JP2003167063A - Earthquake observation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an earthquake observation system, capable of edit- processing and transmitting data of observation of seismographs installed in a plurality of earthquake observation facilities in a short time, and estimating earthquake information on one district even if the earthquake observation facility of the district can't conduct edit processing for the earthquake information on the district and transmit the information. <P>SOLUTION: In this earthquake observation system, the earthquake observation facilities 2A to 2H are installed in each of a plurality of divided districts, thereby observing an earthquake. The earthquake observation facilities 2A to 2H are provided with a function of storing the data of observation by the seismograph in the concerned district, and edit-processing the same. The earthquake observation facilities are connected to each other by a communication line 4, and the respective earthquake observation facilities 2A to 2H are provided with a supervise earthquake observation facility 5 for storing the stored and edit-processed data information, and supervising and edit-processing the same. <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 an earthquake observation system for editing observation data of a plurality of seismographs as earthquake information and transmitting it to a user.

[0002]

2. Description of the Related Art Conventionally, a system shown in FIG. 4 is known as a system for transmitting observation data of a plurality of seismographs to a user as seismic information. This system uses seismograph observation data installed at multiple seismic observation points 1 in Japan, and seismic observation facilities 2
Data is recorded in the data recording device, and the recorded data is sequentially taken into the database server, and the calculation device, WWW
(Distributed database system) Edit processing using a server, etc.
To send information to. Note that, as a related technique of this type, there is one described in, for example, JP-A-10-253765.

[0003]

In this system, the processing of information is concentrated in one seismic observation facility, so when an earthquake is observed over a wide area, the seismometer data increases, and It takes time to capture the data. In addition, if the number of data to be taken in is large, the editing process also takes time, and it takes time to transmit the earthquake information. Further, since the information is concentrated on the telephone line in a specific area, if the ordinary telephone line is congested or the ordinary telephone line is damaged, the data cannot be transmitted.

Furthermore, the observation data of the seismographs installed at a plurality of seismic observation points are transmitted to a plurality of seismic observation facilities (reception stations) by using ISDN (Integrated Service Digital Network) lines.
It has been reported that the data is imported to the data server of, and is edited in parallel and the information is transmitted on the Internet.
In this method, the seismograph-equipped seismograph facility performs primary data processing, and the processed data is transmitted to a plurality of seismic observation facilities, so that each seismic observation facility performs processing a plurality of times. According to this method, although the initial earthquake information can be transmitted in a short time with the first data, it takes time to transmit all the earthquake information. Further, since there is no upper facility (upper station) of the earthquake observation facility, if the earthquake observation facility in charge of the epicenter is damaged and cannot be edited, for example, the information of the epicenter is lost.

An object of the present invention is to provide an earthquake observation system which edits data observed by seismographs installed in a plurality of earthquake observation facilities in a short time and transmits earthquake information. Another object of the present invention is to provide an integrated seismic observation facility having a function capable of estimating the seismic information of the seismic observation facility in one area where transmission has become impossible. An object of the present invention is to provide an earthquake observation system that can estimate the earthquake information of the area even if it is impossible to record, edit, or transmit the earthquake information. Still another object of the present invention is to provide an earthquake observation system capable of improving the data accuracy of the boundary area between adjacent areas.

[0006]

[Means for Solving the Problems] In order to achieve the above object, the seismic observation system according to the present invention installs seismic observation facilities in each of a plurality of areas, and installs seismographs in the seismic observation facilities. In the seismic observation system for observing an earthquake, the seismic observation facility accumulates and edits the data observed by the seismographs in the area, and the seismic observation facilities are connected to each other through a communication line. The facility is equipped with an integrated seismic observation facility that accumulates and edits data information that is accumulated and edited by the facility.

If seismic observation facilities are installed in a plurality of areas and the seismographs in each area and the seismic observation facilities in charge of each area are connected by communication lines, the observation data can be recorded in parallel, and the recording time can be reduced. Can be shortened. Further, since each seismic observation facility is provided with the editing processing function, the seismic information can be edited for each region in a distributed manner, and the editing time can be shortened. Specifically, the earthquake observation facility has a function of transmitting the edited data information accumulated and stored in the earthquake observation facility to the user through the communication line, so that each earthquake observation facility can be used by users in the area in charge. Earthquake information can be sent quickly.

Further, by providing a general seismic observation facility for accumulating and editing data information accumulated and edited by each seismic observation facility, general editing can be performed in parallel with each seismic observation facility. . Furthermore, since the integrated seismic observation facility has a function of estimating the seismic information of the seismic observation facility that cannot be transmitted, one seismic observation facility cannot record, edit, and transmit information. However, it is possible to estimate the earthquake information of the area.
In addition, the data accuracy of the boundary area is improved.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a schematic system diagram of an earthquake observation system according to the present invention, FIG. 2 is a schematic block diagram, and FIG. 3 is a detailed block diagram.

The lower right part of FIG. 1 is a diagram schematically showing the whole of Japan. In the diagram, the whole of Japan is roughly divided into eight regions, that is, regions A to H, and seismographs 11 are provided in the respective regions.
The seismic observation point 1 (shown with a ● mark) is installed (see Fig. 3). For example, a servo acceleration type is installed in the seismograph 11 and detects three components in the north-south direction (x-axis), the east-west direction (y-axis), and the vertical direction (z-axis). Earthquake observation facility (observation station) 2A ~ for each area A ~ H
2H is installed, and a plurality of seismic observation points 1 in each area and the seismic observation facilities 2A to 2H are connected by a communication line 3.
The seismic observation facilities 2A to 2H are also connected by the communication line 4. A general seismic observation facility 5 is provided as a superordinate facility (superior station) of the seismic observation facilities 2A to 2H, and the general seismic observation facility 5 and the seismic observation facilities 2A to 2H are connected by a communication line 6. Each earthquake observation facility 2A-2H and user 7,
The integrated seismic observation facility 5 and the user 7 are connected via the Internet 6.

As shown in FIG. 3, the seismic observation point 1 is composed of a seismograph 11, an amplifier 12, an A / D converter 13 and a communication device 14, and the data detected by the seismograph 11 is converted into digital data. Then, the observation data is transmitted to each of the earthquake observation facilities 2A to 2H through the communication line 3. This seismic observation point 1 is installed in a wide area within each area A to H,
In this embodiment, the areas A to H are divided into eight groups.

The earthquake observation facilities 2A to 2H are communication terminals 2
1, database server 22, arithmetic unit 23, and W
It is composed of a WW server 24. The plurality of communication terminals 21 sequentially receive the observation data transmitted from the seismic observation points 1 in the regions A to H, and the observation data are stored in the database server 22. The observation data saved in the database server 22 is edited into necessary earthquake information by the arithmetic unit 23, and the edited earthquake information is saved in the database server 22. At the same time, the observation data and the earthquake information are uploaded to the WWW server 24. Using the Internet 8, the user 7 can obtain earthquake information in a short time.

By installing the seismic observation facilities 2A to 2H in the areas A to H and providing the arithmetic unit 23, the observation data can be received and edited in parallel, and the areas A to H can be processed in a short time. It becomes possible to deliver the earthquake information of H to the WWW server 24. Further, the seismic observation facilities 2A to 2H are connected by a communication line 4, and are connected to a general seismic observation facility 5 and a communication line 6.

The integrated seismic observation facility 5 is composed of a communication terminal 21, a database server 22, an arithmetic unit 23, and a WWW server 2. In the integrated seismic observation facility 5, the data edited by the seismic observation facilities 2A to 2H are sent to the communication terminal 21.
Are sequentially received and edited by the computing device 23 into comprehensive earthquake information. The comprehensively edited earthquake information is stored in the database server 22, and at the same time, the comprehensive earthquake information is uploaded to the WWW server 24. The user 7 can obtain the general earthquake information in a short time by using the Internet 8.

The general seismic observation facility 5 can improve the data accuracy of the boundary area between regions by making an estimation using the observation data of the adjacent regions. For example, a seismograph installed near the area C side of area E observes seismic intensity “5”
When the seismographs installed around the area E side of No. 1 observe the seismic intensity “3”, the seismic intensity “4” is roughly estimated by the integrated seismic observation facility 5 as long as there is no special reason. Such estimation can be performed in all boundary regions from the data observed by the seismographs installed around the regions A to H.

Further, for example, an earthquake observation facility 2E in area E
Even if the person becomes unable to record, edit, or send information for any reason, the general seismic observation facility 5
By providing a guessing function in the adjacent areas C, D,
It is possible to estimate the earthquake information of area E using information from F and the like. Guessing functions are, for example, regional data,
This function has a database of past earthquake observation data and its damage status, and can predict the occurrence status of earthquakes by using neural networks and chaos theory.

Furthermore, if the communication line 6 or the Internet 8 is connected to main facilities such as local government offices, police stations, fire stations, hospitals, and various broadcasting stations, the seismic observation facilities 2A to 2H
By sending the earthquake information to the main facility immediately after the editing process is completed, it becomes possible to promptly perform disaster countermeasures and rescue. In the embodiment of the present invention, since the areas A to H are divided, the number of earthquake observation facilities is eight,
The number of regions (earthquake observation facilities) is arbitrary. Further, the communication line 3 and the communication line 6 described as data communication means.
Is not specified, and another method may be used as long as it is a communication line capable of transmitting and receiving a large amount of digital data at high speed.

[0019]

As described above, according to the seismic observation system of the present invention, the data observed by seismographs installed in a plurality of seismic observation facilities are edited in a short time and the seismic information is transmitted. be able to. In addition, by setting up a general seismic observation facility that has the function of estimating and supplementing the seismic information of the seismic observation facility in one area that cannot be transmitted, the seismic observation facility in one area can Even if it becomes impossible to record, edit, or transmit information, it is possible to estimate the earthquake information of the area. Furthermore, the data accuracy of the boundary area between adjacent areas can be improved.

[Brief description of drawings]

FIG. 1 is a system diagram showing an outline of an earthquake observation system according to the present invention.

FIG. 2 is a schematic block diagram of the system of FIG.

3 is a detailed block diagram of the system of FIG.

FIG. 4 is a block diagram showing a conventional technique.

[Explanation of symbols]

1 ... Earthquake observation point, 2A-2H ... Earthquake observation facility, 3, 4, 6
… Communication line, 5… General earthquake observation facility, 7… User, 8…
Internet, 11 ... Seismometer, 12 ... Amplifier, 13 ...
A / D converter, 14 ... Communication device, 21 ... Communication terminal,
22 ... Database server, 23 ... Computing device, 24 ... W
WW server.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Takao Konno             603 Jinmachi-cho, Tsuchiura-shi, Ibaraki Japan Co., Ltd.             Tate Manufacturing Industrial Machinery Systems Division

Claims (5)

[Claims] 1. An earthquake observation system in which an earthquake observation facility is installed in each of a plurality of divided areas and an earthquake is provided by the seismic observation facility, and the earthquake observation facility is an earthquake in the area. The seismic observation facility has a function of accumulating and observing data, and each seismic observation facility is connected to each other through a communication line. An earthquake observation system characterized by having an integrated earthquake observation facility. 2. The seismic observation facility has a function of transmitting data information accumulated and edited by the seismic observation facility to a user via a communication line. 2. The seismic observation system according to claim 1, wherein the seismic observation system is provided with a function of transmitting the stored and edited data information to a user via a communication line. 3. The integrated seismic observation facility, when the data observed by each of the seismic observation facilities cannot be transmitted, from the observation data transmitted by the seismic observation facilities in the vicinity of the seismic observation facility that cannot be transmitted. 2. A function for estimating earthquake information of an area where transmission is disabled is provided.
Earthquake observation system described. 4. The seismic observation system according to claim 1, wherein the integrated seismic observation facility has a function of estimating data in a boundary region from observation data in the vicinity of a boundary between adjacent seismic observation facilities. . 5. An earthquake observation system in which an earthquake observation facility is installed in each of a plurality of divided areas, and an earthquake is installed in the earthquake observation facility to observe an earthquake. The data observed by the meter is accumulated and edited, and each seismic observation facility is connected to each other via a communication line. This seismic observation facility accumulates and sends the edited data information to the user via the communication line. The seismic observation facility is equipped with a function to store and edit data information accumulated and edited by the seismic observation facility. When the transmission becomes impossible, the function to estimate the earthquake information of the area where the transmission could not be performed from the observation data transmitted by the earthquake observation facility around the transmission failure facility, and the integrated earthquake An earthquake observation system characterized in that the observation facility has a function of transmitting data information accumulated and edited and processed to a user through a communication line.