JP2003273925A - Information transmission system and transmission control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To promptly and surely transmit information regarding an information transmission system by which the same piece of information from a master station is transmitted to a plurality of slave stations and to provide a transmission control method. <P>SOLUTION: The information transmission system transmits the same piece of information from the master station 1 to a plurality of the slave stations 2-1 to 2-n via a network 3, the master station 1 is provided with a control part 11 that performs a processing for transmitting the same piece of information to a plurality of the slave stations 2-1 to 2-n by multi-cast by using a multi-cast router 4 and for re-transmitting the information to the slave stations which can not receive delivery confirmation from the slave stations by unicast, a transmission processing part 12, a reception processing part 13 that receives delivery confirmation and a data base 14 and the slave stations 2-1 to 2-n are provided with information processing parts 21 that receives the information from the master station 1 and performs transmission processings of the delivery confirmation to the master station 1 and transmission/reception parts 22. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to information transmission in which a master station and a plurality of slave stations are connected via a network so that information such as disaster prevention information can be reliably transmitted from the master station to a plurality of slave stations. The present invention relates to a system and a transmission control method.

[0002]

2. Description of the Related Art Various information transmission systems are known in which a master station and a plurality of distributed slave stations are connected via a wired or wireless network, and the same information is transmitted from the master station to each slave station. ing. As such an information transmission system, for example, a disaster prevention command system is known. In this disaster prevention command system, the command center is the master station, and the slave stations are located at the unit of municipality.
Various alarm information such as flood warning, tsunami warning, fire warning, and earthquake warning is sent to each slave station.

As a method of transmitting the same information to a plurality of slave stations, it is possible to roughly divide it into individual transmission (Unicast; unicast) and broadcast transmission (Multicast). The individual transmission method is, for example, TCP (Transmission Cosion).
control protocol) is applied to send information to the slave station designated by the master station, and when the slave station receives the information from the master station, the slave station sends a delivery confirmation. The parent station is
By the delivery confirmation, the next slave station is designated and the information is similarly sent out. Such processing is repeated for the number of slave stations.

The broadcast transmission method is, for example, UDP (Us
er Datagram Protocol) is applied to broadcast from the master station to each slave station, and it is possible to speed up information transmission to a large number of slave stations. In addition, the information transmission system is hierarchically structured, multiple bases are provided between the master station and multiple slave stations, the master station transmits information to the base once, and each base transmits information to the slave stations under its control. A system for transmitting information by individual transmission or broadcast transmission is also known.

[0005]

In a system in which information is transmitted from a master station to a plurality of slave stations by the aforementioned individual transmission method, the larger the number of slave stations, the longer the transmission time becomes. However, this is a problem when urgent information is quickly transmitted to each slave station. Also, in a system that transfers information by a broadcast transmission method, the same information is sent to all slave stations all at once, so the time required for transmission will be short, but when UDP is applied However, there is a problem that the master station cannot confirm whether or not the information is surely transmitted to each slave station. Further, in a system in which the network has a hierarchical structure, it is necessary to install a plurality of bases, so there is a problem that the system cost rises. Moreover, there is a problem that the system cannot cope with the slave station temporarily installed. It is an object of the present invention to speed up the process of transmitting information to a plurality of slave stations and to easily confirm that the information has been reliably transmitted.

[0006]

An information transmission system of the present invention will be described with reference to FIG. 1. Information transmission for transmitting the same information from a master station 1 to a plurality of slave stations 2-1 to 2-n. In the system, the master station 1 sends the same information to a plurality of slave stations 2-1 to 2-n by multicast, and unicasts the slave stations that cannot receive the delivery confirmation from the slave stations. A control unit 11 that performs a process of retransmitting information,
Each of the slave stations 2-1 to 2-n includes an information processing unit 21 and a transmission / reception unit 22 that receive information from the master station 1 and perform a transmission confirmation transmission process to the master station 1. The master station 1 is a slave station 2-1 to 2
A database 14 for managing the status of a plurality of slave stations by receiving a request for addition or deletion of -n or periodic information is provided.

The transmission control method of the present invention is a transmission control method for transmitting the same information from the master station 1 to a plurality of slave stations 2-1 to 2-n, and the master station 1 multicasts a plurality of slaves. A process of transmitting the same information to the stations 2-1 to 2-n,
The slave stations 2-1 to 2-n transmit the delivery confirmation to the master station 1 when receiving the information from the master station 1, and the slave stations 2-1 to 2 -n even after the delivery confirmation time in the master station 1 elapses. The number of slave stations that cannot receive the delivery confirmation is compared with a threshold value, and when the number of slave stations that cannot receive the delivery confirmation is greater than the threshold value, the above information is retransmitted by multicast. And a step of retransmitting the information.

Further, the delivery confirmation time for monitoring reception of delivery confirmation from the slave stations 2-1 to 2-n in the master station 1 is changed according to the transmission data length, and the transmission data length is equal to or shorter than a predetermined length. At the time of, the process of setting to the predetermined minimum delivery confirmation time can be included. Also, from the master station 1 to the slave stations 2-1 to 2-
It is possible to include a process of giving a priority to the transmission data to be transmitted to n and performing transmission processing of the transmission data having a high priority by an interrupt. A process of giving generation time information to the transmission data to be transmitted from the master station 1 to the slave stations 2-1 to 2-n, comparing the generation time information and prioritizing the transmission data having the previous generation time. Can be included. Further, the master station 1 includes a process of managing, by the database 14, the slave stations based on the computer names of the plurality of slave stations 2-1 to 2-n and the addresses for unicast, removal, and normality. be able to.

[0009]

1 is an explanatory view of an embodiment of the present invention, in which 1 is a master station, 2-1 to 2-n are slave stations, 3 is a network, 4 is a multicast router, and 11 is a control. Department,
Reference numeral 12 is a transmission processing unit, 13 is a reception processing unit, 14 is a database, 21 is an information processing unit, and 22 is a transmission / reception unit. A plurality of slave stations 2-1 to 2-n are connected to a master station 1 such as a command center via a network 3 to form an information transmission system.

The master station 1 includes a control section 11, a transmission processing section 12, a reception processing section 13 and a database 14, and the database 14 stores information for managing the respective slave stations 2-1 to 2-n. . Therefore, the master station corresponds to a command center in the disaster prevention command system and the like, and has a function of transmitting various data including voices and images to the slave stations 2-1 to 2-n. Each of the slave stations 2-1 to 2-n corresponds to an information receiving unit that receives various contact information such as alarm information from the command center, includes an information processing unit 21 and a transmitting / receiving unit 22, and is a parent unit. It includes a function of processing information from the station 1 and displaying or printing out on a display. In addition, child station 2-1
2-n has a function of transmitting a delivery confirmation to the master station 1 by the information processing unit 21 and the transmission / reception unit 22 even when the information from the master station 1 is received by multicast.

Information such as disaster information from the master station 1 is sent to the control unit 1
From the transmission processing unit 12 under the control of 1, first, each slave station 2
It is transmitted by multicast to -1 to 2-n. The slave station that received this information, although receiving information by UDP, sends a delivery confirmation to the master station 1, and the master station 1 retransmits the information by unicast to the slave station that could not receive the delivery confirmation. To do. Therefore, for example, in the master station 1,
Multicast SAP (Service Advertiser)
TCP and IP (Inter) for receiving delivery confirmation from the slave station.
Net Protocol) address. Also, the slave stations 2-1 to 2-n have a multicast address,
Allocate the TCP IP address for retransmission.

[0012] The multicast router 4 has a function of copying data and transmitting the data by broadcast, and in terms of procedure, because it uses UDP, it does not include a procedure of delivery confirmation. Therefore, as described above, the slave stations 2-1 to 2-
n is provided with a function capable of transmitting a delivery confirmation.
In addition, the master station 1 transmits each slave station 2 via the multicast router 4.
After transmitting the data to -1 to 2-n, the database 14
It confirms whether or not the delivery confirmation from the slave stations 2-1 to 2-n managed by can be received, identifies the slave station which cannot receive the delivery confirmation, and sequentially performs retransmission processing by unicast. It has a function. In this case, the master station 1
After sending by multicast, set the time that is expected to be able to receive the delivery confirmation, that is, the delivery confirmation time, and perform resend processing for the slave station that could not receive the delivery confirmation even after that time It will be. If there are a large number of slave stations that cannot receive the delivery confirmation, the same data will be transmitted again by multicast.

FIG. 2 is a transmission control flowchart according to the embodiment of the present invention, in which the master station 1 calculates the delivery confirmation time based on the transmission data length for each slave station 2-1 to 2-n. (A1). This delivery confirmation time can be a value obtained by dividing the data length to be transmitted by the data length coefficient. For example, if the data length coefficient is 100, the data length to be transmitted is 1,000,000 bytes. /
100 = 10,000 [ms] (10 seconds), and 50
In the case of 0 byte, 500/100 = 5 [ms]. If the minimum value is set to 1 second, the delivery confirmation time is set to 1 second even when the calculation time is 5 ms. That is, when the transmission data length is less than or equal to the predetermined length, the predetermined time is set to the predetermined one second or the like.

At the first time, the data is transmitted from the master station to each slave station by multicast (A2). Slave stations 2-1 to 2-
Since n is for sending the delivery confirmation by receiving the transmission data from the parent station, in the parent station 1, whether or not the delivery confirmation could be received and whether the delivery confirmation time has elapsed or not. (A3), all slave stations 2- within the delivery confirmation time
If the delivery confirmations from 1 to 2-n can be received, it means that all the slave stations 2-1 to 2-n have surely received, and the process is ended.

When the delivery confirmation time has elapsed, the number of slave stations that have not sent a delivery confirmation, that is, the number of undelivered slave stations is compared with the threshold value (A4), and the number of undelivered slave stations is less than the threshold value. If the number is large, it is retransmitted by multicast (A5). If the number of undelivered slave stations is less than the threshold value, undelivered slave stations are sequentially designated and retransmitted by unicast (A6). In this case, T
Since the transmission is performed by the CP procedure, if the transmission is normally completed, it can be processed as a delivery confirmation, and thus the processing can be ended before the delivery confirmation is received. The threshold in step (A4) can be selected in consideration of the time required for unicast retransmission processing, and should be set to, for example, 50% or 30% of the total number of slave stations. You can Further, the above-mentioned retransmission processing and the like can be realized by the processing function in the control unit 11 of the master station 1.

FIG. 3 is a processing flowchart of the slave station according to the embodiment of the present invention. When data is received from the master station by the multicast address (B1), the slave station sends a delivery confirmation to the master station by unicast. (B3). Also, when data is received from the master station with a unicast address (B2), similarly, a delivery confirmation is transmitted to the master station by unicast (B2).
3). Such delivery confirmation transmission can be performed within the transmission / reception unit 22 or under the control of the information processing unit 21. Further, the master station 1 uses the multicast address to make the slave stations 2-1 and 2-2.
It is possible to perform a unicast retransmission process by designating a route different from the route transmitted for -n.

FIG. 4 is a flowchart of the multicast interrupt processing. When the transmission data is long, it is divided into predetermined data lengths and transmitted, and the receiving side assembles the original data, and the priority is low. During data transmission, it is necessary to interrupt and transmit data with a high priority. Therefore, the time of occurrence of the transmission data and the priority are added, the priorities are compared when the transmission is congested, and the transmission data with a high priority is transmitted by an interrupt. At that time, a part of the divided comparison transmission data of the priority order is temporarily held with the generation time and the priority order added.

In such an interrupt transmission, it is judged whether or not there is untransmitted multicast data (C
1) If it exists, the data having the highest priority and the oldest occurrence time among the existing data are searched (C2),
At present, it is determined whether or not there is data for which the delivery confirmation is being received (C3). If not, the retrieved data is transmitted by multicast (C6). If it exists, the priority of the data and the data retrieved in step (C2) are compared, and it is judged whether the priority of the latter is higher than that of the former (C4). In the case, the process proceeds to step (C1), and in the case of being high, the process is stopped, treated as untransmitted multicast data (C5), and transmitted by multicast (C6).

Therefore, when transmission data with a high priority such as emergency alert information occurs, even during transmission processing of other transmission data with a low priority, the transmission data with a high priority is interrupted by the interrupt processing. The transmission processing of the transmission data having the lower priority can be restarted. Further, since the occurrence time information is added, the data transmitted first and the data transmitted after the interrupt processing can be assembled based on the occurrence time information.

FIG. 5 is a flowchart of the unicast interrupt processing. As with the interrupt in the above-mentioned multicast, when data of low priority is transmitted by unicast, data of high priority is processed by the interrupt processing. May be sent. Therefore, it is determined whether or not there is untransmitted retransmission data (D1). If it exists, the data having the highest priority and the oldest occurrence time among the existing data are searched (D2), and it is determined whether or not there is retransmission data that is currently undergoing transmission processing (D3). If it does not exist, the retrieved data is transmitted by unicast (D6). If it exists, the priority of the data and the data retrieved in step (D2) are compared, and it is judged whether the latter has a higher priority than the former (D4). In the case, the process proceeds to step (D1), and in the case of being high, the process is stopped, treated as untransmitted retransmitted data, and the intermediate results are aggregated, and in the next process, the retransmitting process is performed only to the untransmitted receiving side. (D5). Then, the retrieved untransmitted data is transmitted by unicast (D6).

FIG. 6 is an explanatory diagram of the registration process. The transmitting device side, that is, the master station 1 and the receiving device side, that is, the slave stations 2-1 to 2-1.
2-n, the transmitting device side has a database (DB) 14 as shown in FIG. 1 and manages it as a receiving device list. The receiving device includes a computer name and an IP address. Then, the transmitting device side waits for reception at the SAP reception multicast address, and the receiving device side transmits the computer name and the IP address by participating in the SAP address at the time of new installation. Also, when the IP address is changed, the computer name and IP address are transmitted. Also, the computer name and the IP address are transmitted at predetermined time intervals. Also, at the time of removal, the computer name and IP address are transmitted.

On the transmitter side, the database 14 is searched by the computer name of the received data. At the time of new installation, since it is not registered in the database 14,
Register as a new device and notify the multicast router 4. When the IP address is changed, the computer names registered in the database 14 are the same, but the IP addresses are different, so the registered IP address in the database 14 is changed.

Further, the master station receives the delivery confirmation of the slave station for the periodical multicast, and determines whether the computer name and IP address of the received data match the registered computer name and IP address of the database 14. Then
If both match, it is determined to be regular reception. In this case, if reception is not possible within a predetermined time interval, it is determined that an abnormality has occurred or is removed, and the computer name is deleted from the database 14. When the slave station is removed, the computer name of the received data is deleted from the database 14. Therefore, the master station 1 can always manage the states of the slave stations 2-1 to 2-n, and can transmit data by multicast and unicast.

[0024]

As described above, according to the present invention, the master station 1
Since the information is transmitted to the plurality of slave stations 2-1 to 2-n by multicast, the transmission process of the master station 1 can be simplified and the processing time can be shortened. Then, by receiving the delivery confirmation from each of the slave stations 2-1 to 2-n, it is possible to surely confirm whether or not the important station has received the important information. Then, since the retransmitting process is performed by unicast to the slave stations that did not send the delivery confirmation, it is possible to reliably send the information to the slave stations that could not receive the multicast information for some reason. it can. In this case, if there are many undelivered slave stations, the retransmission processing by unicast will take a long time.Therefore, compare the number of undelivered slave stations with the threshold value. The time required can be shortened.

Further, even if information having a low priority is being transmitted, if information having a high priority occurs, it is possible to transmit information having a high priority by an interrupt process. After the information has been transmitted, the information that has been waiting due to the interruption is transmitted, and therefore, it is possible to quickly transmit the information that requires urgency to each slave station. Further, by managing the addition, removal, and normality of the slave stations 2-1 to 2-n by the database 14 of the master station 1, the master station 1 can reliably handle the presence of a slave station that is temporarily installed. Therefore, necessary information can be surely transmitted.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of an embodiment of the present invention.

FIG. 2 is a transmission control flowchart according to the embodiment of this invention.

FIG. 3 is a processing flowchart of a slave station according to the embodiment of this invention.

FIG. 4 is a flowchart of a multicast interrupt process.

FIG. 5 is a unicast interrupt processing flowchart.

FIG. 6 is an explanatory diagram of registration processing.

[Explanation of symbols]

1 parent station 2-1 to 2-n Slave station 3 network 4 Multicast router 11 Control unit 12 Transmission processing unit 13 Reception processing unit 14 Database 21 Information Processing Department 22 Transmitter / receiver

Claims (7)

[Claims] 1. An information transmission system for transmitting the same information from a master station to a plurality of slave stations, wherein the master station sends the same information to the plurality of slave stations by multicasting, and the slave station transmits the same information. A control unit that performs a process of retransmitting the information by unicast to a slave station that cannot receive the delivery confirmation, the slave station receives the information from the master station, and sends a delivery confirmation to the master station. An information transmission system comprising an information processing unit for performing processing and a transmission / reception unit. 2. The master station is provided with a database for managing the states of a plurality of slave stations by receiving a request for addition or deletion from the slave station or periodic information. 1. The information transmission system described in 1. 3. A transmission control method for transmitting the same information from a master station to a plurality of slave stations, the step of transmitting the same information from the master station to the plurality of slave stations by multicasting, and the slave station. Is the process of sending a delivery confirmation to the parent station when receiving information from the parent station, and the number of child stations that cannot receive the delivery confirmation from the child station even after the delivery confirmation time at the parent station elapses. And the threshold value,
When the number of slave stations that cannot receive the delivery confirmation is greater than the threshold value, the information is retransmitted by multicast, and when it is less than the threshold value, the information is sequentially retransmitted to the slave stations by unicast. And a transmission control method. 4. The delivery confirmation time at which the master station receives and monitors the delivery confirmation from the slave station is changed according to the transmission data length, and when the transmission data length is equal to or shorter than a predetermined length,
4. The transmission control information method according to claim 3, further comprising the step of setting a predetermined minimum delivery confirmation time. 5. The transmission according to claim 3, further comprising the step of assigning a priority to the transmission data to be transmitted from the master station to the slave station and transmitting the transmission data having a high priority by an interrupt. Control method. 6. A step of adding transmission time information to transmission data to be transmitted from the master station to the slave station, comparing the transmission time information, and prioritizing transmission processing of transmission data having a previous generation time. The transmission control method according to claim 3 or 5, characterized in that. 7. The master station includes a process of managing, by a database, the slave stations based on computer names of the plurality of slave stations and addresses for unicast, removal, and normality of the slave stations. The transmission control method according to any one of claims 3 to 6.