JP4364067B2 - Seismometer management system - Google Patents

Description

  The present invention relates to a seismometer management system.

Conventionally, multiple seismometers are installed at different points, management terminals are connected to each seismometer, and earthquake information data obtained by each seismometer is used to analyze earthquakes by seismographers, Settings of each seismic measuring device are performed by a system administrator or the like (see, for example, Patent Document 1).
The seismometer includes a plurality of communication units for communication connection with a management terminal, and each communication unit may perform communication using a different protocol depending on the type of data.
Here, a plurality of communication units are provided. When a plurality of data are communicated by one communication unit, other data cannot be transmitted / received while a certain data is transmitted / received, so an emergency such as an earthquake wave is required. This is because there is a problem that even if data is detected, it cannot be transmitted to the management terminal immediately.
JP 2002-367057 A

  However, if a communication unit is provided for each data to be communicated, the seismometer and the management terminal become complicated, the communication management becomes complicated, and the communication line to the management terminal is crowded with multiple data, so the communication speed decreases. There was a problem of inviting.

Therefore, the present invention has been made to solve the above-described problem, and includes a seismometer capable of switching and communicating with a plurality of protocols with one communication unit, and a plurality of transmission destinations with one communication unit. An object is to provide a seismometer management system capable of switching and communicating.

In order to solve the above-mentioned problem, the invention described in claim 1 is a seismometer management system , wherein a vibration detection unit for detecting earthquake vibration and vibration data detected by the vibration detection unit are stored in a storage unit in advance. A seismometer having a data processing unit for processing based on the set program and a communication unit connected to the data processing unit and capable of supporting a plurality of protocols ;
A seismometer management system comprising a plurality of management terminals communicably connected to the seismometer, wherein the communication unit is configured to be compatible with any protocol of TCP / IP and UDP / IP, and The meter comprises a protocol switching means for switching to a desired protocol among a plurality of protocols when performing communication connection with an external terminal via the communication unit ,
The protocol switching means switches the protocol from TCP / IP to UDP / IP when the vibration detection unit detects vibration data of a predetermined value or more .
Here, the vibration data greater than or equal to a predetermined value refers to the magnitude of vibration data set in advance by the administrator. For example, the vibration data value (acceleration value) that results in an earthquake having a seismic intensity of 3 or more is converted. .

According to a second aspect of the present invention, in the seismometer management system according to the first aspect, when a communication connection is established with the management terminal via the communication unit, a desired management terminal is selected from the plurality of management terminals. Connection switching means for switching the connection is provided.

The invention according to claim 3, in seismograph management system according to claim 2, wherein the storage unit includes a reception data table stored in association with data to be received for each management terminal, the connection switching The means switches to a management terminal corresponding to data to be transmitted by the communication unit based on the received data table.

According to the first aspect of the present invention, when the vibration detection unit detects earthquake vibration, the data processing unit processes the vibration data detected by the vibration detection unit based on a setting program stored in the storage unit in advance. . The vibration data processed by the data processing unit is transmitted to the external terminal via the communication unit. Here, at the time of communication connection between the communication unit and the external terminal, the protocol switching unit switches to a desired protocol among a plurality of protocols.
As a result, even when a plurality of protocols are required for data communication, the protocol switching means can appropriately switch to a protocol necessary for communication, so that a single communication unit can switch between a plurality of protocols for communication. This eliminates the need to provide a communication unit for each protocol. Therefore, the seismometer can be downsized and the communication speed can be improved.

In addition, when the vibration detection unit detects vibration data exceeding a predetermined value, such as when a large earthquake occurs, the protocol switching unit switches the protocol from TCP / IP to UDP / IP according to the vibration data . Vibration data can be sent immediately.

According to the second aspect of the present invention, the connection switching unit switches the connection to a desired management terminal among the plurality of management terminals when performing communication connection with the management terminal via the communication unit.
Thereby, even if it is necessary to perform data communication with a plurality of management terminals, it is possible to perform communication by switching a plurality of transmission destinations with one communication unit, and there is no need to provide a communication unit for each management terminal. Therefore, the seismometer can be downsized.

According to the invention described in claim 3 , the connection switching means is a management terminal corresponding to the data to be transmitted, based on the reception data table that stores the data to be received by each management terminal in association with each management terminal. Switch to.
Thus, the communication unit automatically selects the transmission destination and transmits the data simply by storing the reception data table in the storage unit, so that the transmission work can be automated.

Hereinafter, the best mode of a seismometer management system according to the present invention will be described in detail with reference to the drawings.
<Configuration of seismometer management system >
As shown in FIG. 1, the seismometer management system 100 includes a plurality (or one) of seismometers 1 installed at different points and vibration data detected by the seismometer 1 via a communication line T. And a plurality (or one) of management terminals 2 to receive.
The seismometer 1 includes a vibration detector 11 as a vibration detection unit that detects earthquake vibration, an A / D converter 12 connected to the vibration detector 11, and a data processing unit connected to the A / D converter 12. And a communication device 14 as a communication unit connected to the data processing device 13. Here, vibration data based on the acceleration detected by the vibration detector 11 due to vibration such as an earthquake is transmitted to the A / D converter 12 as an analog acceleration signal, and converted into a digital acceleration signal by the A / D converter 12. After the conversion, the data is transmitted to the data processing device 13.
The data processor 13 is connected to the CPU 131 that performs processing such as waveform recording of vibration data, seismic intensity calculation, and the like. The ROM 132 as a storage unit storing programs and data, and the programs and data stored in the ROM 132 are stored in the data processor 13. And a RAM 133 that is expanded and serves as a work area for the CPU 131.

Specifically, when the ROM 132 performs communication connection with the management terminal 2 via the communication device 14, the protocol switching program 132 a for switching to a desired protocol among a plurality of protocols, and the management terminal 2 via the communication device 14 The connection switching program 132b for switching the connection to a desired management terminal among a plurality of management terminals when performing communication connection, and received data that stores data to be received by each management terminal 2 in association with each management terminal 2 And a table 132c.
Here, specifically, the protocol switching program 132a is configured to switch to a protocol corresponding to the vibration data processed by the data processing device 13 when the vibration detector 11 detects vibration data of a predetermined value or more. Has been. The connection switching program 132b is configured to switch to the management terminal 2 corresponding to the data to be transmitted based on the reception data table 132c.

The communication device 14 is connected to the communication line T via the router 15, and vibration data is configured to be transmitted to the management terminal 2 via the communication line T. Here, the communication line T may be wired or wireless, and is constituted by, for example, a telephone line or a communication cable. The communication line T may be a general line or a dedicated line.
The communication device 14 is configured to be compatible with a plurality of protocols. For example, as shown in FIG. 1, the communication protocol between the data processing device 13 and the communication device 14 is TCP / IP or UDP / IP. Communication can be performed by either. Further, the communication device 14 and the router 15 can communicate with each other by either TCP / IP or UDP / IP. The router 15 and the communication line T can communicate with each other by either TCP / IP or UDP / IP.

The management terminal 2 is, for example, a system administrator's server, and includes a communication device 21 connected to the communication line T and a data processing device 22 connected to the communication device 21.
The communication device 21 is connected to the communication line T via the router 23 and is configured to receive vibration data from the seismometer 1 via the communication line T.
In the communication device 21, for example, as shown in FIG. 1, the communication protocol between the management terminal 2 and the router 23 can be communicated by TCP / IP. Further, the router 23 and the communication line T can communicate with each other by TCP / IP.
Here, when another seismometer 1a is connected to the communication line T in addition to the management terminal 2, for example, as shown in FIG. 1, the communication protocol between the other seismometer 1a and the router 23 is UDP / It can communicate by IP. The router 24 and the communication line T can communicate with each other by UDP / IP.
Note that TCP / IP is mainly used when communicating maintenance data of the seismometer 1, and UDP / IP is mainly used when communicating vibration data detected by the seismometer 1. The reason why the vibration data is communicated by UDP / IP is that vibration data due to an earthquake or the like needs to be immediately transmitted to the management terminal 2.

The data processing device 22 is connected to the CPU 221 that performs various processes, a ROM 222 that stores programs and data, a RAM 223 that develops programs and data stored in the ROM 222, and serves as a work area for the CPU 221, and It has.
The management terminal 2 includes a GPS antenna (not shown) and a GPS receiver (not shown), and the GPS receiver is connected to the CPU 221. The GPS receiver creates time data based on the time information received from the satellite by the GPS antenna, and transmits the time data to the CPU 221. Then, the CPU 221 associates the time data received from the GPS receiver with the vibration data received from the seismometer 1 by the communication device 21, creates time series data regarding the earthquake, and stores it in the ROM 222.
The ROM 222 stores an identification ID for identifying the transmission source of the received data. That is, the CPU 221 compares the identification ID stored in the ROM 222 at the time of data reception with the identification ID of the transmission source of the received data, and returns to the transmission source only when there is an identification ID that matches the ROM 222.

<Communication processing>
Next, data communication processing in the seismometer management system 100 will be described.
Here, communication processing when the seismometer 1 transmits data to the other seismometers 1a and the management terminal 2 will be described.
The seismometer 1 normally transmits maintenance data to the management terminal 2. The communication protocol of the communication device 14 at this time is TCP / IP. When an earthquake occurs and the vibration detector 11 detects vibration data of a predetermined value or more, the seismometer 1 needs to transmit vibration data to the management terminal 2. At this time, the CPU 131 switches the protocol of the communication device 14 from TCP / IP to UDP / IP by executing the protocol switching program 132a. Further, the CPU 131 reads the reception database 132c stored in the ROM 132 by executing the connection switching program 132b, selects the management terminal 2 that transmits the vibration data according to the vibration data to be transmitted, and switches the communication connection. .

As shown in FIG. 2, the vibration data is a UDP / IP broadcast transmission, and the other seismometer 1 a on the receiving side determines whether or not it matches the response destination information stored in the ROM 132. If the identification ID “xxxx” of the transmission source of the received vibration data matches the stored response destination information, the BCC is calculated, and if normal, the identification ID “yyyy” of the other seismometer 1a is added. The ACK is transmitted by designating the identification ID “xxxx” of the seismometer 1 that is the transmission source. The management terminal 2 on the receiving side determines whether the response destination information stored in the ROM 222 matches. Then, if the identification ID “xxxx” of the transmission source of the received vibration data matches the stored response destination information, the BCC is calculated, and if normal, the ACK with the identification ID “zzz” of the management terminal 2 appended Is transmitted by designating the identification ID “xxxx” of the seismometer 1 that is the transmission source.
Here, BCC (block checking code) is for detecting a communication error. If the received BCC and the BCC calculated on the receiving side are different, a communication error has occurred, and retransmission is performed. Procedures are carried out to supplement the data. ASK (acknowledge) means an affirmative response, and is sent from the receiving side as an affirmative response to the transmitting side.

As shown in FIG. 3, the seismometer 1 transmits data again when a NAK is returned from the management terminal 2 or no response is received within a certain time T1 after data transmission. After this retransmission, if there is no response in T2, it is excluded from the data transmission destination. However, if an ACK response is returned during data transmission, the excluded transmission destination is re-registered.
Here, NAK (negative acknowledge) means a negative response and is sent from the receiving side as a negative response to the transmitting side.

Then, since the seismometer 1 transmits the maintenance data again after the vibration data is transmitted, the CPU 131 executes the protocol switching program 132a to switch the protocol of the communication device 14 from UDP / IP to TCP / IP. In addition, the CPU 131 reads the reception database 132c stored in the ROM 132 by executing the connection switching program 132b, selects the management terminal 2 that transmits maintenance data according to the maintenance data to be transmitted, and switches the communication connection. .
Thereby, after the vibration data is transmitted, the maintenance data can be transmitted to the management terminal 2.

As described above, according to the seismometer management system 100 according to the present invention, the vibration detector 11 detects a seismic vibration, the data processing unit 13 in advance ROM132 to store vibration data detected by the vibration detector 11 Processing is performed based on the set program. The vibration data processed by the data processing device 13 is transmitted to the management terminal 2 via the communication device 14. Here, when communication connection between the communication device 14 and the management terminal 2 is performed, the CPU 131 executes the protocol switching program 132a, so that the CPU 131 switches to a desired protocol among a plurality of protocols used by the communication device 14 for communication. .
As a result, even when a plurality of protocols are required for data communication, the CPU 131 executes the protocol switching program 132a, so that the communication device 14 can appropriately switch to a protocol necessary for communication. Thus, a single communication device 14 can switch and communicate with a plurality of protocols, and there is no need to provide a communication device 14 for each protocol. Therefore, the seismometer 1 can be downsized and the communication speed can be improved.

Further, when the vibration detector 11 detects vibration data exceeding a predetermined value as in the case of a large earthquake, the CPU 131 executes the protocol switching program 132a, so that the protocol is changed from TCP / IP to UDP / Since switching to IP, vibration data can be transmitted immediately.

In addition, when the CPU 131 executes the connection switching program 132b to perform communication connection with the management terminal 2 via the communication device 14, the connection is switched to the desired management terminal 2 among the plurality of management terminals 2.
Thereby, even if it is necessary to perform data communication with a plurality of management terminals 2, it is possible to communicate by switching a plurality of transmission destinations with one communication device 14, and it is necessary to provide a communication device 14 for each management terminal 2. Disappear. Therefore, the seismometer 1 can be downsized.

Further, when the CPU 131 executes the connection switching program 132b, the management according to the data to be transmitted is based on the reception data table 132c that stores the data to be received by each management terminal 2 in association with each management terminal 2. Switch to terminal 2.
Thus, simply by storing the reception data table 132c in the ROM 132, the communication device 14 automatically selects the transmission destination and transmits the data, so that the transmission operation can be automated.

  The present invention is not limited to the above embodiment. For example, the management terminal does not need to be a system administrator's server, and may be a client or another seismometer. In addition, the present invention can be freely modified and improved without departing from the essence of the invention.

It is a schematic block diagram of a seismometer management system according to the present invention. It is a timing chart which shows the communication process of data. It is a timing chart which shows the communication process of data.

Explanation of symbols

11 Vibration detector (vibration detector)
13 Data processing device (data processing unit)
131 CPU (protocol switching means, connection switching means)
132 ROM (storage unit)
132a Protocol switching program (protocol switching means)
132b Connection switching program (connection switching means)
132c Reception data table 14 Communication device (communication unit)
2 management terminal

Claims (3)

A vibration detector for detecting seismic vibrations;
A data processing unit for processing vibration data detected by the vibration detection unit based on a setting program stored in the storage unit in advance;
A communication unit connected to the data processing unit and capable of supporting a plurality of protocols, a seismometer,
A seismometer management system comprising a plurality of management terminals communicably connected to the seismometer,
The communication unit is configured to be compatible with any protocol of TCP / IP and UDP / IP,
The seismometer comprises a protocol switching means for switching to a desired protocol among a plurality of protocols when performing communication connection with an external terminal via the communication unit ,
The seismometer management system , wherein the protocol switching means switches the protocol from TCP / IP to UDP / IP when the vibration detection unit detects vibration data of a predetermined value or more . The seismometer management according to claim 1, further comprising connection switching means for switching connection to a desired management terminal among a plurality of management terminals when performing communication connection with the management terminal via the communication unit. system. The storage unit has a reception data table for storing data to be received for each management terminal in association with each other,
The connection switching means
The seismometer management system according to claim 2 , wherein communication connection is switched to a management terminal corresponding to data to be transmitted by the communication unit based on the received data table.

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