JP2008227721A - Information processing system, server unit, data transfer method and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an information processing system, reducing a network load and the load of a transfer processing unit when the amount of transfer data is large. <P>SOLUTION: The information processing system includes a server unit being connected to a first information processing unit via a first network, having as a decision criterion a stored threshold whether or not data transmission is to be delayed, for examining a data amount per unit time in regard to the data received from the first information processing unit, and transmitting the data after waiting for a certain time when the data amount is larger than the threshold. The information processing system also includes a gateway unit connected to the server unit, for converting the data received from the server unit from a communication format in the first network into a communication format in a second network, and transmitting the data after conversion to a second information processing unit via the second network. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an information processing system for distributing data to a plurality of information terminals, a server device, a data transfer method, and a program to be executed by a computer.

  There is an MBMS (Multimedia Broadcast Multicast Service) that distributes music videos, sports highlight scenes, and the like to a plurality of mobile terminals. Since data distributed by MBMS (hereinafter referred to as MBMS data) includes not only voice but also image data, it is characterized in that the amount of data is larger than that of conventional data communication. In MBMS, MBMS data is simultaneously distributed to a plurality of mobile terminals by broadcast or multicast.

A system for distributing data to a plurality of portable terminals is disclosed in Patent Document 1.
JP 2005-318119 A

  When MBMS is put into practical use and MBMS data is distributed all at once to many mobile terminals, MBMS data is simultaneously transmitted to a large number of base station controllers, increasing the load on the radio access network. . In addition, since data is transmitted all at once, the load of duplication processing increases in the base station controller. Furthermore, there is a risk of data congestion in the radio access network, and in this case, the load on the network will increase.

  Also, normally, MBMS data is provided from a network having a communication format different from that of the radio access network. In this case, it is necessary to consider MBMS data format conversion and transfer, and even if the method disclosed in Patent Document 1 is adopted, the effect is not sufficient.

  The present invention has been made to solve the above-described problems of the prior art, and an information processing system and server that reduce the load on the network and the transfer processing device when the amount of transfer data is large An object is to provide an apparatus, a data transfer method, and a program for causing a computer to execute the program.

In order to achieve the above object, an information processing system of the present invention transmits data transmitted from a first information processing apparatus via a first network via a second network having a communication format different from that of the first network. An information processing system for transmitting to the second information processing device and distributing the data from the second information processing device to a plurality of terminals,
A threshold that is a criterion for determining whether to delay transmission of the data is connected to the first network, and a data amount per unit time of the data received from the first information processing apparatus is examined. If the amount of data is greater than the threshold, a server device that sends the data after waiting for a predetermined time; and
Data that is connected to the server device and received from the server device is converted from a communication format in the first network to a communication format of the second network, and the converted data is converted to the data via the second network. A gateway device that transmits to the second information processing device;
It is the structure which has.

  In the present invention, even if data having a data amount larger than a predetermined value is intermittently sent, the server device waits for a predetermined time after each intermittently received data and passes it to the gateway device. Therefore, even a large amount of data can be processed with a margin for conversion of the communication format. Furthermore, after that, when data is transmitted to the second information processing apparatus, the data transmission interval becomes longer according to the standby time of the server apparatus, and the load on the second network is reduced.

  According to the present invention, when the gateway device converts the data format of the data received from the server device and transmits the data, even when intermittently transmitting data with a large amount of data, the gateway device waits for a predetermined time. Since it is received after that, the processing load on the gateway device is reduced. Further, if the transmission destination of the data from the gateway device is a base station control device of the radio access network, the data is transmitted to the base station control device according to the standby time, so the load on the base station control device and the radio access network Can be prevented from increasing.

  The configuration of the information processing system of this embodiment will be described. FIG. 1 is a block diagram including a configuration example of the information processing system of the present embodiment.

  In FIG. 1, a core network (CN) 2 is connected to a radio access network (UTRAN) 1 and the Internet 3. The CN 2 performs data format conversion and data relay for data exchanged between the UTRAN 1 and the Internet 3.

  The CN 2 includes a BM-SC (Broadcast Multicast-Service Center) server 21, a GGSN (Gateway GPRS Support Node) 22, an SGSN (Serving GPRS Support Node) 23, and an IP (Internet Protocol) network 30. Yes. The BM-SC server 21 and the GGSN 22 are connected. The GGSN 22 and the SGSN 23 are connected via the IP network 30. The BM-SC server 21 is connected to an MBMS server 31 that is an MBMS provider server via the Internet 3. The information processing system of this embodiment includes a BM-SC server 21, a GGSN 22, and an SGSN 23.

  Note that “GPRS” is an abbreviation for General Packet Radio Service. In the present embodiment, the network provided in the CN 2 is an IP network, but is not limited to an IP network. The connection between the GGSN 22 and the SGSN 23 may be via an ATM (Asynchronous Transfer Mode) network or another communication network having the same communication format as the UTRAN 1.

  The UTRAN 1 is provided with base station controllers (RNCs) 12a and 12b and radio base station devices (Node-B) 11a1 to 11an and 11b1 to 11bn (where n is an integer of 1 or more). The base station control device 12a and the radio base station devices 11a1 to 11an are connected, and the base station control device 12b and the radio base station devices 11b1 to 11bn are connected. Base station controllers 12a and 12b and SGSN 23 are connected via UTRAN1. In the present embodiment, two base station control devices are used, but the number is not limited to two.

  The BM-SC server 21 receives MBMS data from the MBMS server 31 via the Internet 3 and transmits the data to the GGSN 22. Moreover, the control signal regarding communication is transmitted / received with each of the MBMS server 31 and GGSN22. The MBMS data includes information on a service ID indicating an identifier that differs depending on the type of MBMS, the type of data, or the MBMS data to be transmitted.

  The GGSN 22 is a gateway device that converts data transmitted and received between different communication networks such as the UTRAN 1 and the Internet 3 into respective communication formats. Control signals related to communication of MBMS data are transmitted to and received from each of the BM-SC server 21 and the SGSN 23. Also, MBMS data received from the BM-SC 21 is transferred to the SGSN 23 via the IP network 30.

  The SGSN 23 is a router that relays data and signals exchanged between the IP network 30 and the base station controllers 12a and 12b. Control signals related to communication of MBMS data are transmitted to and received from the GGSN 22 and the base station controllers 12a and 12b. Also, MBMS data received from the GGSN 22 is transferred to the base station controllers 12a and 12b.

  Next, the configuration of the BM-SC server 21 will be described in detail.

  FIG. 2 is a block diagram illustrating a configuration example of the BM-SC server. As shown in FIG. 2, the BM-SC server 21 includes an MBMS control unit 211 that manages MBMS data received from the MBMS server 31, and a transmission / reception control unit 212 that transmits and receives control signals and MBMS data to and from the MBMS server 31 and the GGSN 22. Have The BM-SC server 21 is provided with a CPU (Central Processing Unit) (not shown) that executes predetermined processing according to a program, and a memory (not shown) for storing the program. When the CPU executes the program, the transmission / reception control unit 212 and the MBMS control unit 211 are virtually configured in the BM-SC server 21.

  The memory stores temporary MBMS data and a management table for managing the MBMS data. In the management table, corresponding to the service ID of MBMS data, a threshold value that is a criterion for determining whether or not to transmit data after a longer time than usual is registered. The service ID and the threshold value corresponding to the service ID are registered in advance, but can be changed by the operator.

  When receiving the MBMS data, the MBMS control unit 211 reads the service ID and refers to the management table to identify the threshold value. It is determined whether the amount of data received per unit time for MBMS data is greater than a threshold value. If the data amount is less than or equal to the threshold, the transmission timer for waiting for transmission of MBMS data until a predetermined time is set to a default value, and the transmission timer is started. On the other hand, when the data amount is larger than the threshold, the transmission timer is set to a time longer than the default value, and the transmission timer is started. The MBMS data is transmitted to the GGSN 22 after the transmission timer times out.

  When the data amount is larger than the threshold, the transmission timer is lengthened for the following reason. The first is to reduce the data processing load by giving a margin to the interval at which the GGSN 22 receives MBMS data. The second is to reduce the load of data processing in the SGSN 23 by giving a margin to the MBMS data transmission interval from the GGSN 22 to the SGSN 23, and finally a large load on the UTRAN 1 that is the transmission destination of the MBMS data. This is to prevent that.

  Note that the default value of the transmission timer and the increase time when the set time of the timer is increased are registered in advance, but can be changed by the operator.

  The control signal includes a parameter for notifying information on data processing. When the data amount is larger than the threshold value, the MBMS control unit 211 issues an instruction to the transmission / reception control unit 212 to transmit a control signal in which “congestion control flag = ON” is described in the parameter to the GGSN 22. “Congestion control flag = ON” is an instruction to provide a time difference for data transmission to the base station apparatus for each base station apparatus.

  The transmission / reception control unit 212 transmits a control signal according to an instruction from the MBMS control unit 211 to the GGSN 22. Also, the MBMS data is transmitted to the GGSN 22 after the transmission timer times out.

  Next, the configuration of the SGSN 23 will be described in detail.

  FIG. 3 is a block diagram showing a configuration example of SGSN. As shown in FIG. 3, the SGSN 23 includes a call processing control unit 231 that manages and controls call processing, and a U-plane control unit 232 that controls transmission and reception of control signals and MBMS data according to instructions from the call processing control unit 231. Have The SGSN 23 is provided with a CPU (not shown) that executes predetermined processing in accordance with a program and a memory (not shown) for storing the program. When the CPU executes the program, the U plane control unit 232 and the call processing control unit 231 are virtually configured in the SGSN 23.

  The MBMS data to be sent is temporarily stored in the memory, and an RNC destination list indicating the base station controller to which the MBMS data is transmitted is stored.

  When receiving a control signal from the GGSN 22 via the U-plane control unit 232, the call processing control unit 231 checks whether or not “congestion control flag = ON” is described in the parameter of the control signal. When “congestion control flag = ON” is described, in order to shift the data transmission time to each of the plurality of base station control devices of the MBMS data transmission destination, the address of the base station control device that is the transmission destination of the MBMS data And a destination RNC list including the offset value information is generated and passed to the U-plane control unit 232.

  When the U-plane control unit 232 receives the destination RNC list from the call processing control unit 231, the U-plane control unit 232 checks whether or not the destination RNC list includes offset value information, and if there is offset value information, it is described in the list. When transmitting the MBMS data to the base station controller, the transmission time is shifted by the offset value and the data is transmitted to each base station controller. If the destination RNC list contains no offset value information, the MBMS data is transmitted to all the base station controllers described in the list as in the conventional case.

  Note that the radio base station apparatuses 11a1 to 11an and 11b1 to 11bn and the base station control apparatuses 12a and 12b in the UTRAN 1 shown in FIG. 1 have the same configuration as the conventional one. In this embodiment, the normal functions of these apparatuses are used. The detailed description about is omitted.

  Next, the operation of the BM-SC server 21 until the MBMS data sent from the MBMS server 31 is sent to the GGSN 22 in the information processing system of this embodiment will be described.

  FIG. 4 is a flowchart showing an operation procedure of the BM-SC server in the information processing system of this embodiment.

  When the BM-SC server 21 receives MBMS data from the MBMS server 31 (step 401), the transmission / reception control unit 212 confirms the service ID of the received MBMS data and the amount of data received per unit time, and stores these information in the MBMS. The control unit 211 is notified (step 402). The MBMS control unit 211 refers to a management table stored in a memory (not shown), searches the management table for the same ID as the received service ID, and if a matching service ID is found, the threshold registered together with the service ID Is read. Then, the data amount notified from the transmission / reception control unit 212 is compared with the threshold value read from the management table (step 403). Here, a management table managed by the MBMS control unit 211 will be described.

  FIG. 5 is a diagram illustrating an example of a table managed by the MBMS control unit. In FIG. 5, the threshold for the amount of MBMS data with service ID # 1 is a, the threshold for the amount of MBMS data with service ID # 2 is b, and the threshold for the amount of MBMS data with service ID # 3. Is c. As in the example shown in FIG. 5, a threshold is set and recorded for each service ID so that the service ID can be managed for each MBMS and the threshold can be managed for each MBMS.

  When the amount of MBMS data is equal to or less than the threshold value in step 403 shown in FIG. 4, the MBMS control unit 211 causes the transmission / reception control unit 212 to transmit the MBMS data to the GGSN 22 without using a special transmission method. The transmission timer is set to a default value (step 404).

  On the other hand, if the amount of MBMS data exceeds the threshold value in step 403, the MBMS control unit 211 describes “congestion control flag = ON” in the parameter of the control signal (step 405), and sends the control signal to the GGSN 22. An instruction to transmit to the transmission / reception control unit 212 is issued (step 406). Then, the transmission timer is set to a time longer than the default value (step 407), and the transmission timer is started (step 408).

  The transmission / reception control unit 212 that has received the control signal from the MBMS control unit 211 edits the control signal into a message for the GGSN 22 (step 409), and transmits the edited control signal to the GGSN 22 (step 410). Thereafter, when a signal indicating that the transmission timer has timed out is received from the MBMS control unit 211 (step 411), the MBMS data stored in the memory is transmitted to the GGSN 22 (step 412).

  When the GGSN 22 receives the control signal and the MBMS data from the BM-SC server 21, the GGSN 22 converts the data format of the MBMS data into a format corresponding to UTRAN 1, and transmits the converted MBMS data and the control signal to the SGSN 23. The operation of the GGSN 22 is not directly related to the characteristic part of the present invention except for the gateway function and the router function, and is the same as the conventional one, and thus detailed description thereof is omitted.

  If the threshold of the data amount is the same regardless of the type of MBMS or the type or identifier of MBMS data, even if the service ID is not included in the information notified from the transmission / reception control unit 212 to the MBMS control unit 211 Good. Further, a control unit that integrates the functions of the MBMS control unit 211 and the transmission / reception control unit 212 may be provided in the BM-SC server 21, and the control unit may execute the processing of the BM-SC server 21 illustrated in FIG.

  Next, the operation of the SGSN 23 until the MBMS data sent from the GGSN is sent to the base station control device in the information processing system of this embodiment will be described.

  FIG. 6 is a flowchart showing the operation procedure of the SGSN in the information processing system of this embodiment.

  When receiving the control signal and the MBMS data from the GGSN 22 (step 601), the U-plane control unit 232 stores the received MBMS data in the memory, and passes the received control signal to the call processing control unit 231 (step 602). The call processing control unit 231 checks whether “congestion control flag = ON” is described in the parameter of the control signal (step 603). If there is no specific instruction in the control signal, the call processing control unit 231 creates a destination RNC list so as to transmit data to all the RNCs to which MBMS data is transmitted, and passes it to the U-plane control unit 232 (step 604). Upon receiving the destination RNC list from the U plane control unit 232, the U plane control unit 232 sets a target base station control device and a U plane path (step 607), and then refers to the destination RNC list to specify the destination RNC list. MBMS data is transmitted to all base station controllers in the list (step 609).

  On the other hand, when “congestion control flag = ON” is described in the parameter in step 603, the call processing control unit 231 includes information on addresses and offset values of a plurality of base station control devices that are MBMS data transmission destinations. A destination RNC list is created (step 605), and the destination RNC list is transmitted to the U-plane control unit 232 (step 606).

  Upon receiving the destination RNC list from the call processing control unit 231, the U plane control unit 232 performs U plane path setting with each base station controller described in the destination RNC list (step 607). Subsequently, when the offset value described in the destination RNC list is read and the MBMS data is transmitted to each base station controller, the MBMS data stored in the memory is duplicated (step 608) so that the transmission interval becomes the offset value. Then, the replicated MBMS data is transmitted to each base station controller (steps 609 and 610).

  In FIG. 6, the U-plane control unit 232 transmits MBMS data to the base station control device 12b (step 609), and transmits MBMS data to the base station control device 12a after the time of the offset value has passed (step 609). 610).

  Note that a control unit that integrates the functions of the call processing control unit 231 and the U plane control unit 232 may be provided in the SGSN 23, and the control unit may execute the processing of the SGSN 23 illustrated in FIG.

  In the information processing system according to the present embodiment, if the amount of MBMS data is larger than the threshold, the BM-SC server waits for a predetermined time before sending data to the GGSN. When data having a data amount larger than the threshold value is intermittently sent, the data received intermittently is waited for a predetermined time and then passed to the GGSN. Therefore, the GGSN can process data with a large amount of data with a margin for conversion of the communication format. Furthermore, after that, when data is transmitted to the base station control apparatus via SSGN, the data transmission interval also becomes longer according to the standby time of the server apparatus, and the load on UTRAN 1 is reduced.

  In addition, when data is transmitted from the SGSN to a plurality of base station controllers, a time difference is provided between the data duplication process and the data transmission process, so that it is possible to prevent an increase in the processing load of the U-plane control unit inside the SGSN. Further, since data is transmitted in the UTRAN 1 with a time difference, an increase in the load on the UTRAN 1 can be prevented.

  In addition, although SGSN23 and GGSN22 were provided in this embodiment, you may provide the node which integrated the function of both SGSN and GGSN. Moreover, although the case of MBMS data including audio and image information has been described, it may be audio only or image only data. If the amount of data transmitted / received per unit time is large and causes the problem described in the problem column, it is a target of the data handled in the present invention, regardless of the type of information included in the data. . Furthermore, when the data amount of the table, the destination RNC list, and the MBMS data shown in FIG. 5 is large, these data may be stored in a storage unit provided separately from the memory in the control unit.

  In this embodiment, the threshold value registered in the management table by the BM-SC server 21 can be changed.

  The MBMS control unit 211 changes the threshold value stored in a memory (not shown) in its own device according to the traffic load amount of UTRAN1 communication as well as the change by the operator. The SGSN 23 periodically notifies the BM-SC server 21 of UTRAN1 communication traffic information. The MBMS control unit 211 receives communication traffic information from the SGSN 23, increases the threshold if it is determined that the network load is small from the communication traffic information, and decreases the threshold if it is determined that the network load is large.

  In this way, the threshold can be changed in the BM-SC in accordance with the network load of the UTRAN 1, so that the MBMS data can be provided to the user without delay when the network load is small. When the network load is large, the network load can be reduced by lowering the threshold value.

  As described above, in this embodiment, the threshold value is automatically changed without intervention by an operator. Therefore, when the network load is small, the threshold value is quickly changed to a transfer mode that does not cause a difference in data transfer time. It is possible to obtain an effect that serviceability is not further impaired.

  In this embodiment, the SGSN 23 can edit the destination list according to the number of mobile terminals connected to the base station control device.

  The call processing control unit 231 of the SGSN 23 creates a destination RNC list indicating the base station control device to which data is to be transmitted. At this time, the base station control device having many attached users transmits data in order. Edit the destination RNC list as follows. In this case, each base station control apparatus periodically notifies the SGSN 23 of the number of mobile terminals that are requesting delivery of MBMS data.

  As described above, in this embodiment, since data is transmitted from the base station controller with a large number of users, services can be provided without giving a time difference to many users, and the serviceability of MBMS is not impaired. An effect is obtained.

  In this embodiment, the SGSN 23 can change the transmission interval of the MBMS data.

  Regarding the change of the transmission interval (offset value) shown in FIG. 6, not only the change by the operator, but also at least the amount of data received by the call processing control unit 231 of the SGSN 23 per unit time or the load of the communication traffic of the UTAN 1 Any one of the observation targets may be changed, and the offset value may be changed according to the value. A threshold value that is a criterion for determining an offset value change is stored in advance. If the observation target value is larger than the threshold value, the offset value is made larger than the default value, and if smaller than the threshold value, the offset value is made smaller. Note that the communication traffic load amount may be observed by the SGSN 23 periodically receiving communication traffic information of the UTRAN 1 as in the first embodiment.

  As described above, in this embodiment, the transmission interval when transmitting MBMS data to each base station controller can be automatically changed not only by the operator but also by the call processing control unit. There is an effect that more detailed control can be performed depending on the total amount of data and the level of communication traffic.

It is a block diagram containing the example of 1 structure of the information processing system of this embodiment. It is a block diagram which shows one structural example of the BM-SC server shown in FIG. It is a block diagram which shows the example of 1 structure of SGSN shown in FIG. 3 is a flowchart showing an operation procedure of the BM-SC server shown in FIG. 2. It is a figure which shows an example of the table which a BM-SC server manages. It is a flowchart which shows the operation | movement procedure of SGSN shown in FIG.

Explanation of symbols

1 Wireless Access Network 2 Core Network 3 Internet 21 BM-SC Server 22 GGSN
23 SGSN
30 IP network

Claims (12)

Data transmitted from the first information processing apparatus via the first network is transmitted to the second information processing apparatus via the second network having a communication format different from that of the first network, and the second information processing apparatus An information processing system for distributing the data from an information processing device to a plurality of terminals,
A threshold that is a criterion for determining whether to delay transmission of the data is connected to the first network, and a data amount per unit time of the data received from the first information processing apparatus is examined. If the amount of data is greater than the threshold, a server device that sends the data after waiting for a predetermined time; and
Data that is connected to the server device and received from the server device is converted from a communication format in the first network to a communication format of the second network, and the converted data is converted to the data via the second network. A gateway device that transmits to the second information processing device;
An information processing system. A plurality of the second information processing devices are connected to the second network;
The server device transmits a control signal including an instruction to transmit a copy of the data at a predetermined time interval to the gateway device;
When the gateway device receives the control signal from the server device, the gateway device copies the converted data, and copies the copied data at a predetermined time interval via the second network. The information processing system according to claim 1, wherein the information processing system is transmitted to each of the information processing systems.   The information processing system according to claim 1, wherein the server device increases the threshold value as the traffic amount of the second network increases. A plurality of the second information processing devices are connected to the second network;
The gateway device is
The number of terminals connected to the plurality of second information processing apparatuses is checked, and the copied data is transmitted earlier in a plurality of the second information processing apparatuses as the number of terminals increases. Item 4. The information processing system according to any one of Items 1 to 3. The gateway device is
The amount of data received per unit time when receiving the data or the traffic amount of the second network is checked, and the larger the value, the larger the transmission interval of the copied data. The information processing system according to any one of claims. Data received from a first information processing apparatus connected via a first network is transferred to a gateway apparatus that converts the data to a communication format of a second network having a communication format different from that of the first network. A server device,
A storage unit storing a threshold value as a criterion for determining whether to delay transmission of the data;
A control unit that checks the data amount per unit time of the data received from the first information processing device, and transmits the data to the gateway device after waiting for a predetermined time if the data amount is larger than the threshold value When,
A server device. A server device for transferring data received from a first information processing device connected via a first network, and a second device having a communication format different from that of the first network for data received from the server device connected for communication. A data transfer method by an information processing system having a gateway device that converts the communication format of the network to a second information processing device via the second network,
The server device stores a threshold value that is a criterion for determining whether or not to delay transmission of the data, examines the data amount per unit time of the data received from the first information processing device, and the data amount is If it is greater than the threshold, after waiting for a predetermined time, the data is sent to the gateway device,
The gateway device converts data received from the server device from a communication format in the first network to a communication format of the second network, and converts the converted data to the second network via the second network. Data transfer method for transmitting to the information processing apparatus. A plurality of the second information processing devices are connected to the second network;
The server device transmits a control signal including an instruction to transmit a copy of the data at a predetermined time interval to the gateway device;
When the gateway device receives the control signal from the server device, the gateway device copies the converted data, and copies the copied data at a predetermined time interval via the second network. The data transfer method according to claim 7, wherein the data is transmitted to each of the data.   The data transfer method according to claim 7 or 8, wherein the server device increases the threshold value as the traffic amount of the second network increases. A plurality of the second information processing devices are connected to the second network;
The gateway device is
The number of terminals connected to the plurality of second information processing apparatuses is checked, and the copied data is transmitted earlier in a plurality of the second information processing apparatuses as the number of terminals increases. Item 10. The data transfer method according to any one of Items 7 to 9. The gateway device is
11. The data amount received per unit time of the data or the traffic amount of the second network is checked, and the larger the value, the larger the transmission interval of copied data. The data transfer method described. Data received from a first information processing apparatus connected via a first network is transferred to a gateway apparatus that converts the data to a communication format of a second network having a communication format different from that of the first network. A program for causing a computer to execute,
Stores a threshold value as a criterion for determining whether to delay transmission of the data,
Check the data amount per unit time of the data received from the first information processing device,
A program for causing the computer to execute a process of transmitting the data to the gateway device after waiting for a predetermined time if the data amount is larger than the threshold value.

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