ontology system as a whole. This makes it possible to easily cope with dynamic federation between event places, but on the other hand, every time an event straddles an event place, an ontology conversion process occurs. It has the feature that processing overhead increases.
[0067]
<Community and Evolving Network>
Next, a community service, which is one of the killer services of SION1, will be described. An entity in a community service is an autonomous decentralized operation entity that can dynamically determine an activity mode by repeating learning, evolution, degeneration, and disappearance based on its own policy. Communities provide an efficient forum for such entities to communicate. That is, an entity in the community can dynamically search, discover, and identify an entity that should communicate with itself and an entity that affects its own behavior, and can interact with the identified entity.
[0068]
This community can handle entities with the following characteristics in particular:
(1) There is a huge number of entities in a community with a very small granularity (an unspecified number of entities).
(2) The attributes of the entity change in real time. Typical entity attributes include position information, time, and the like.
(3) The behavior of the entities in the community is not regular, and it is difficult to predict the behavior.
(4) Participation in the community, departure from the community, disappearance, duplication, etc. occur frequently and irregularly.
(5) Entities in a community need to meet each other in real time based on policies, attributes, scenarios, and the like.
[0069]
It is not easy in terms of performance to manage entities having such characteristics by a server or a mediator (broker) and to search and discover each other in real time. The EP of the SION1 is positioned as an execution environment of a community having such characteristics. That is, the community is a meta execution environment of the EP, and provides a place of communication with a higher level of abstraction than directly using the EP. By using EP for the execution environment of the community, all the entities in the community can directly discover the entity to communicate with without going through the broker. This is because communication of entities in the community is implemented as sending and receiving events in the EP.
[0070]
FIG. 15 shows a conceptual model of a community. A user agent (UA) and an information and service providing agent (ISA) correspond to entities in a community. UA isAn agent that behaves autonomouslyIt dynamically determines its own behavior according to the user's preference, operating environment, location information, situation, tendency, etc., searches for ISAs and other UAs to interact with, and interacts with them. ISAAlso act autonomouslySearch for UAs and other ISAs to interact with based on the provider's intention. That is, a user suitable for providing his / her information is searched for and specified.
[0071]
On the other hand, a community agent (ComA) is an agent that manages a community. The EP operator controls and operates the SION via the SION-MT based on the operation policy. Accordingly, the ComA can be regarded as an agent of the EP operator. Basically, the operational policy of the community is defined by ComA. For example, UAs, ISAs, and other entities are allowed to participate in the community, leave, disappear, and be duplicated, etc., grasp and control of information distributed in the community (deletion of inappropriate events, etc.), and statistical information (trend information) in the community And reputable information) based on their own management policies.
[0072]
In addition, in order to achieve high scalability and reliability of the community, SION control such as increase / decrease, withdrawal, and migration of EPs and EPOs is executed according to the load status and the failure status. That is, by combining ION1 and ComA, ION1 evolves from an autonomous decentralized network to an evolved network that can learn, grow, and evolve. In this way, the ComA controls the behavior of the entities in the community and plays a role in self-organizing SION1. Further, the collaboration between the communities enables the sharing of information between the communities. For example, among the information distributed in the community A, only the top 10 most popular can be distributed to the community B. The processing flow is shown below.
[0073]
First, the ComA of the community B instructs the FA of the event place B to “distribute only the top 10 most popular information among the information distributed in the community A to the community B”.
[0074]
Next, the FA inquires of the event place A about the top ten event types. In response, the event place A inquires the subordinate statistical information collection object (SO) and returns the result to the FA.
[0075]
Next, the FA creates an ontology conversion table based on the acquired event type, and sets a filter for the event place A. Thereafter, the FA can receive the event from the event place A.
[0076]
Next, the FA converts the event obtained from the event place A into an ontology based on the ontology conversion table, and sends the event to the event place B.
[0077]
As described above, according to this embodiment, the following two effects can be obtained.
First, a SION network environment can be easily constructed on a distributed object environment.
Second, by allowing the service application to participate in the community as an entity, it is possible to easily send out an event or to pick up a necessary event, thereby enabling mutual communication.
[0078]
【The invention's effect】
As described above, according to the present invention, the following effects can be obtained.
With the federation mechanism between event places via FA, an event that has been distributed only in other event places can be taken into its own event place. Conversely, by sending an event to another event place, it is possible to advertise the event distributed in the own event place. In this way, events can be shared between different event places, and interoperability between event places considering ontologies makes it possible to construct a global autonomous decentralized collation network using a bottom-up approach. Become.
[0079]
The multiple EPO mechanism makes it possible to distribute the load of the filtering process to a plurality of EPOs, and the event routing mechanism between the EPOs that operates autonomously makes it possible to minimize network traffic. As a result, the total throughput of the EP can be scalably improved.
[0080]
It is possible to directly search and find an entity suitable for itself without going through a broker. For example, the information provider can specify a user who is appropriate for the information provided by himself without knowing the existence of the user. Similarly, the user can search for and find an information provider suitable for his / her taste without knowing the existence of the information provider. That is, the user and the information provider are transparent to each other. As a result, information can be transmitted in real time according to its own policy without relying on a specific broker. Further, when the number of entities to be searched is enormous or when the entities frequently enter and leave the search target domain, the search technique based on the non-broker model is particularly effective.
[0081]
In the SION, the end point of the semantic information is the network. On the other hand, in the method of performing a peer-to-peer connection between terminals, the terminal of the semantic information is the terminal, so that the contents of the terminal are disclosed to the outside. Therefore, SION can realize higher security and privacy protection than the latter method.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an embodiment of the present invention.
FIG. 2 is an explanatory diagram showing a configuration of an event.
FIG. 3 is a diagram showing a model of a semantic information network.
FIG. 4 is an explanatory diagram showing a definition of semantic information.
FIG. 5 is an explanatory diagram showing a definition example of an event type.
FIG. 6 is an explanatory diagram illustrating an example of an event.
FIG. 7 is an explanatory diagram illustrating a definition example of a filter.
FIG. 8 is a diagram showing a configuration of a semantic information network.
FIG. 9 is an explanatory diagram showing an operation mechanism and a control interface of the semantic information network.
FIG. 10 is an explanatory diagram showing a physical link.
FIG. 11 is an explanatory diagram showing a filter management method.
FIG. 12 is an explanatory diagram showing an event routing method.
FIG. 13 is an explanatory diagram showing a registration status of a filter.
FIG. 14 is an explanatory diagram showing a federation method.
FIG. 15 is an explanatory diagram showing a community model.
FIG. 16 is an explanatory diagram showing a conventional technique.
FIG. 17 is an explanatory diagram showing a conventional technique.
FIG. 18 is an explanatory diagram showing a conventional technique.
[Explanation of symbols]
1 ... semantic information network (SION),
2 ... terminal,
SI-SW: Meaning information switch,
SI-R: semantic information router,
SI-GW ... semantic information gateway,
EPO: Event place object,
SLO: Shared link object,
FA: Federation agent.

Claims (23)

A semantic information network system for delivering an event including data and semantic information that is meta information of the data ,
For each event place, which is a place for the event receiving entity to match the event from the event sending entity to the filter that has set the semantic information of the event desired to be received as the event acquisition condition,
Having a plurality of semantic information switches and one or more semantic information routers,
The semantic information switch,
A matching unit that matches the semantic information registered in advance as the filter with the semantic information included in the event,
Event transmitting means for notifying the event receiving entity corresponding to the filter of the event matched based on the matching result,
Has,
The semantic information router,
Means for selecting the route of the event between the semantic information switches belonging to the same event place based on the contents of the semantic information and transferring the event between the semantic information switches
Semantic information network system characterized <br/> to have. The semantic information router,
Requesting a filter registration from the semantic information switch that is the transfer source of the event, receiving the event from the semantic information switch as a result that matches the filter, and sending the event to the other semantic information switch that is the transfer destination 2. The semantic information network system according to claim 1, wherein the transfer realizes path selection of the event and transfer of the event. 3. The semantic information network system according to claim 1, wherein only the name of an event type that is an event template is set in a filter for which the semantic information router requests registration. 4. The matching means of the semantic information switch, when a plurality of filters are registered, gives priority to matching processing with a filter corresponding to the semantic information router over matching processing with a filter corresponding to the event receiving entity. 4. The semantic information network system according to claim 2, wherein the semantic information network system performs the operation. Means for retaining the two identifiers of the semantic information switches passed as control information for the transferred event in the latest order, and preventing the infinite transfer of the event by referring to the control information. Item 5. The semantic information network system according to any one of Items 1 to 4. In order to deliver an event consisting of data and semantic information that is meta information of the data , the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. An event routing device that determines an event delivery route based on semantic information included in the event in an event place that is a place for matching
A plurality of event place objects that compare the semantic information registered as the filter in advance with the semantic information included in the event and transmit a matched event based on the result to the event receiving entity corresponding to the filter. A shared link that is a logical link for transferring an event between the event place objects based on the physical link information of the event place object, and generates a shared link object that transfers the event between the event place objects. Means,
Transfer the said one of the event place object (hereinafter "EPO1") to register the filter itself, the other of said adjacent a shared link event place objects (hereinafter, "EPO2") of the event from to the EPO1 An event path setting means for notifying the shared link object to that effect, and requesting the EPO 2 to register the filter when the shared link object receives the notification. Routing device. When establishing the shared link corresponding to an event transfer from one of the event place objects (hereinafter “EPOj”) to another event place object (hereinafter “EPOi”),
The shared link object generating means generates the shared link object on the same site as EPOi,
7. The event routing apparatus according to claim 6, wherein the shared link object establishes a session for event reception with EPOj and establishes a session for event transmission with EPOi. In order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. In the event place, which is a place for matching
Semantic information having a plurality of semantic information switches for notifying the event receiving entity corresponding to the filter of an event that matches based on a result of matching the semantic information registered in advance as the filter with the semantic information included in the event. In a network system, a semantic information router that performs route selection of the event between the semantic information switches belonging to the same event place,
Means for selecting the route of the event between the semantic information switches based on the content of the semantic information and transferring the event between the semantic information switches
A semantic information router characterized by that: A semantic information network system for delivering an event consisting of data and semantic information that is meta information of the data,
For each event place that is a place to match the event from the event sending entity against the filter that the event receiving entity wants to receive the semantic information of the event as the acquisition condition of the event,
One or more semantic information switches, having a semantic information gateway for transferring the event between different event places,
The semantic information switch,
Means registered in advance as the filter and the semantic information included in the event are compared, and means for notifying the event receiving entity corresponding to the filter of the event that is matched based on the comparison result,
The semantic information gateway,
Means for holding a difference in ontology information between the event places as ontology conversion information;
Means for receiving the event from the semantic information switch belonging to a transfer source event place,
Means for converting the received event into an ontology of an event place of a transfer destination using the ontology conversion information;
Means for transferring the converted event to the semantic information switch belonging to the event place of the transfer destination.
A semantic information network system, characterized in that: In order to perform delivery of an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends a filter, which has set the semantic information of the event desired to be received as an event acquisition condition, from the event transmitting entity. A plurality of event places having a semantic information switch for matching the event and notifying the matched event based on the matching result to an event receiving entity corresponding to the filter are provided. A semantic information network system for transferring the event between different event places,
Means for holding a difference of ontology information between the event places as ontology conversion information,
Means for receiving the event from the semantic information switch belonging to a transfer source event place,
Means for converting the received event into an ontology of an event place of a transfer destination using the ontology conversion information;
Means for transferring the converted event to the semantic information switch belonging to the event place of the transfer destination.
A semantic information gateway characterized by that: In order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. A semantic information switch on a semantic information network system having an event place that is a place for matching
The semantic information switch,
A matching unit that matches the semantic information registered as the filter in advance with the semantic information included in the event,
Means for notifying the event receiving entity corresponding to the filter of the event matched based on the matching result,
A means for classifying the filter for each event type that is a template of semantic information, and further sub-classifying and managing for each session for event reception between the event receiving entity and the semantic information switch,
Has,
When a plurality of filters are registered in the same session, the matching unit sequentially performs the matching on the plurality of filters, and if the matching result of one of the filters matches, the subsequent filter among the plurality of filters is used. A semantic information switch characterized in that no collation is performed. In order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. An event delivery method in a semantic information network system having a plurality of semantic information switches and one or a plurality of semantic information routers for each event place that is a place for matching
The semantic information switch,
A matching step of matching the semantic information registered in advance as the filter with the semantic information included in the event,
An event transmitting step of notifying the event receiving entity corresponding to the filter of the event matched based on the matching result,
The semantic information router,
Selecting a route of the event between the semantic information switches belonging to the same event place based on the contents of the semantic information and transferring the event between the semantic information switches.
An event delivery method, characterized in that: In order to deliver an event consisting of data and semantic information that is meta information of the data , the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. An event routing method in an event routing device that determines an event delivery route based on semantic information included in the event in an event place that is a place for matching
A plurality of event place objects for comparing the semantic information registered as the filter in advance with the semantic information included in the event, and transmitting an event that matches based on the result to the event receiving entity corresponding to the filter. A shared link object that establishes a shared link that is a logical link for transferring events between the event place objects based on physical link information between the event place objects and generates a shared link object that transfers the event between the event place objects. Generation process,
When the one event place object (hereinafter, “EPO1”) registers the filter with itself, the event is transferred to the EPO1 from another adjacent event place object (hereinafter, “EPO2”) as the shared link. An event path setting step of notifying the shared link object to that effect, and requesting the EPO 2 to register the filter when the shared link object receives the notification. . In order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. In the event place, which is a place for matching
Semantic information having a plurality of semantic information switches for notifying the event receiving entity corresponding to the filter of an event that matches based on a result of matching the semantic information registered in advance as the filter with the semantic information included in the event. In a network system, a routing method for selecting a route of the event between the semantic information switches belonging to the same event place,
A step of selecting the route of the event between the semantic information switches based on the contents of the semantic information and transferring the event between the semantic information switches.
A routing method, characterized in that: In order to deliver an event consisting of data and semantic information that is meta information of the data, an event transmitting entity sets a semantic information of the event that the event receiving entity desires to receive as a condition for acquiring the event as an event transmitting entity. For each event place that is a place to match the event from
An event delivery method in a semantic information network system having one or more semantic information switches and a semantic information gateway that transfers the event between different event places,
The semantic information switch,
Semantic information pre-registered as the filter, collating the semantic information included in the event, and having a step of notifying the event receiving entity corresponding to the filter the event matched based on the collation result,
The semantic information gateway,
Holding the difference of the ontology information between the event places as ontology conversion information;
Receiving the event from the semantic information switch belonging to a transfer source event place;
Using the ontology conversion information, converting the received event into an ontology of a transfer destination event place;
Transferring the converted event to the semantic information switch belonging to the event place of the transfer destination.
An event delivery method, characterized in that: In order to perform delivery of an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends a filter, which has set the semantic information of the event desired to be received as an event acquisition condition, from the event transmitting entity. Said In a semantic information network system having a plurality of event places having a semantic information switch for causing an event to be matched and notifying the event receiving entity corresponding to the filter of the matched event based on the matching result, An event transfer method for transferring an event,
Holding the difference of the ontology information between the event places as ontology conversion information,
Receiving the event from the semantic information switch belonging to a transfer source event place;
Using the ontology conversion information, converting the received event into an ontology of a transfer destination event place;
Transferring the converted event to the semantic information switch belonging to the event place of the transfer destination.
An event transfer method, characterized in that: In order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. An event delivery method on a semantic information network system having an event place that is a place for matching
A matching step of matching the semantic information registered as the filter in advance with the semantic information included in the event,
Notifying the event receiving entity corresponding to the filter of the event matched based on the matching result,
Classifying the filter for each event type that is a template of semantic information, further sub-classifying and managing for each session for event reception between the event receiving entity and the semantic information switch;
Has,
In the matching process, when a plurality of filters are registered in the same session, the matching is sequentially performed on the plurality of filters, and if the matching result of one of the filters matches, a subsequent filter among the plurality of filters is used. An event delivery method characterized in that no collation is performed. In order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. For each event place that is a place for collating, a computer-readable recording medium that records an event delivery program that performs event delivery in a semantic information network system having a plurality of semantic information switches and one or more semantic information routers. So,
In the semantic information switch,
The semantic information registered in advance as the filter, and a collation process for collating the semantic information included in the event,
Causing the computer to perform an event transmission process of notifying the event matched based on the matching result to an event receiving entity corresponding to the filter,
In the semantic information router,
The computer selects a route of the event between the semantic information switches belonging to the same event place based on the contents of the semantic information and performs a process of transferring the event between the semantic information switches.
A recording medium on which an event delivery program is recorded. In order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. In the event place, which is a place for matching A computer-readable recording medium recording an event routing program for performing a route determination in an event routing device that determines a route of event delivery based on the information,
A plurality of event place objects for comparing the semantic information registered as the filter in advance with the semantic information included in the event, and transmitting an event that matches based on the result to the event receiving entity corresponding to the filter. A shared link object that establishes a shared link that is a logical link for event transfer between the event place objects based on physical link information between the event place objects and generates a shared link object that transfers the event between the event place objects Generation processing,
When the one event place object (hereinafter, “EPO1”) registers the filter with itself, the event is transferred to the EPO1 from another adjacent event place object (hereinafter, “EPO2”) as the shared link. An event path setting process of notifying the shared link object to that effect, and requesting the EPO2 to register the filter when the shared link object receives the notification;
Recording medium storing an event routing program, which causes a computer to perform the following. In order to deliver an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends an event from the event transmitting entity to a filter that sets the semantic information of the event desired to be received as an event acquisition condition. In the event place, which is a place for matching
Semantic information having a plurality of semantic information switches for notifying the event receiving entity corresponding to the filter of an event that matches based on a result of matching the semantic information registered in advance as the filter with the semantic information included in the event. In a network system, a computer-readable recording medium recording a routing program for selecting a route of the event between the semantic information switches belonging to the same event place,
Based on the content of the semantic information, the computer performs a process of selecting the route of the event between the semantic information switches and transferring the event between the semantic information switches.
A recording medium having recorded thereon a routing program. In order to deliver an event consisting of data and semantic information that is meta information of the data, an event transmitting entity sets a semantic information of the event that the event receiving entity desires to receive as a condition for acquiring the event as an event transmitting entity. For each event place that is a place to match the event from
A computer-readable recording medium storing an event delivery program for delivering an event in a semantic information network system having one or more semantic information switches and a semantic information gateway for transferring the event between different event places. hand,
In the semantic information switch,
The computer performs a process of comparing the semantic information registered in advance as the filter with the semantic information included in the event, and notifying the event receiving entity corresponding to the filter of the matched event based on the matching result. ,
In the semantic information gateway,
A process of holding a difference of ontology information between the event places as ontology conversion information,
A process of receiving the event from the semantic information switch belonging to a transfer source event place;
Using the ontology conversion information, converting the received event into an ontology of a transfer destination event place;
Transferring the converted event to the semantic information switch belonging to the event place of the transfer destination.
A recording medium on which an event delivery program is recorded. In order to perform delivery of an event consisting of data and semantic information that is meta information of the data, the event receiving entity sends a filter that sets the semantic information of the event desired to be received as an event acquisition condition to the filter from the event transmitting entity. In the semantic information network system having a plurality of event places having a semantic information switch for notifying the event receiving entity corresponding to the filter of the event matched based on the matching result based on the matching result, A computer-readable recording medium recording an event transfer program for transferring the event,
A process of holding a difference of the ontology information between the event places as ontology conversion information,
A process of receiving the event from the semantic information switch belonging to a transfer source event place;
Using the ontology conversion information, converting the received event into an ontology of a transfer destination event place;
Transferring the converted event to the semantic information switch belonging to the event place of the transfer destination.
A recording medium on which an event transfer program is recorded. In order to deliver an event composed of data and semantic information that is meta information of the data, an event from the event transmitting entity is applied to a filter in which the event receiving entity has set the semantic information of the event desired to be received as an event acquisition condition. A computer-readable recording medium recording an event delivery program for delivering an event in a semantic information network system having an event place that is a place for matching
A matching process for matching the semantic information registered in advance as the filter with semantic information included in the event,
A process of notifying the event receiving entity corresponding to the filter of the event matched based on the matching result,
Classifying the filter for each event type that is a template of semantic information, further processing to subdivide and manage for each session for event reception between the event receiving entity and the semantic information switch,
To the computer,
In the matching process, when a plurality of filters are registered in the same session, the matching is sequentially performed on the plurality of filters, and if the matching result of one of the filters matches, a subsequent filter among the plurality of filters is used. A recording medium on which an event delivery program is recorded.

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