JP2008072313A - Optimal network selection system - Google Patents

Abstract

Even when a connection to the other party cannot be made due to congestion, a failure of a switching system, etc., it is not necessary for the user to perform a re-call operation, and a call with the desired party is realized.
A control message for re-transmission via another communication network is transmitted from a short message processing device 4 to a caller terminal when a connection from a caller terminal 1 to a callee terminal 2 via a voice network is impossible. 1 to send. In this way, even when the call cannot be connected to the other party due to congestion, a failure of the exchange, or the like, the user does not need to perform a re-call operation, and a call with the desired party can be realized.
[Selection] Figure 2

Description

  The present invention relates to an optimum network selection system, and more particularly to a system that selects an optimum communication network according to the network conditions.

  Currently, mobile phone services based on IMT (International Mobile Telecommunication) 2000 are in practical use. In this cellular phone service, when trying to connect to the other party via the voice network, the connection cannot be established if the voice switch breaks down or congestion occurs. In that case, it is necessary to give up the connection or perform a re-transmission operation for a call using another communication network, for example, a packet communication network.

  For example, in FIG. 13, a mobile station (hereinafter referred to as a calling mobile station) 1 that is a terminal used by user A to a mobile station (hereinafter referred to as a destination mobile station) that is a terminal used by user B. Let us consider a case where a connection to the voice network is attempted. Here, the packet switch 11 and the voice switch 12 corresponding to the communication area where the originating mobile station 1 is located are provided in the Osaka area, and the packet switch 21 corresponding to the communication area where the destination mobile station 2 is located. And a voice switch 22 are provided in the Tokyo area. The packet switches 11 and 21 and the voice switches 12 and 22 are connected to the public network NW.

In such a configuration, when a failure or congestion occurs in the voice exchange 22, it is not possible to connect from the source mobile station 1 to the destination mobile station 2. In this case, a re-transmission operation for a call using the packet communication network is performed, and the calling mobile device 1 is connected to the called mobile device 2.
In addition, there is a technique in which a facsimile apparatus automatically makes a call again by switching the network when a communication error occurs (for example, Patent Document 1).
JP 2004-112516 A

In the above-described prior art, when a call by voice communication using a voice network cannot be connected to the other party due to congestion, a failure of the exchange, or the like, the user needs to perform a re-transmission operation. The re-calling technique described in Patent Document 1 has a drawback in that it is highly likely that a connection cannot be made because a call is made to the same type of network when congestion or an exchange failure occurs.
The present invention has been made to solve the above-described problems of the prior art, and its purpose is to allow a user to perform a re-transmission operation even when a connection to the other party cannot be made due to congestion or a failure of the exchange. Rather, it is to provide an optimum network selection system capable of realizing a call with a desired partner.

  An optimum network selection system according to claim 1 of the present invention is an optimum network selection system that selects an optimum communication network in response to a call from a calling side terminal capable of communication using a plurality of types of communication networks to a receiving side terminal. Means for transmitting a control message for re-transmission via another communication network when the connection from the caller terminal to the callee terminal is impossible (short message in FIG. 2). Corresponding to a processing apparatus). Corresponding to the first embodiment to be described later, according to such a configuration, even if the connection to the other party cannot be made due to congestion, a failure of the exchange, etc., the user does not need to perform a re-transmission operation, and the desired party You can make a call with.

  The optimum network selection system according to claim 2 of the present invention is an optimum network selection system that selects an optimum communication network in response to a call from a calling side terminal capable of communication using a plurality of types of communication networks to a receiving side terminal. The means for acquiring the status of the communication network (corresponding to step S201 by the network management device in FIG. 5) and the means for determining the priority network based on the acquired status (in step S202 by the network management device in FIG. 5) And the means for notifying the determined priority network to the originating terminal (corresponding to step S203 by the network management apparatus in FIG. 5), the priority is given to the originating terminal that has received the notified priority network. It is characterized by being transmitted via the network. Corresponding to the second embodiment to be described later, according to such a configuration, even if the connection to the other party cannot be made due to congestion or a failure of the exchange, the user does not need to perform a re-transmission operation, and the desired party You can make a call with.

The optimum network selection system according to a third aspect of the present invention is characterized in that, in the second aspect, the caller terminal that has received the notified priority network forcibly transmits via the priority network. Corresponding to case (1) in FIG. 5 to be described later, according to this configuration, it is possible to forcibly switch to the priority network for transmission regardless of the transmitted communication network.
The optimum network selection system according to claim 4 of the present invention is the optimum network selection system according to claim 2, wherein the caller terminal that has received the notified priority network cannot connect to the callee terminal when the connection to the callee terminal is impossible. It is characterized by being retransmitted via the network. Corresponding to the case (2) in FIG. 5 to be described later, according to this configuration, connection in the communication network that is transmitted is allowed, and when the connection is not possible, it is switched to the priority network and transmitted. Can do.

  The optimum network selection system according to claim 5 of the present invention is an optimum network selection system for selecting an optimum communication network in response to a call from a calling side terminal capable of communication using a plurality of types of communication networks to a receiving side terminal. Means for acquiring the status of the communication network (corresponding to step S301 by the network management device in FIG. 7 described later) and means for determining the priority network based on the acquired status (network management device in FIG. 7 described later) Corresponding to step S306), means for notifying the determined priority network to the caller terminal (corresponding to step S307 by the network management device in FIG. 7 described later), and from the caller terminal to the callee terminal Means for transmitting a control message for re-transmission via another communication network to the calling-side terminal when the connection is impossible ( And a corresponding) to the short message processing apparatus in FIG. 7 to be described, in the calling-side terminal having received the notified priority network, characterized by being adapted to redial via preferential network. Corresponding to the third embodiment to be described later, according to such a configuration, even when the connection to the other party cannot be made due to congestion or a failure of the exchange, the user does not need to perform a re-transmission operation, and the desired party You can make a call with.

  An optimum network selection system according to a sixth aspect of the present invention is an optimum network selection system that selects an optimum communication network in response to a call from a calling side terminal capable of communication using a plurality of types of communication networks to a receiving side terminal. Means for acquiring the status of the communication network (corresponding to step S401 by the network management apparatus in FIG. 9 to be described later) and means for notifying all the exchanges of the acquired status (by the network management apparatus in FIG. 9 to be described later) (Corresponding to S403) and means for determining a priority network based on the acquired situation when connection from the calling terminal to the receiving terminal is impossible (step S408 by the voice switch in FIG. 9 described later) And a means for notifying the calling terminal of the determined priority network (corresponding to step S409 by the voice exchange in FIG. 9 to be described later). In the calling-side terminal having received the notified priority network, characterized by being adapted to redial via preferential network. Corresponding to the fourth embodiment to be described later, according to such a configuration, even if the connection to the other party cannot be made due to congestion, a failure of the exchange, etc., the user does not need to perform a re-transmission operation, and the desired party You can make a call with.

  According to the present invention, when a call by voice communication using the voice network cannot be connected to the other party due to congestion, a failure of the exchange, or the like, the network situation such as switching to connection by voice communication using the packet communication network, etc. By switching to the optimal network according to the situation, there is no need for the user to perform a re-transmission operation, and there is an effect that a call with a desired partner can be realized.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the drawings referred to in the following description, the same parts as those in the other drawings are denoted by the same reference numerals.
(First embodiment)
(System configuration)
FIG. 1 is a block diagram showing a configuration example of an optimum network selection system according to the first embodiment of the present invention. In the figure, the optimum network selection system according to the first embodiment of the present invention is a mobile station 1 used by a user A and a packet provided corresponding to a communication area where the mobile station 1 is located. The exchange 11, the voice exchange 12 provided corresponding to the communication area where the originating mobile station 1 is located, the destination mobile 2 used by the user B, and the destination mobile 2 are located. A packet switch 21 provided corresponding to the communication area, a voice switch 22 provided corresponding to the communication area where the destination mobile station 2 is located, and a communication area where the subscriber is currently located It includes a subscriber information storage device 3 that stores location information, which is information related to information, and a short message processing device 4 that transmits a short message.

The source mobile device 1 and the destination mobile device 2 are communication terminals capable of performing transmission using a voice network and transmission using a packet communication network. These mobile devices can perform voice communication and packet communication when they are located in a communication area realized by a radio base station and a base station control device (not shown).
The packet switches 11 and 21, the voice switches 12 and 22, the subscriber information storage device 3, and the short message processing device 4 are connected to the public network NW.

(System operation example)
FIG. 2 is a sequence diagram showing the operation of the optimum network selection system according to the first embodiment of the present invention. In the figure, signals are transmitted among the originating mobile station 1, packet switch 11, voice switch 12, destination mobile station 2, packet switch 21, voice switch 22, subscriber information storage device 3, and short message processing device 4. Transfer processing etc. are shown.
In the figure, the presetting is performed from the calling mobile device 1 to the subscriber information storage device 3. First, when a call cannot be made, a message for setting whether or not to perform a call operation in another communication network (that is, another bearer) is transmitted from the calling mobile device 1 to the subscriber information storage device 3 (step). S101). Here, a message for setting to operate both the voice communication network and the packet communication network is transmitted.

  Receiving this message, the subscriber information storage device 3 notifies the voice switch 12 of the setting information of the calling mobile device 1 regarding the operation when the voice call cannot be made (step S102). The notified setting information is held in the voice exchange 12 as a subscriber profile. Further, the subscriber information storage device 3 notifies the packet switch 11 of the setting information of the calling mobile device 1 regarding the operation when the transmission through the packet communication network is not possible (step S103). The notified setting information is held in the packet switch 11 as a subscriber profile. With the above processing, when transmission by either one of the voice communication network and the packet communication network cannot be performed, setting for automatically performing transmission by the other is performed.

  After the above presetting, voice transmission is performed from the user A's source mobile device 1 to the user B's destination mobile device 2 (step S104). Thereafter, a message indicating that voice transmission is in progress is displayed on the display screen of the calling mobile device 1 (step S105). The voice exchange 12 makes an inquiry to the subscriber information storage device 3 in which communication area the destination mobile device 2 is currently located, that is, in-zone inquiry (step S106). After that, the voice switch 12 that has acquired the area where the called mobile device 2 is located by this inquiry tries to connect to the voice switch 22 corresponding to the area where the called mobile device 2 is located via the voice network (step S107).

  Here, it is assumed that a failure or congestion occurs in the voice switch 22 and connection via the voice network cannot be made, and a response to that effect is returned from the voice switch 22 (step S108). Receiving the response, the voice exchange 12 accesses the subscriber profile held in step S102, and confirms the operation when the voice transmission cannot be performed (step S109). If no action is set, the process ends. In this example, the operation is set, and a control message transmission instruction for retransmitting the packet communication network is transmitted to the short message processing device 4 (step S110).

The short message processing device 4 that has received this transmission instruction transmits a control message for re-transmission in the packet communication network to the source mobile device 1 (step S111). This control message is sent to the source mobile device 1 via the packet switch 11 (step S112). Receiving this control message, the originating mobile device 1 performs re-transmission via the packet communication network (step S113). Thereafter, the display screen of the calling mobile device 1 displays that the packet communication network is transmitting (step S114).
When re-transmission is performed through the packet communication network, connection processing is performed toward the destination mobile device 2 via the packet switch 11 and the packet switch 21 (steps S115 and S116). With the above processing, the connection processing from the source mobile device 1 to the destination mobile device 2 is completed (step S117), and thereafter, a call is performed between both mobile devices via the packet communication network.

In this example, the case where the re-transmission is performed via the packet communication network when the connection via the voice network cannot be performed has been described. However, the re-transmission via the voice network is performed when the connection via the packet communication network cannot be performed. It is obvious that processing can be similarly performed for cases.
According to the first embodiment described above, even when a connection to the other party cannot be made due to congestion, a failure of the exchange, etc., it is not necessary for the user to perform a re-transmission operation, and a call with the desired party can be realized.

(Modification of the first embodiment)
In the first embodiment described above, when a connection could not be made, a control message was transmitted to the originating mobile station automatically according to the result of the determination in the switch, but it was automatically retransmitted. Therefore, the control message transmission process can be omitted by making a determination in the mobile station. The operation sequence in this case will be described with reference to FIG.

  In the figure, the mobile station 1 is pre-set as to whether or not to make a call operation on another communication network when the call cannot be made (step S100). Here, the voice communication network and the packet communication network are set to operate. After this pre-setting, voice transmission is performed from the user A's calling mobile device 1 to the user B's destination mobile device 2 (step S104). Thereafter, a message indicating that voice transmission is in progress is displayed on the display screen of the calling mobile device 1 (step S105). The voice exchange 12 makes an inquiry to the subscriber information storage device 3 in which communication area the destination mobile device 2 is currently located, that is, in-zone inquiry (step S106). After that, the voice switch 12 that has acquired the area where the called mobile device 2 is located by this inquiry tries to connect to the voice switch 22 corresponding to the area where the called mobile device 2 is located via the voice network (step S107).

  Here, it is assumed that a failure or congestion occurs in the voice switch 22 and connection via the voice network cannot be made, and a response to that effect is returned from the voice switch 22 (step S108). When receiving the response, the voice exchange 12 transmits it to the calling mobile device 1 (step S108 '). Receiving this, the calling mobile device 1 accesses the contents set in advance in step S100, and confirms the operation when the voice transmission cannot be performed (step S109 '). If no action is set, the process ends. In this example, the operation is set, and the calling mobile device 1 performs re-transmission via the packet communication network (step S113). Thereafter, the display screen of the calling mobile device 1 displays that the packet communication network is transmitting (step S114). The subsequent operation is the same as that described with reference to FIG.

In this example, the case where the re-transmission is performed via the packet communication network when the connection via the voice network cannot be performed has been described. However, the re-transmission via the voice network is performed when the connection via the packet communication network cannot be performed. It is obvious that processing can be similarly performed for cases.
According to the modification described above, even when the connection to the other party cannot be made due to congestion, a failure of the exchange, etc., it is not necessary for the user to perform a re-call operation, and a call with the desired party can be realized.

(Second Embodiment)
(System configuration)
FIG. 4 is a block diagram showing a configuration example of the optimum network selection system according to the second embodiment of the present invention. In the figure, the optimum network selection system according to the second embodiment of the present invention includes a source mobile device 1, a packet switch 11, a voice switch 12, a network management device 5, a destination mobile device 2, and a packet switch 21. The voice exchange 22 and the subscriber information storage device 3 are included.

In this example, the packet switch 11 and the voice switch 12 are provided, for example, in the Osaka area. The packet switch 21 and the voice switch 22 are provided in the Tokyo area, for example.
The network management device 5 receives information such as failure and congestion from a packet switch and a voice switch, determines the network status of the communication area corresponding to the switch based on the received information, and has a function in the communication area. This is a device having a function of notifying information on priority bearers to mobile devices in service. The network management device 5 holds an LAI (Local Area Identify) management table, an RAI (Routing Area Identify) management table, and an area management table, which will be described later.
Other functions of the apparatus are the same as those described with reference to FIG.

(System operation example)
FIG. 5 is a sequence diagram showing the operation of the optimum network selection system according to the second embodiment of the present invention. In the same figure, signal transmission / reception among the originating mobile station 1, packet switch 11, voice switch 12, network management device 5, destination mobile device 2, packet switch 21, voice switch 22, and subscriber information storage device 3 is performed. Processing etc. are shown.

In FIG. 1, a calling mobile device 1 is a communication terminal capable of performing transmission using a voice network and transmission using a packet communication network. For this reason, both the voice network and the packet communication network are initially displayed as priority bearers on the display screen of the calling mobile device 1 (step S200).
Here, when a failure or congestion occurs in the voice switch 12 in the Osaka area, the voice switch 12 sends a notification to the network management device 5 that the voice connection in the Osaka area is difficult (step S201). This state notification is sent at the timing when the state change occurs. Thereafter, notifications are periodically sent out from the necessity of confirming whether or not the state has been changed.

  Receiving this notification, the network management device 5 determines the network status in units of areas (step S202). In this example, it is difficult to connect via the voice network in the Osaka area, and it is determined that connection via the packet communication network is possible. Therefore, the network management device 5 sends a notification that the packet communication network is a priority bearer (step S203). This notification is sent to the source mobile device 1 via the packet switch 11 (step S204). The packet communication network is displayed as a priority bearer on the display screen of the originating mobile device 1 that has received this notification (step S205).

  There are two types of subsequent operations. First, case (1) will be described. When a call is transmitted from the calling mobile device 1 to the called mobile device 2 via the voice network (step S206), the call is forcedly switched to the packet communication network that is the priority bearer (step S206 '). Thereafter, the display screen of the calling mobile device 1 displays that the packet communication network is transmitting (step S207).

  When a call is transmitted from the source mobile device 1 to the destination mobile device 2, the packet switch 11 corresponding to the communication area in which the source mobile device 1 is located is located in which communication area the destination mobile device 2 is currently located. In other words, a location inquiry is made to the subscriber information storage device 3 (step S208). Thereafter, connection is made via the packet communication network from the packet switch 11 that has acquired the area where the destination mobile device 2 is located by this inquiry to the packet switch 21 corresponding to the area where the destination mobile device 2 is located (step S209, S210, S211).

Next, case (2) will be described. When a call is made from the calling mobile device 1 to the called mobile device 2 via the voice network (step S212), the packet communication network is not switched and is sent to the voice network as it is. Thereafter, the display screen of the calling mobile device 1 displays that the voice is being transmitted (step S213).
Even if transmission is made from the originating mobile station 1 to the terminating mobile station 2, in this example, the voice switch 12 corresponding to the communication area in which the originating mobile station 1 is located has failed or congested. Can not. Here, it is assumed that a response to that effect is returned from the voice exchange 12 (step S214). Receiving this response, the calling mobile device 1 automatically performs re-transmission via the packet communication network (step S215). After that, the display screen of the calling mobile device 1 displays that the packet communication network is transmitting (step S216).

  When this re-transmission is performed, the packet switch 11 corresponding to the communication area in which the originating mobile device 1 is located is in which communication area the destination mobile device 2 is currently located, that is, the inquiries are made to the subscriber. This is performed for the information storage device 3 (step S217). Thereafter, a connection is made via the packet communication network from the packet switch 11 that has acquired the area where the destination mobile device 2 is located by this inquiry to the packet switch 21 corresponding to the area where the destination mobile device 2 is located (step S218, S219, S220).

In this example, the case where the packet communication network is a priority bearer has been described. However, it is obvious that the same processing can be performed when the voice network is a priority bearer.
According to the second embodiment described above, even when the connection to the other party cannot be made due to congestion, a failure of the exchange, or the like, it is not necessary for the user to perform a re-call operation, and a call with the desired party can be realized.

(Third embodiment)
(System configuration)
FIG. 6 is a block diagram showing a configuration example of the optimum network selection system according to the third embodiment of the present invention. In the figure, the optimum network selection system according to the third embodiment of the present invention includes a source mobile device 1, a packet switch 11, a voice switch 12, a network management device 5, a destination mobile device 2, and a packet switch 21. The voice exchange 22, the subscriber information storage device 3, and the short message processing device 4 are configured.

In this example, the packet switch 11 and the voice switch 12 are provided, for example, in the Osaka area. The packet switch 21 and the voice switch 22 are provided in the Tokyo area, for example.
The network management device 5 receives information such as failure and congestion from a packet switch and a voice switch, and determines the network status in the whole country based on the received information, and a packet switch and a voice switch by transmission from a mobile device. In response to the priority bearer inquiry from the network, it is a device having a function of notifying information on the priority bearer based on the nationwide network situation. The network management device 5 holds an LAI management table, an RAI management table, and a region management table, which will be described later.
Other functions of the apparatus are the same as those described with reference to FIG.

(System operation example)
FIG. 7 is a sequence diagram showing the operation of the optimum network selection system according to the third embodiment of the present invention. In the figure, the source mobile device 1, the packet switch 11, the voice switch 12, the network management device 5, the destination mobile device 2, the packet switch 21, the voice switch 22, the subscriber information storage device 3, and the short message processing device 4 are shown. Signal exchange processing and the like between each other is shown.

  In the figure, when a failure or congestion occurs in the voice switch 22 in the Tokyo area, the voice switch 22 sends a notification that the voice connection in the Tokyo area is difficult to the network management device 5 (step S301). . This state notification is sent at the timing when the state change occurs. Thereafter, notifications are periodically sent out from the necessity of confirming whether or not the state has been changed.

  A voice is transmitted from the calling mobile device 1 to the destination mobile device 2 of the user B (step S302). Thereafter, a message indicating that voice transmission is in progress is displayed on the display screen of the calling mobile device 1 (step S303). The voice exchange 12 makes an inquiry to the subscriber information storage device 3 as to which communication area the destination mobile device 2 is currently located, that is, in-zone inquiry (step S304). At the same time, the voice exchange 12 sends an inquiry to the network management device 5 as to whether the priority bearer is a voice network or a packet communication network (step S305). Receiving this inquiry, the network management device 5 determines the network status for each area (step S306). In this example, the notification of step S301 has already been received, and it can be determined that the voice connection in the Tokyo area is difficult. On the other hand, it is determined that connection by the packet communication network is possible. Therefore, the network management device 5 sends a notification that the packet communication network is a priority bearer (step S307). This notification is sent to the voice switch 12. The voice switch 12 transmits a control message transmission instruction for re-transmission via the packet communication network to the short message processing device 4 (step S308).

  The short message processing device 4 that has received this transmission instruction transmits a control message for re-transmission in the packet communication network to the originating mobile device 1 (step S309). This control message is sent to the source mobile device 1 via the packet switch 11 (step S310). Receiving this control message, the originating mobile device 1 performs re-transmission via the packet communication network (step S311). After that, the display screen of the calling mobile device 1 displays that the packet communication network is transmitting (step S312).

  When re-transmission is performed by the packet communication network, the packet switch 11 makes an inquiry to the subscriber information storage device 3 as to which communication area the destination mobile device 2 is currently located, that is, in-zone inquiry (step S313). . Thereafter, connection processing is performed from the packet switch 11 that has acquired the in-service area of the destination mobile device 2 by this inquiry toward the destination mobile device 2 (steps S314 and S315). With the above processing, the connection processing from the source mobile device 1 to the destination mobile device 2 is completed (step S316), and after that, a call is performed between both mobile devices via the packet communication network.

In this example, the case where the packet communication network is a priority bearer has been described. However, it is obvious that the same processing can be performed when the voice network is a priority bearer.
According to the third embodiment described above, even when the connection to the other party cannot be made due to congestion, a failure of the exchange, or the like, it is not necessary for the user to perform a re-transmission operation, and a call with the desired party can be realized.

(Fourth embodiment)
(System configuration)
FIG. 8 is a block diagram showing a configuration example of the optimum network selection system according to the fourth embodiment of the present invention. In the figure, the optimum network selection system according to the fourth embodiment of the present invention includes a source mobile device 1, a packet switch 11, a voice switch 12, a network management device 5, a destination mobile device 2, and a packet switch 21. The voice exchange 22 and the subscriber information storage device 3 are included.

In this example, the packet switch 11 and the voice switch 12 are provided, for example, in the Osaka area. The packet switch 21 and the voice switch 22 are provided in the Tokyo area, for example.
The network management device 5 receives information such as failure and congestion from a packet switch and a voice switch, and determines the nationwide network status based on the received information, and for the packet switch and voice switch in the country, This device has a function of notifying the nationwide network status. The network management device 5 holds an LAI management table, an RAI management table, and a region management table, which will be described later.
Other functions of the apparatus are the same as those described with reference to FIG.

(System operation example)
FIG. 9 is a sequence diagram showing the operation of the optimum network selection system according to the fourth embodiment of the present invention. In the same figure, signal transmission / reception among the originating mobile station 1, packet switch 11, voice switch 12, network management device 5, destination mobile device 2, packet switch 21, voice switch 22, and subscriber information storage device 3 is performed. Processing etc. are shown.

  In the figure, when a failure or congestion occurs in the voice switch 22 in the Tokyo area, the voice switch 22 sends a notification that the voice connection in the Tokyo area is difficult to the network management device 5 (step S401). . This state notification is sent at the timing when the state change occurs. Thereafter, notifications are periodically sent out from the necessity of confirming whether or not the state has been changed.

  Receiving this notification, the network management device 5 determines the network status in units of areas (step S402). In this example, it is determined that connection via the voice network is difficult in the Tokyo area, and connection via the packet communication network is possible. For this reason, the network management device 5 sends a notification that the packet communication network is a priority bearer in the Tokyo area to voice switches and packet switches throughout the country (step S403). The notification related to the priority bearer is transmitted at the timing when the state change occurs. Thereafter, notifications are periodically sent out from the necessity of confirming whether or not the state has been changed. In this example, the network status of each communication area is held as a subscriber profile in the voice exchanges 12 and 22 and the packet exchanges 11 and 21 (steps S404a, S404b, S404c, and S404d).

  On the premise of the above processing, voice transmission is performed from the user A's source mobile device 1 to the user B's destination mobile device 2 (step S405). Thereafter, a message indicating that voice transmission is in progress is displayed on the display screen of the calling mobile device 1 (step S406). The voice exchange 12 makes an inquiry to the subscriber information storage device 3 in which communication area the destination mobile device 2 is currently located, that is, a location inquiry (step S407). The voice exchange 12 that has received the response accesses the subscriber profile held in step S404 and confirms the network status (step S408). If connection via the packet communication network is difficult, the process is terminated. In this example, connection via a packet communication network is possible, and the voice exchange 12 sends a notification that the packet communication network is a priority bearer to the originating mobile device 1 (step S409). Receiving this notification, the calling mobile device 1 performs re-transmission via the packet communication network (step S410). Thereafter, the display screen of the calling mobile device 1 displays that the packet communication network is transmitting (step S411).

  When re-transmission is performed by the packet communication network, the packet switch 11 makes an inquiry to the subscriber information storage device 3 in which communication area the destination mobile device 2 is currently located, that is, in-zone inquiry (step S412). . Thereafter, connection processing is performed from the packet switch 11 that has acquired the in-service area of the destination mobile device 2 by this inquiry toward the destination mobile device 2 (steps S413 and S414). With the above processing, the connection processing from the source mobile device 1 to the destination mobile device 2 is completed (step S415), and thereafter, a call is made between both mobile devices via the packet communication network.

In this example, the case where the packet communication network is a priority bearer has been described. However, it is obvious that the same processing can be performed when the voice network is a priority bearer.
According to the fourth embodiment described above, even when a connection to the other party cannot be made due to congestion, a failure of the exchange, or the like, it is not necessary for the user to perform a re-call operation, and a call with the desired party can be realized.

(Table in network management device)
A configuration example of a table held in the network management device 5 in the second embodiment, the third embodiment, and the fourth embodiment described above will be described with reference to FIGS. First, the communication area accommodated by the voice exchange and the packet exchange is assigned with an identifier and managed. For example, the identifiers for identifying the communication areas of the voice network are LAI1, LAI2,. Also, identifiers for identifying communication areas of the packet communication network are RAI1, RAI2,. The LAI is configured by, for example, “mobile device country code” + “mobile operator identification number” + “identification number”. The RAI is configured by, for example, “LAI” + “identification number”.

As shown in FIG. 10, LAI and RAI are assigned to the communication areas of the Osaka area, the Tokyo area, the Hokkaido area, and so on. The network management device 5 holds an LAI management table and an RAI management table. For each item in these tables, the contents of the data are updated synchronously in real time.
In the example of the figure, both the packet switch and the voice switch in the Osaka area are normal. On the other hand, congestion occurs in the voice switch in the Tokyo area, and a failure occurs in the packet switch in the Hokkaido area.

  For this reason, in the LAI management table, in the items of the LAI numbers “3” and “4” in the Tokyo area, the network status is “congested”, and the priority bearer is communication by the “packet network”. In the RAI management table, in the items of RAI numbers “5” and “6” in the Hokkaido area, the network status is “failing”, and the priority bearer is communication by “voice network”. Items other than these are “DUAL” indicating that connection is possible by either the voice network or the packet communication network.

  Further, the network management device 5 holds a regional management table. Here, as shown in FIG. 11, the voice exchange has a hierarchical structure of a voice exchange relay level, a voice switching agency gate level, and a voice switching subscriber level. The base station belongs to the lower level of the voice switch subscriber floor. For this reason, when making an inter-regional connection (for example, a connection between the Kansai area and the Kanto area) by voice call, it always passes through a voice switch on the relay floor. Therefore, if the exchange on the relay floor breaks down or congestion occurs, it is difficult to connect outgoing calls and incoming calls to the area. For example, when congestion occurs in a voice exchange on the relay floor in the Kansai area, it is difficult to connect outgoing calls from the Kansai area and incoming calls to the Kansai area. Note that when a voice call connection is made within the same area, it does not go through the exchange on the relay floor.

  In order to perform the above management, the area management table is configured to specify an area by area number. In this example, the Hokkaido area is “01”, the Tohoku area is “02”, the Kanto area is “03”, the Tokai area is “04”, the Hokuriku area is “05”, the Kansai area is “06”, and the Shikoku area is “ 07 ", China area is" 08 "and Kyushu area is" 09 ". For each of these areas, as shown in FIG. 12, a table is constructed with the calling area as the vertical axis and the incoming area as the horizontal axis. Then, the contents are updated in synchronization with the contents of the LAI management table and the RAI management table described above in real time. By doing so, the priority bearer is determined according to the network status.

In this example, it is difficult to connect when the call area is “01” and the call area is “03”, when the call area is “01” and the call area is “06”, when the call area is “03” and the call area is “01”. It has become.
By using the table described above, an optimal communication network can be selected according to the network status.

  The present invention can be used when an optimum communication network is selected according to the network status.

It is a block diagram which shows the structural example of the optimal network selection system by 1st Embodiment of this invention. It is a sequence diagram which shows operation | movement of the optimal network selection system by 1st Embodiment of this invention. It is a sequence diagram which shows the operation | movement of the system which deform | transformed the optimal network selection system of FIG.1 and FIG.2. It is a block diagram which shows the structural example of the optimal network selection system by 2nd Embodiment of this invention. It is a sequence diagram which shows operation | movement of the optimal network selection system by 2nd Embodiment of this invention. It is a block diagram which shows the structural example of the optimal network selection system by 3rd Embodiment of this invention. It is a sequence diagram which shows operation | movement of the optimal network selection system by 3rd Embodiment of this invention. It is a block diagram which shows the structural example of the optimal network selection system by 4th Embodiment of this invention. It is a sequence diagram which shows operation | movement of the optimal network selection system by 4th Embodiment of this invention. It is a figure which shows the example of the LAI management table hold | maintained at a network management apparatus, and a RAI management table. It is a figure which shows the hierarchical structure regarding a voice switch. It is a figure which shows the example of the area management table hold | maintained at a network management apparatus. It is a figure which shows the structure of a general mobile communication network.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Originating mobile device 2 Terminating mobile device 3 Subscriber information storage device 4 Short message processing device 5 Network management device 11, 21 Packet exchange 12, 22 Voice exchange

Claims (6)

  An optimum network selection system for selecting an optimum communication network in response to a call from a calling terminal to a receiving terminal capable of communication using a plurality of types of communication networks, the communication from the calling terminal to the receiving terminal An optimum network selection system comprising means for transmitting a control message for re-transmission via another communication network to the caller terminal when connection is impossible.   An optimum network selection system for selecting an optimum communication network in response to a call from a calling terminal to a receiving terminal capable of communication using a plurality of types of communication networks, and means for acquiring the status of the communication network, and acquisition Including a means for determining a priority network based on the determined situation and a means for notifying the determined priority network to the caller terminal, and transmitting via the priority network at the caller terminal receiving the notified priority network An optimal network selection system characterized by doing so.   3. The optimum network selection system according to claim 2, wherein the originating side terminal receiving the notified priority network forcibly transmits via the priority network.   3. The originating terminal that has received the notified priority network retransmits via the priority network when connection to the terminating terminal is impossible. Optimal web selection system.   An optimum network selection system for selecting an optimum communication network in response to a call from a calling terminal to a receiving terminal capable of communication using a plurality of types of communication networks, and means for acquiring the status of the communication network, and acquisition Means for determining a priority network based on the situation, means for notifying the determined priority network to the caller terminal, and other communication when connection from the caller terminal to the callee terminal is impossible. Means for transmitting a control message for re-transmission via the network to the caller terminal, and retransmits via the priority network at the caller terminal that has received the notified priority network. Optimal network selection system.   An optimum network selection system for selecting an optimum communication network in response to a call from a calling terminal to a receiving terminal capable of communication using a plurality of types of communication networks, and means for acquiring the status of the communication network, and acquisition Means for notifying all the exchanges of the status, and means for determining a priority network based on the acquired status when connection from the calling terminal to the receiving terminal is not possible, and the determined priority network Means for notifying the originating terminal of the optimum network selection system, wherein the originating terminal that has received the notified priority network retransmits via the priority network.

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