JP2006174346A - Data transmission controller, data transmission control method and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a data transmission technology by which large quantities of high-priority data can be transmitted during a necessary time period without depending on traffic conditions of a communication network. <P>SOLUTION: When an OA apparatus P1 transmits data p1 to an image forming apparatus M1, it transmits control information including "information on order of priority" to a control server P0. When the control server P0 receives the control information, it compares the priority with other data in the course of transmission on the communication network 100. It controls the data transmission according to the order of priority. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a technique for transmitting a large amount of data via a communication network.

  Conventionally, when a large amount of data is transmitted through a communication interface such as a LAN or the Internet, a load is imposed on the communication network for data transmission, or the transmission takes time depending on the traffic situation of the communication network. There's a problem.

  The above problem will be described below with a specific example. FIG. 7 is a diagram showing an example of the overall configuration of a transmission system using a communication network such as a LAN. FIG. 8 shows the occupancy rate of the communication network based on transmission data for the transmission system shown in FIG. It is the figure which showed the result of having investigated. In FIG. 7, P and Q are communication networks such as a LAN, and A to H are OA devices such as personal computers and image forming apparatuses. The OA devices A to H are connected to the communication network P or the communication network Q, and a to h denote connection points between the OA devices A to H and the communication network P or the communication network Q. In FIG. 8, “Net <ad>” indicates the communication network occupation rate by the transmission data between the connection point a and the connection point d, with the horizontal axis as the time axis, “50% or less”, “50% or more”. , “100%” is divided into three stages. This occupation ratio indicates an average of communication network occupation ratios in the past week. “Net <db>”, “Net <bfp>”, “Net <efq>”, “Net <he>”, “Net <ch>”, and “Net <gc>” are also “Net <ad>”. The occupancy rate of the communication network between each connection point is shown in the same manner as in FIG.

  In FIG. 8, in the time zone where the communication network occupancy rate is “100%”, the data transmission speed becomes slow, and even when data with particularly high priority is transmitted, the data transmission completion time The problem that becomes slow occurs.

  In order to transmit a large amount of data, for example, a method of compressing data and reducing the amount of data before transmission is conventionally used. However, since the amount of data is enormous, the conventional compression method compresses the data. Some data formats are not suitable for compression depending on the type of data, and this cannot always be solved when a large amount of data is transmitted.

  On the other hand, the following technologies are disclosed for the purpose of transmitting a large amount of data. The technique described in Patent Document 1 or 2 uses e-mail as a data transmission means, transmits data in pieces, and combines them after reception. As a result, even if the data transfer amount increases, it is possible to avoid the transfer restriction of the electronic mail due to its capacity, thereby enabling a large amount of data to be transmitted and received by the electronic mail.

  In addition, techniques as disclosed in Patent Documents 3 to 6 are disclosed for the purpose of controlling data transmission according to data contents and an operation state of a transmission destination apparatus. The technique described in Patent Document 3 confirms whether or not a data transmission destination terminal device is communicable, and transmits data when communication is possible, so that data transfer is wasted because communication is impossible. It is possible to prevent such a situation. Further, the technique described in Patent Document 4 allows various user needs of e-mails to be set for each e-mail transmission method by setting transmission rules such as right or wrong of transfer and transfer destination for each time zone. Can be met. In addition, the technology described in Patent Document 5 identifies whether a received message is a highly urgent immediate message or a less urgent waiting message when a short message (hereinafter referred to as a message) input from a calling subscriber is received. In the case of waiting messages, the call identification information that sets the transfer time to the called subscriber in a low traffic time zone and charges the message transfer service in that time zone is set as the calling subscriber number and the called subscriber. The message is stored in the SMS together with the number, and the waiting message is read and transmitted to the called subscriber when the transfer time is reached. As a result, the traffic can be transmitted to the called subscriber at a time when the nighttime traffic is low, and the traffic can be equalized by automatically shifting the daytime traffic to the nighttime. In addition, the technology described in Patent Document 6 uses a communication line when distributing various contents such as a music content, a game program, still image data, and moving image data to a communication terminal through a communication network such as a telephone network. In a time zone in which it is possible to receive distribution at a low price that is not crowded, it is possible to receive distribution of the target content.

JP 2002-259070 A JP 2002-259212 A JP 2003-264648 A JP 2004-015782 A JP 2003-047057 A JP 2001-337882 A

  However, the techniques of Patent Documents 1 to 6 described above have a problem that data is transmitted even when the traffic of the communication network is high, resulting in a burden on the communication network. Further, even when a large amount of data with high priority is transmitted, there is a problem that when the traffic is high, it takes time for transmission or waits for transmission.

  An object of the present invention is to provide a data transmission technique capable of transmitting a large amount of high-priority data in a necessary time zone without depending on the traffic situation of a communication network in view of the above-described conventional problems. It is in.

  In order to solve the above-described problem, the present invention relates to data transmitted over a communication network, receiving means for receiving priority information indicating transmission priority for the data, and transmission / reception of predetermined data, When receiving the priority information by the dedicated time zone setting means for providing a dedicated time zone and the receiving means, it is determined whether or not the current time is within the dedicated time zone, If it is determined, a data transmission control device comprising: data transmission control means for restricting or interrupting data transmission based on the received priority information.

In a preferred aspect of the present invention, the data transmission control means performs data transmission control by transmitting control instruction information for instructing a data reception mode to a communication device that receives the data.
Moreover, in another preferable aspect of the present invention, the communication system further comprises traffic status confirmation means for confirming the traffic status of the communication network, and the time zone setting means is based on the traffic status confirmed by the traffic status confirmation means. The time zone is set.

In addition, the present invention reads a dedicated time zone provided for transmission / reception of predetermined data stored by the storage means, and determines whether or not the current time is the dedicated time zone If the determination function determines that it is within the dedicated time zone, data transmission other than the data to be prioritized is based on the priority information indicating the transmission priority of the data transmitted over the communication network. A data control function for restricting or interrupting the program is provided.
Further, the present invention provides a reception step for receiving priority information indicating the priority of transmission for data transmitted over a communication network, and a dedicated time zone for transmission / reception of predetermined data. When the priority information is received by the time zone setting step and the reception step, it is determined whether or not the current time is within the dedicated time zone, and if it is determined that the current time is within the dedicated time zone, And a data transmission control step for restricting or interrupting data transmission based on the priority order information.

(1) Configuration First, the overall configuration of the data transmission system according to the present embodiment will be described.
FIG. 1 is a diagram illustrating an example of the overall configuration of the data transmission system according to the present embodiment. In FIG. 1, P1, P2, and P3 are OA devices such as personal computers. Reference numerals M1 and M2 denote image forming apparatuses such as a printer, a scanner, or a multifunction peripheral having a plurality of these functions. P0 is a control server that monitors and controls data transmission of the OA devices P1 to P3 or the image forming apparatuses M1 and M2. The OA devices P1 to P3, the image forming apparatuses M1 and M2, and the control server P0 are connected to a communication network 100 such as a LAN (Local Area Network), and transmit / receive data to / from other apparatuses via the communication network 100. Do. In the following description, for convenience of description, when it is not necessary to distinguish between the OA devices P1 to P3 and the image forming apparatuses M1 and M2, these will be referred to as “communication apparatus 1”. On the communication network 100, the communication device 1 once transmits data to the control server P0, and the control server P0 transfers the data to the destination communication device 1, whereby data is transmitted between the communication devices 1. Is called.

Next, the overall configuration of the control server P0 according to the present embodiment will be described.
FIG. 2 is a diagram illustrating an example of the overall configuration of the control server P0 according to the present embodiment. In FIG. 2, reference numeral 10 denotes an arithmetic device such as a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM ( Random Access Memory) and the like, and controls each unit of the control server P0 according to the control program PRG21 stored in the storage unit 20. Each component described below operates based on an operation command from the control unit 10.

  Reference numeral 30 denotes a communication interface for communicating with the communication device 1 or the like. The control server P0 is connected to the communication network 100 via the communication interface 30. Reference numeral 40 denotes a user interface for the user to perform various operations. The user interface 40 includes a display unit 41 and an operation unit 42. The display unit 41 is a liquid crystal display, for example, and displays an image based on data supplied by the control unit 10. The operation unit 42 is an operation unit such as a keyboard or a mouse, for example, and supplies a signal corresponding to the operation content of the user to the control unit 10.

  In the non-volatile area of the storage unit 20, transmission control time zone information INF22, a data table TBL23 being transmitted, and a data table TBL24 awaiting transmission are stored. The transmission control time zone information INF22 is information indicating a time zone in which important data needs to be transmitted immediately. In this time zone, the control server P0 performs a data transmission control process that is a feature of the present embodiment. At the same time, the received data is transferred to the destination communication device 1. At times other than this time zone, the control server P0 does not perform the data transmission control process and transfers the received data as it is to the destination communication device 1. The transmission control time zone information INF22 is set by the administrator of the control server P0 using the user interface 40.

  The control unit 10 of the control server P0 performs the data transmission control process by using the data table TBL23 during transmission and the data table TBL24 during transmission waiting in the time zone indicated by the transmission control time zone information INF22. The in-transmission data table TBL23 is a table for storing control information of data being transmitted on the communication network 100. When it is determined that data is to be transmitted to another communication device 1, the communication device 1 transmits data to be transmitted and control information to the control server P0. The control unit 10 of the control server P0 performs data transmission control processing according to the control information, and stores the control information of the data for which transmission has been started in the data table TBL23 during transmission. The control unit 10 can confirm which data is being transmitted by referring to this table.

  The transmission waiting data table TBL24 is a table for storing control information of data whose transmission is suspended or waited by the transmission control processing of the control server P0. When the communication device 1 that is the data transmission destination is receiving high-priority data, the control server P0 waits for transmission of data other than the high-priority data. In this case, the control server P0 stores the received control information in the transmission standby data table TBL24. The control unit 10 can confirm which data is waiting for transmission by referring to this table.

  In the transmission data table TBL23 and the transmission standby data table TBL24, as shown in FIG. 3, "transmission source apparatus information", "destination apparatus information", and "priority information" of the transmission or transmission standby data are stored. Including control information is stored. This control information is information transmitted to the control server P0 when the communication device 1 transmits data to the other communication device 1, and is information that the control unit 10 refers to in order to control data transmission. The “transmission source device information” is a device identifier for identifying the communication device 1 that is a data transmission source, such as an IP address. “Destination device information” is a device identifier for identifying the communication device 1 that is a data transmission destination, such as an IP address. “Priority information” is information indicating the priority of data to be transmitted. In the “priority information”, any one of four types of numerical information “11”, “10”, “01”, and “00” is set. “11” indicates “unconditional top priority”, and the transmission of other data is suspended until the transmission of the data is completed. “10” indicates “priority designation”, and the transmission of the data is completed by a designated date (for example, until the next date, etc.), but not immediately. “01” indicates “high priority”, and packet transmission is performed at a ratio of 10 to 1 with respect to normal data transmission, whereby data transmission processing is preferentially performed over other data. “00” indicates “normal handling” and indicates normal data that is not priority data.

  The communication device 1 generates the control information described above at the timing when data transmission to the other communication device 1 starts or the data transmission ends, and controls the generated control information via the communication network 100. Send to server P0. This control information includes information of “source device information”, “destination device information”, “priority information”, and “start / end type”. The “start / end type” is information indicating whether data transmission starts or ends. At the start of transmission, control information in which information indicating “start” is set in the “start / end type” is transmitted, and control information in which information indicating “end” is set is transmitted at the end of transmission. The control unit 10 of the control server P0 refers to the “start / end type” to determine whether the transmission of the data is started or the transmission is completed. The control server P0 reads “priority information” from the received control information, determines the priority of the data, and performs data transmission control processing based on the priority. This data transmission control process will be described in detail later.

(2) Operation Next, the operation of the transmission system according to the present embodiment will be described.
First, the data transmission control process performed by the control unit 10 of the control server P0 will be described below with reference to the flowchart shown in FIG.
In the following description, for convenience of explanation, the received control information is “control information A”, the data indicated by the control information A is “data A”, and the communication device indicated by “destination device information” included in the control information A 1 will be described as “destination communication apparatus A”.

When the control unit 10 of the control server P0 receives the control information A, the control unit 10 reads the transmission control time zone information INF22 and determines whether or not the current time is the time limit zone (S200). If it is outside the time limit, the control unit 10 determines that it is not necessary to perform control processing, and transfers the data A as it is without performing the subsequent processing shown in FIG. In this case, the destination communication apparatus A performs normal reception processing on the data A.
If it is determined in step S200 of FIG. 4 that the time is within the time limit, the control unit 10 reads the “start / end type” from the control information A, and starts data transmission or ends data transmission. Is determined (S201). When it is determined that the data transmission is started, the instruction information transmission process shown in step S202 is performed, and the instruction information for instructing the control content of the data A and the data A is transmitted to the destination communication apparatus A.

  FIG. 5 is a flowchart showing details of the instruction information transmission process described above. First, the control unit 10 determines whether or not the destination communication device A is receiving data having “11” as the “priority information” (S300). This determination is made based on whether or not control information in which “destination device information” is the communication device A and “priority information” is “11” is stored in the data table TBL23 during transmission. If it is stored, it is determined that it is being received. If reception is in progress, it is necessary to wait for transmission of data A, so control information A is stored in the transmission standby data table TBL24 (S301), and the process ends without sending instruction information to the destination communication device A To do. On the other hand, when not receiving, the “priority information” of the control information A is read and the priority is judged (S302). When “11” is set in the “priority information”, instruction information for interrupting reception processing of other data is transmitted to the destination communication apparatus A until reception of the data A is terminated. (S303). When receiving this instruction information, the destination communication device A interrupts the reception process of data other than the data A, and performs the reception process of only the data A. As a result, data A is preferentially received. After transmitting the instruction information, the control unit 10 stores the control information A in the in-transmission data table TBL23 (S304).

  If it is determined in step S302 in FIG. 5 that the “priority information” is “00” or “01”, the control unit 10 determines whether or not instruction information needs to be transmitted (S305). For example, when a transmission request for data “00” is made while data “priority information” is “01”, the ratio of “01” data to “00” data is 10: 1. It is necessary to transmit instruction information indicating that packet processing is to be performed. As described above, when it is determined that the destination communication apparatus A needs to change the reception process, instruction information to that effect is transmitted (S306). Then, the control information A is stored in the data table TBL23 during transmission (S304), and the process is terminated.

  When the “priority information” is “10”, the control unit 10 issues a timer inside the control server P0 so that the timer is started at the time when the transmission must be completed (S307). When the time at which transmission must be completed has arrived, the control unit 10 changes the “priority information” of the control information A to “11”, and performs the instruction information transmission process shown in FIG. . As a result, data A having “10” as the “priority information” can be transmitted with the highest priority when data transmission is not completed by the designated time. As described above, the control unit 10 of the control server P0 transmits the instruction information based on the value of the “priority information” to the destination communication device A. When receiving the instruction information, the destination communication apparatus A performs a reception process based on the instruction content.

  Returning to the description of FIG. In step S201 of FIG. 4, if the “start / end type” of the received control information A is “end”, the control information received at the start of transmission is deleted from the data table TBL23 during transmission (S203). Then, the “priority information” of the control information A is determined (S204). If the “priority information” is “11”, it is determined by referring to the transmission standby data table TBL24 whether or not transmission standby data is stored (S205). If there is data waiting for transmission, it is necessary to start transmission of data that has been kept waiting for transmission by giving priority to data A, so that the data is read (S206), The instruction information transmission process shown in FIG. 5 is performed (S207), and data transmission is started.

  If “priority information” is “10” in step S201 of FIG. 4, the timer set at the start of transmission is discarded (S208). This is because it is not necessary for the control unit 10 to know the time at which the transmission should be completed because the data transmission has already been completed. When the “priority information” is “01” or “00”, it is determined whether or not the instruction information should be transmitted (S209). If it is determined that the instruction information needs to be issued, the instruction information is transmitted to the destination communication device. A is transmitted to A (S210). The data transmission control process is performed as described above.

Next, a specific operation of the transmission system shown in FIG. 1 will be described.
Hereinafter, in the transmission system illustrated in FIG. 1, operations when the OA devices P1 to P3 transmit data to the image forming apparatus M1 in the following order will be described with reference to FIG.
[1] The OA device P2 transmits “normally handled” data p2.
[2] The OA device P1 transmits the data p1 of “high priority”.
[3] The OA device P3 transmits the data p3 of “unconditional top priority”.

FIG. 6 is a diagram illustrating an example of an operation sequence of the transmission system according to the present embodiment.
First, the OA device P2 sets “00” in “priority information”, the device identifier of the OA device P2 itself in “source device information”, and the device identifier of the image forming apparatus M1 in “destination device information”. Control information is generated, and the generated control information and data p2 are transmitted to the control server P0 (S101). When receiving control information from the OA device P2, the control unit 10 of the control server P0 performs data transmission control processing based on the control information.

  Since the “priority information” of the data p2 is “00” and the image forming apparatus M1 is not receiving other data, the control unit 10 of the control server P0 instructs in the process of step S305 in FIG. It is determined that there is no need to transmit information. Therefore, the control unit 10 transmits only the data p2 to the image forming apparatus M1 without transmitting the instruction information (S102). Since the image forming apparatus M1 does not receive the instruction information from the control server P0, the image forming apparatus M1 performs normal data reception processing on the data p2.

  Next, the OA device P1 tries to transmit data p1 to the image forming apparatus M1. At this time, the OA device P1 generates control information in which “01” is set in the “priority information”, and transmits the generated control information and data p1 to the control server P0 (S103). When receiving the control information, the control unit 10 of the control server P0 performs the data transmission control process shown in FIG. Currently, the data to be received by the image forming apparatus M1 is two data, ie, data p2 and data p1, and the “priority information” of the data p1 is “01”, and the “priority information” of the data p2 is Since it is “00”, the control unit 10 of the control server P0 uses the priority order information to give instruction information indicating that the data p1 and the data p2 are to be received at a ratio of 10 to 1, and the image forming apparatus. It transmits to M1 (S104). The image forming apparatus M1 receives this instruction information from the control server P0, and changes the reception process so as to receive the data p1 and the data p2 at a ratio of 10: 1 based on the contents of the instruction. As a result, the data p1 is preferentially received with respect to the data p2.

  When the transmission of the data p2 is completed, the OA device P2 transmits control information in which “end” is set in the “start / end type” to the control server P0 (S105). Upon receiving this control information, the control server P0 performs the data transmission control process shown in FIG. 5, and transmits instruction information for performing the normal reception process to the image forming apparatus M1 (S106). The image forming apparatus M1 changes the reception process based on the received instruction information and performs a normal data reception process.

  Next, the OA device P3 transmits data p3 and control information to the control server P0 in order to transmit data p3 to the image forming apparatus M1 (S107). When receiving the control information of the data p3, the control unit 10 of the control server P0 performs data transmission control processing based on “priority information” included in the control information. Since the priority information of the data p3 is “11”, the control server P0 transmits to the image forming apparatus M1 instruction information for interrupting reception of data other than the data p3 (S108). Upon receiving this instruction information, the image forming apparatus M1 interrupts the data p1 reception process and performs only the data p3 reception process. As a result, the transmission of the data p3 is performed with priority.

  When the transmission of the data p3 is completed, the OA device P3 transmits instruction information indicating the end of transmission to the control server P0 (S109). Upon receiving this instruction information, the control server P0 transmits instruction information indicating a change in reception control processing to the image forming apparatus M1 (S110). Upon receiving this instruction information, the image forming apparatus M1 resumes the data reception process from the OA device P1.

  As described above, for the data transmitted on the communication network 100, the control server P0 transmits the instruction information about the data reception process to the communication device 1 on the data reception side based on the data priority information. Thus, the communication device 1 on the receiving side performs a reception process based on the received instruction information, whereby priority is given to high-priority data without depending on the traffic status of the communication network 100 in a predetermined time zone. Can be transmitted.

<Modification>
As mentioned above, although embodiment of this invention was described, this invention is not limited to embodiment mentioned above, It can implement with another various form. An example is shown below.
(1)
In the embodiment described above, the control server P0 controls data transmission on the communication network 100. However, without using the control server P0, a program for realizing a transmission control function is installed in each communication device 1, and data is transmitted. The receiving side communication device 1 itself may perform the data transmission control process shown in FIG.

  In the above-described embodiment, the control server P0 transmits the instruction information indicating the content of the reception process to the communication device 1 on the data reception side, and changes the reception process in the communication device 1 on the reception side. The data transmission control method is not limited to this. For example, the control server P0 may transmit instruction information indicating the content of the transmission process to the communication device 1 that is the transmission source. In this case, the communication device 1 that has received the instruction information restricts the transmission process based on the instruction content or interrupts the transmission process.

(2)
In the above-described embodiment, the communication apparatus 1 transmits the control information and the actual data as separate data. However, the method of transmitting the control information is not limited to this, and the data that is actually transmitted is transmitted. A field for setting “priority information” or the like may be provided in the predetermined header, and the communication apparatus 1 may set “priority information” in the header and transmit the data to the control server P0. In this case, the control server P0 determines the priority with reference to the “priority information” from the predetermined header of the received data.

(3)
In the above-described embodiment, the communication device 1 transmits control information and actual data to the control server P0, and the control server P0 transfers the received data to the communication device 1 as a transmission destination as needed. Actual data may be directly transmitted to the communication apparatus 1 as the transmission destination. In this case, the communication device 1 transmits only the control information to the control server P0, and the actual data is directly transmitted to the communication device 1 as the transmission destination.

  In the above-described embodiment, four types of information set in the “priority information” are provided in the control information as a method for determining whether or not the data should be prioritized. The information is not limited to such information, and various other information can be used. Further, the priority determination method is not limited to this, and any method may be used as long as the priority can be determined.

(4)
In the embodiment described above, the administrator of the control server P0 sets the time limit for the transmission control time zone information INF22. However, the method for setting the time limit is not limited to this, and the control server P0 is not limited thereto. However, the traffic situation of the communication network 100 may be monitored, and a suitable time zone with low traffic may be automatically determined and updated. For example, the traffic status of the communication network 100 may be confirmed using a protocol such as SNMP (Simple Network Management Protocol).

  As a result, data can be transmitted in a time zone when traffic is low, and data can be transmitted more reliably within a specified time.

(5)
In the embodiment described above, for data in which “priority designation priority” is set in the “priority information” of the control information, if the data transmission is not completed at the time when transmission should be completed, the “priority information” Is changed to "Unconditional priority", but data transmission is performed, but the data transmission control method when "priority designation priority" is set in "priority information" is not limited to this, Any other control method may be used. For example, the control unit 10 of the control server P0 determines a time zone in which traffic is low (for example, from midnight) based on the statistics so far, and the control unit 10 calculates a transmission time including a time required for data merging processing. To do. In the determined time zone, data transmission is performed with “priority information” set to “high priority”. If the transmission is not completed at the time when the calculated transmission time is subtracted from the time at which the transmission should be completed, the data transmission is performed by changing the “priority information” to “unconditional priority”. To. Specifically, for example, in the case of data that absolutely needs to be transmitted by 7 am the next day, if it is determined that the transmission takes 1 hour, the normal The data transmission starts with the priority, and when the data has not ended, the “priority information” is changed to “high priority” in the middle of the transmission. Then, from 6 am the next day, the “priority information” is changed to “unconditional priority”.

  This makes it possible to transmit the data more reliably within the specified time even for data that does not need immediate transmission but must be completely transmitted by a certain date.

1 is a diagram illustrating an overall configuration of a transmission system according to an embodiment of the present invention. It is a figure which shows the whole structure of the control server P0 of the embodiment. It is a data block diagram of transmission data table TBL23 of the embodiment. It is a figure which shows the data transmission control process of the embodiment. It is a figure which shows the instruction information transmission process of the embodiment. It is a figure which shows the sequence of operation | movement of the embodiment. It is a figure which shows the whole structure of a transmission system. It is a figure which shows the network occupation rate of a transmission system.

Explanation of symbols

P0: control server, P1, P2, P3: OA equipment, M1, M2: image forming apparatus, 10: control unit, 20: storage unit, 30: communication interface, 40: user interface.

Claims (5)

Receiving means for receiving priority information indicating the priority of transmission of data transmitted over a communication network;
Dedicated time zone setting means for setting a dedicated time zone for transmission and reception of predetermined data;
When the priority information is received by the receiving means, it is determined whether or not the current time is within the dedicated time zone. If it is determined that the current time is within the dedicated time zone, the received priority information is included in the received priority information. Data transmission control means for restricting or interrupting data transmission based on;
A data transmission control device comprising:   2. The data transmission according to claim 1, wherein the data transmission control means performs data transmission control by transmitting control instruction information for instructing a data reception mode to a communication apparatus that receives the data. Control device. Comprising traffic status confirmation means for confirming the traffic status of the communication network;
The data transmission control device according to claim 1, wherein the time zone setting unit sets the time zone based on the traffic situation confirmed by the traffic situation confirmation unit. On the computer,
A determination function for reading a dedicated time zone provided for transmission / reception of predetermined data stored by the storage means and determining whether the current time is the dedicated time zone; and
If it is determined by the determination function that it is within the dedicated time zone, based on priority information indicating the priority of transmission of data transmitted over a communication network, data transmission other than data to be prioritized is performed. Data control function to limit or interrupt,
A program that realizes In a control method of a data transmission apparatus that performs transmission control for data on a communication network,
A receiving step of receiving priority information indicating a priority of transmission for data on the communication network;
A dedicated time zone setting step for setting a dedicated time zone for transmission and reception of predetermined data;
When the priority order information is received in the receiving step, it is determined whether or not the current time is within the dedicated time zone. If it is determined that the current time is within the dedicated time zone, the received priority order information A data transmission control step for restricting or interrupting data transmission based on
A data transmission control method comprising:

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