JP7097586B2 - Earthquake early warning system - Google Patents

Description

The present invention relates to an earthquake early warning system.

In recent years, studies have been actively conducted to detect the P wave (preliminary tremors) generated when an earthquake occurs and predict the behavior of the S wave (primary tremors) (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2016-180723

In the method for determining the main motion of an earthquake disclosed in Patent Document 1, the seismograph is installed at the determination target point. Therefore, the system is not configured on the assumption that P waves are detected by a plurality of seismographs.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide an earthquake bulletin system capable of outputting earthquake bulletin information quickly and with high accuracy.

The present invention solves the above-mentioned problems, and the earthquake early warning system according to the embodiment of the present invention is
With multiple seismographs,
It is provided with one or a plurality of seismic monitoring devices connected to the plurality of seismographs and output seismic bulletin information based on seismic wave observation data by the plurality of seismographs.

According to the seismic bulletin system according to the embodiment of the present invention, the seismic monitoring device outputs seismic bulletin information based on seismic wave observation data by a plurality of seismographs. Therefore, the seismic bulletin information can be output quickly and with high accuracy.

It is an overall block diagram which shows an example of the earthquake early warning system 1 which concerns on 1st Embodiment. It is a block diagram which shows an example of the earthquake early warning system 1 which concerns on 1st Embodiment. It is a flowchart which shows an example of the operation which the seismic monitoring apparatus 3 executes the generation processing of the seismic bulletin information according to the number of P wave detection seismographs. It is a flowchart (continuation of FIG. 3) which shows an example of the operation which the seismic monitoring apparatus 3 executes the generation processing of the seismic bulletin information according to the number of P wave detection seismographs. It is a flowchart which shows an example of the operation when the seismic monitoring apparatus 3 receives the external preliminary report information from the external organization 4 after specifying the P wave detection seismograph. It is a flowchart which shows an example of the operation when the P wave detection seismograph is specified after the seismic monitoring apparatus 3 has received the external preliminary information from the external engine 4. It is an overall block diagram which shows an example of the earthquake early warning system 1 which concerns on 2nd Embodiment. It is a schematic layout drawing which shows an example of the earthquake early warning system 1 which concerns on 2nd Embodiment.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

(First Embodiment)
FIG. 1 is an overall configuration diagram showing an example of the earthquake early warning system 1 according to the first embodiment.

The seismic bulletin system 1 includes a plurality of seismographs 2 and an earthquake monitoring device 3 that is connected to the plurality of seismographs 2 and outputs seismic bulletin information based on seismic wave observation data by the plurality of seismographs 2.

Further, the earthquake early warning system 1 is connected to an external seismic observation engine 4 (hereinafter referred to as “external engine 4”) and an earthquake early warning distribution device 5 via a network 6. The network 6 communicates various data and signals by wire communication or wireless communication, and any communication standard is used.

The external organization 4 is, for example, a comprehensive monitoring system for seismic activity of the Japan Meteorological Agency, a high-sensitivity seismic observation network (Hi-net) of the National Research Institute for Earth Science and Disaster Prevention, and the like. The external organization 4 outputs external preliminary information based on the seismic observation records at the seismic observation points located all over the country. The spacing between seismic stations at the Japan Meteorological Agency is about 40 km, and the spacing between earthquake stations at the National Research Institute for Earth Science and Disaster Prevention is about 25 km.

The earthquake bulletin distribution device 5 receives the earthquake bulletin information from the earthquake monitoring device 3, receives the external bulletin information from the external organization 4, and distributes the earthquake bulletin information and the external bulletin information to a predetermined distribution destination.

Earthquake bulletin information includes, for example, the time of occurrence of an earthquake, the location of the epicenter indicating the location of the epicenter (latitude, longitude, depth), the magnitude of the earthquake (eg, magnitude, etc.), each point around the location of the epicenter, or each. Includes the intensity and arrival time of the S wave (main motion) predicted in the area. The intensity of the S wave may be converted into, for example, the maximum acceleration or the maximum seismic intensity. Further, the external breaking news information includes information similar to the seismic breaking news information, and includes at least the epicenter position.

The plurality of seismographs 2 are distributed and arranged so as to have a predetermined arrangement interval. It is preferable that the arrangement density of the plurality of seismographs 2 is higher than the arrangement density of the seismic observation points in the external engine 4. It is not essential that the arrangement interval of the plurality of seismographs 2 is uniform, but for example, it is preferably about 5 to 15 km, and more preferably about 10 km.

The plurality of seismographs 2 are installed in, for example, a plurality of base stations 70 constituting the communication network 7. The base station 70 includes a steel tower type installed on the ground, a rooftop installation type installed on the roof of a building or condominium, a utility pole installation type attached to a utility pole, a mobile type or a portable type that can be installed on a vehicle, etc. Any of them may be used. The communication network 7 may be either a wireless communication network or a wired communication network, or may be a combination thereof.

The plurality of seismographs 2 can be installed in any structure or any moving body other than the base station 70. Even if the seismograph 2 is installed in, for example, a base station or facility constituting the communication network 7, a building related to a business operator providing the communication network 7, or a building related to a user using the communication network 7. good. Examples of the facility constituting the communication network 7 include a network center building in which communication devices such as exchanges, routers, and servers are installed, a relay station building in which a repeater is installed, and the like. Examples of the building related to the business operator that provides the communication network 7 include a data center building, a building owned or occupied by the business operator, and the like. Examples of the building related to the user who uses the communication network 7 include the user's house and the like. In addition, the arbitrary structure is not essential to have a relationship with a business operator or a user, and may be, for example, a building or facility used for various purposes such as residential use, commercial use, public use, industrial use, or an earthquake. It may be a dedicated structure for installing a total of 2. The arbitrary mobile body may be any mobile body that can communicate with the communication network 7, and may be, for example, the wireless communication device 8 described later.

The seismograph 2 is composed of, for example, an acceleration sensor as a detection means capable of detecting a seismic wave caused by an earthquake. The seismograph 2 measures the acceleration detection value by the acceleration sensor in a predetermined sampling cycle (for example, 10 msec), and sequentially outputs the acceleration detection value as seismic wave observation data to the seismic monitoring device 3. The seismograph 2 preferably measures at least vertical acceleration, but may further measure horizontal acceleration. Further, the seismograph 2 may be a combination of a plurality of types of sensors (for example, an acceleration sensor and an angular velocity sensor).

The seismic monitoring device 3 acquires time-series data of seismic waves observed by the seismograph 2 at a predetermined sampling period as seismic wave observation data, and executes seismic bulletin information generation processing by analyzing the time-series data. .. Further, the earthquake monitoring device 3 is configured to be able to receive external preliminary information from the external organization 4. The specific configuration and operation of the earthquake monitoring device 3 will be described later.

FIG. 2 is a block diagram showing an example of the earthquake early warning system 1 according to the first embodiment.

The communication network 7 is composed of, for example, a repeater 71, an exchange facility 72, and the like, in addition to the base station 70 in which the seismograph 2 is installed. In FIG. 2, for the sake of simplification of the drawings, the base station 70 and the repeater 71 are shown one by one, but a plurality of base stations 70 are connected to one repeater 71, and one exchange facility 72 is connected to one. A plurality of repeaters 71 are connected.

The base station 70 includes an antenna radio 700 that transmits and receives various data to and from the wireless communication device 8, and a communication control unit 701 that transmits and receives various data to and from the repeater 71. The communication control unit 701 receives seismic wave observation data from the seismograph 2 installed in the base station 70 and transmits it to the repeater 71.

The repeater 71 includes a communication control unit 710 that transmits and receives various data to and from the base station 70. Of the data received from the base station 70, the communication control unit 710 sends the data whose transmission source is the wireless communication device 8 to the exchange facility 72, and seismic monitoring the data (seismic wave observation data) whose transmission source is the seismograph 2. Send to device 3. Although the seismic wave observation data is shown in FIG. 2 as being sent to the seismic monitoring device 3 via the repeater 71, the seismic wave observation data may be sent from the base station 70 to the seismic monitoring device 3 or exchange equipment. It may be sent to the seismic monitoring device 3 via 72.

The wireless communication device 8 is composed of any electronic device. The wireless communication device 8 may be, for example, a mobile phone, a smartphone, a notebook PC, or the like, or may be a control device such as a vehicle or a robot.

The earthquake monitoring device 3 is composed of, for example, a general-purpose or dedicated computer. As a specific hardware configuration, the earthquake monitoring device 3 has a storage unit 30 composed of HDD, SDD, memory, etc., and a control unit composed of processors such as CPU, MPU, GPU, etc., as shown in FIG. A communication unit 32 that functions as a communication interface between the 31 and an external device (external engine 4, seismic bulletin distribution device 5, communication network 7, etc.) is provided.

The storage unit 30 stores the seismograph management information 300 and the earthquake monitoring program 301.

In the seismograph management information 300, the installation position of the seismograph 2 and the representative seismic depth indicating the typical seismic depth at the installation position are associated with the seismometer ID that identifies a plurality of seismographs 2. Will be recorded. In the seismograph management information 300, when the seismograph 2 is newly installed, a new seismograph ID is assigned to the newly installed seismograph 2, and the installation position and the representative seismic depth of the new seismograph 2 are determined. It is registered in the seismograph management information 300.

By executing the seismic monitoring program 301 stored in the storage unit 30, the control unit 31 generates the seismic wave observation data reception processing unit 310, the filter processing unit 311, the P wave detection unit 312, the external flash information reception processing unit 313, and the generation. It functions as a processing unit 314 and an output processing unit 315.

The seismic wave observation data reception processing unit 310 sequentially receives seismic wave observation data output from each seismograph 2 at a predetermined sampling cycle. Then, the seismic wave observation data reception processing unit 310 creates time-series data of the seismic wave by adding the newly received seismic wave observation data to the seismic wave observation data received in the past predetermined period.

At that time, the seismic wave observation data received from each seismograph 2 includes, for example, a seismograph ID as information for identifying which seismograph 2 is the data observed. Therefore, the seismic wave observation data reception processing unit 310 refers to the seismograph ID, creates the above time-series data for each seismograph 2, and sends them to the filter processing unit 311 and the P wave detection unit 312 in the subsequent stage. The filter processing unit 311 and the P wave detection unit 312 process a plurality of time-series data in parallel.

The filter processing unit 311 acquires time-series data of seismic waves as seismic wave observation data, and executes filter processing for reducing predetermined environmental noise on the time-series data. In order to reduce noise in a predetermined band, the filtering process may be, for example, a bandpass filter, a highpass filter, or a lowpass filter, or may be a combination thereof as appropriate.

The filter processing unit 311 may change the presence / absence of filter processing or the filter parameters (frequency band, etc.) based on the installation environment information and the weather information at the installation position of the seismograph 2, for example. The installation environment information is arbitrary information in which the environment in which the seismograph 2 is installed affects the generation of noise (vibration), for example, information indicating the structure and height of the building in which the seismograph 2 is installed, or As the situation around the building, for example, it is information indicating the traffic volume of vehicles, the presence or absence of road construction and construction work. The meteorological information is arbitrary information in which the meteorological state of the environment in which the seismograph 2 is installed affects the generation of noise (vibration), and is, for example, information indicating the wind speed.

The P wave detection unit 312 acquires seismic wave time-series data as seismic wave observation data, detects the P wave based on the time-series data, and sends the detected result to the generation processing unit 314.

Specifically, when the P wave index value based on the seismic wave observed in the monitoring period (for example, 100 msec) longer than the sampling period (for example, 10 msec) exceeds the predetermined first threshold value, the P wave detection unit 312 may use the P wave detection unit 312. The monitoring period is determined to be the tentative candidate period for earthquakes. Next, when the earthquake tentative candidate period is continuous by a predetermined number, the P wave detection unit 312 sets the continuous series of earthquake tentative candidate periods as the earthquake candidate period. Then, when the P wave index value based on the seismic wave observed in the seismic candidate period exceeds a predetermined second threshold value, the P wave detection unit 312 determines that the P wave has been detected in the seismic candidate period. The P wave index value is calculated as, for example, the average intensity or the maximum intensity.

The external breaking news information reception processing unit 313 monitors whether or not external breaking news information has been received from the external organization 4, and if the external breaking news information is received from the external organization 4, the received external breaking news information is generated and processed. Send to 314.

When the P wave detection unit 312 detects a P wave based on the seismic wave observation data, the generation processing unit 314 sequentially uses the seismograph 2 that outputs the seismic wave observation data among the plurality of seismographs 2 as the P wave detection seismograph. Identify.

Then, when the generation processing unit 314 identifies the P wave detection seismograph, the generation processing unit 314 acquires the installation position of the P wave detection seismograph by referring to the seismograph management information 300 based on the seismograph ID. Further, the generation processing unit 314 acquires the detection intensity and the detection time of the P wave detected by the P wave detection seismometer from the time series data of the seismic wave when the P wave is detected. As a result, the generation processing unit 314 acquires P wave observation information including the installation position of the P wave detection seismometer, the detection intensity and the detection time of the P wave detected by the P wave detection seismometer, and the P wave. By executing the seismic bulletin information generation process based on the observation information, seismic bulletin information including the intensity and arrival time of the S wave is generated.

At that time, the generation processing unit 314 executes the generation processing of the earthquake early warning information according to the number of the specified P wave detection seismographs. Further, the generation processing unit 314 executes the generation processing every time the number of P wave detection seismometers increases, and the number of P wave detection seismometers exceeds a predetermined number (“6” in this embodiment). In this case, the generation process is executed based on the seismic wave observation data by a part of the P wave detection seismograph. Details of the generation process in these cases will be described later (see FIGS. 3 and 4).

Further, when the external bulletin information reception processing unit 313 receives the external bulletin information from the external engine 4, the generation processing unit 314 has a context of the timing of receiving the external bulletin information and the timing of specifying the P wave detection seismograph. By executing the generation process according to the above, seismic bulletin information including the intensity and arrival time of the S wave is generated.

Specifically, when the generation processing unit 314 receives the external preliminary report information from the external engine 4 after specifying the P wave detection seismograph, the seismic wave observation data by the P wave detection seismograph at the time of the reception is obtained. , The generation process is executed based on the seismic source position included in the external preliminary report information. On the other hand, when the generation processing unit 314 newly specifies the P wave detection seismograph after receiving the external preliminary report information from the external engine 4, the seismic wave observation data by the P wave detection seismograph at the specified time point and the seismic wave observation data. The generation process is executed based on the location of the seismic source included in the external preliminary report information. Details of the generation process in these cases will be described later (see FIGS. 5 and 6).

When the generation processing unit 314 generates the seismic bulletin information, the output processing unit 315 executes an output process of outputting (transmitting) the seismic bulletin information to the seismic bulletin distribution device 5. As a result, the earthquake bulletin information is delivered to a predetermined delivery destination by the earthquake bulletin delivery device 5, and is used by each delivery destination.

Various forms can be adopted as the usage form of the earthquake bulletin information. For example, the earthquake early warning information may be distributed to the wireless communication device 8 via the communication network 7 and notified to the user by a notification screen or a notification sound. Also. Seismic bulletin information may be distributed to traffic control systems such as roads and railroads, management systems such as power plants, plants, factories, and buildings, and used for emergency stop control of various devices. Further, the seismic bulletin information may be distributed to a house, a store, or the like and used for emergency stop control of the gas utilization device.

Next, the operation of the earthquake early warning system 1 (particularly the earthquake monitoring device 3) having the above configuration will be described with reference to FIGS. 3 to 6.

3 and 4 are flowcharts showing an example of the operation of the seismic monitoring device 3 for executing the seismic bulletin information generation processing according to the number of P wave detection seismographs.

First, in step S100, the plurality of seismographs 2 output seismic wave observation data observed at a predetermined sampling period to the seismic monitoring device 3 in order to observe seismic waves (mainly P waves) due to the earthquake.

Next, in step S200, the seismic wave observation data reception processing unit 310 of the seismic monitoring device 3 sequentially receives seismic wave observation data from each seismograph 2 at a predetermined sampling cycle to create seismic wave time-series data. Then, the P wave detection unit 312 monitors the presence or absence of P wave detection by analyzing the time series data of the seismic wave after the filter processing by the filter processing unit 311.

Here, as shown in FIG. 3, explaining that an earthquake has occurred at the epicenter E1, in step S210, the P wave detection unit 312 analyzes the time-series data of the seismic waves output from the seismograph 2A. Detects P waves with. Then, the generation processing unit 314 specifies the seismograph 2A as the first P wave detection seismograph 2A. Next, in step S212, when the number of P wave detection seismographs 2A is one, the generation processing unit 314 executes a preparatory process for outputting earthquake early warning information. As a preparatory process, the generation processing unit 314 preferentially executes an analysis process for the seismometer 2 located around the first P wave detection seismometer 2A, for example.

Next, when a predetermined time has elapsed since the first P-wave detection seismograph 2A was specified, in step S220, the P-wave detection unit 312 analyzes the time-series data of the seismic waves output from the seismograph 2B. This detects the P wave. Then, the generation processing unit 314 specifies the seismograph 2B as the second P wave detection seismograph 2B. Next, in step S222, when the number of P wave detection seismographs 2A and 2B is two, the generation processing unit 314 executes a preparatory process for outputting the earthquake early warning information. As a preparatory process, the generation processing unit 314 preferentially executes an analysis process for the seismometers 2 located around the first and second P-wave detection seismometers 2A and 2B, for example.

Next, when a predetermined time has elapsed since the second P-wave detection seismograph 2B was specified, in step S230, the P-wave detection unit 312 analyzes the time-series data of the seismic waves output from the seismograph 2C. As a result, the P wave is detected, and the generation processing unit 314 identifies the seismograph 2C as the third P wave detection seismograph 2C.

Then, in step S232, when the number of P wave detection seismometers 2A to 2C is three, the generation processing unit 314 generates three P wave observation information and P wave detection seismometers 2A to 2A. The seismic bulletin information is generated based on the typical seismic depth in the area where 2C is installed, and the output processing unit 315 outputs the seismic bulletin information.

Here, the processing content of step S232 will be described. The three P-wave observation information are P-wave observation information when P-waves are observed by each of the first to third P-wave detection seismometers 2A to 2C, and specifically, P-wave detection earthquakes. It includes the installation position of the meter and the detection intensity and detection time of the P wave detected by the P wave detection seismometer. For example, the P wave observation information for the first P wave detection seismometer 2A includes the installation position of the first P wave detection seismometer 2A and the detection intensity of the P wave detected by the first P wave detection seismometer 2A. And the detection time.

As for the typical seismic depth, for example, the generation processing unit 314 obtains the representative seismic depth for the first to third P-wave detection seismographs 2A to 2C by referring to the seismograph management information 300, and the representative seismic depths thereof are obtained. Calculated as an average value. Therefore, the generation processing unit 314 calculates the epicenter position (latitude, longitude) by treating the representative seismic depth as a temporary epicenter depth even when the number of P wave detection seismometers 2A to 2C is three.

Then, the generation processing unit 314 uses the detection intensity of the P wave detected by the first to third P wave detection seismometers 2A to 2C, respectively, and the predetermined maximum acceleration calculation formula, and uses the first to third P wave detection seismometers 2A to 2C. Estimate the maximum acceleration at each installation position of the P-wave detection seismographs 2A to 2C. Next, the generation processing unit 314 performs the maximum acceleration at each installation position of the first to third P wave detection seismometers 2A to 2C, the epicentral distance (distance between the epicenter position and the installation position), and the predetermined distance attenuation. Using the formula, the magnitude is estimated as the magnitude of the earthquake that occurred at the epicenter E1, and the intensity of the S wave (main motion) at each point or region is predicted from the magnitude. Further, the generation processing unit 314 uses the epicenter position and a known travel-time table or seismic wave propagation speed (P wave propagation speed Vp = 6.1 km / s, S wave propagation speed Vs = 3.6 km / s). Then, the arrival time of the S wave (main motion) at each point or each area is predicted. As the maximum acceleration calculation formula and the distance attenuation formula, the existing evaluation formula obtained by analyzing and evaluating the seismic motion caused by the past earthquake may be used.

As described above, in step S232, the generation processing unit 314 generates seismic bulletin information including the intensity and arrival time of the S wave. As a result, the earthquake monitoring device 3 can output the earthquake flash report information at an earlier point in time.

Next, when a predetermined time has elapsed since the third P-wave detection seismograph 2C was specified, in step S240, the P-wave detection unit 312 analyzes the time-series data of the seismic waves output from the seismograph 2D. As a result, the P wave is detected, and the generation processing unit 314 specifies the seismograph 2D as the fourth P wave detection seismograph 2D.

Then, in step S242, when the number of P wave detection seismometers 2A to 2D is four, the generation processing unit 314 generates seismic bulletin information based on the four P wave observation information as the generation process. Then, the output processing unit 315 outputs the seismic bulletin information.

Here, the processing content of step S242 will be described. The four P-wave observation information is obtained by adding the P-wave observation information when the P-wave is observed by the fourth P-wave detection seismometer 2D to the three P-wave observation information in step S232. Therefore, the generation processing unit 314 calculates the epicenter position (latitude, longitude, depth) based on the four P-wave observation information as a parameter whose epicenter depth is unknown without using a typical seismic depth.

Then, the generation processing unit 314 uses the detection intensity of the P wave detected by the first to fourth P wave detection seismometers 2A to 2D, respectively, and the predetermined maximum acceleration calculation formula, and the first to fourth P wave detection seismometers 2A to 2D. Estimate the maximum acceleration at each installation position of the P-wave detection seismographs 2A to 2D. Next, the generation processing unit 314 generates at the epicenter E1 using the maximum acceleration at each installation position of the first to fourth P wave detection seismometers 2A to 2D, the epicentral distance, and a predetermined distance attenuation formula. The magnitude is estimated as the magnitude of the earthquake, and the intensity of S waves at each point or region is predicted from the magnitude. Further, the generation processing unit 314 predicts the arrival time of the S wave at each point or each area by using the epicenter position and the known travel-time table or the propagation speed of the seismic wave.

As described above, in step S242, the generation processing unit 314 generates seismic bulletin information including the intensity and arrival time of the S wave. As a result, the earthquake monitoring device 3 can output earthquake flash report information with higher accuracy than that output in step S232. In step S242, the magnitude estimation may be omitted, and in that case, the magnitude estimated in step S232 may be used.

Next, when a predetermined time has elapsed since the fourth P-wave detection seismograph 2D was specified, in step S250, the P-wave detection unit 312 analyzes the time-series data of the seismic waves output from the seismograph 2E. As a result, the P wave is detected, and the generation processing unit 314 specifies the seismograph 2E as the fifth P wave detection seismograph 2E.

Then, in step S252, when the number of P wave detection seismographs 2A to 2E is 5, the generation processing unit 314 generates seismic bulletin information based on the 5 P wave observation information as the generation process. Then, the output processing unit 315 outputs the seismic bulletin information.

Here, the processing content of step S252 will be described. The five P-wave observation information is obtained by adding the P-wave observation information when the P-wave is observed by the fifth P-wave detection seismometer 2E to the four P-wave observation information in step S242. Therefore, the generation processing unit 314 calculates the epicenter position (latitude, longitude, depth) based on the five P-wave observation information.

Then, the generation processing unit 314 uses the detection intensity of the P wave detected by the first to fifth P wave detection seismometers 2A to 2E, respectively, and the predetermined maximum acceleration calculation formula, and uses the first to fifth P wave detection seismometers 2A to 2E. Estimate the maximum acceleration at each installation position of the P-wave detection seismographs 2A to 2E. Next, the generation processing unit 314 generates at the epicenter E1 by using the maximum acceleration at each installation position of the first to fifth P wave detection seismometers 2A to 2E, the epicentral distance, and a predetermined distance attenuation formula. The magnitude is estimated as the magnitude of the earthquake, and the intensity of S waves at each point or region is predicted from the magnitude. Further, the generation processing unit 314 predicts the arrival time of the S wave at each point or each area by using the epicenter position and the known travel-time table or the propagation speed of the seismic wave.

As described above, in step S252, the generation processing unit 314 generates seismic bulletin information including the intensity and arrival time of the S wave. As a result, the earthquake monitoring device 3 can output earthquake flash report information with higher accuracy than that output in step S242. In step S252, the magnitude estimation may be omitted, and in that case, the magnitude estimated in step S232 or S242 may be used.

Next, when a predetermined time has elapsed since the fifth P-wave detection seismograph 2E was specified, in step S260, the P-wave detection unit 312 analyzes the time-series data of the seismic waves output from the seismograph 2F. As a result, the P wave is detected, and the generation processing unit 314 specifies the seismograph 2F as the sixth P wave detection seismograph 2F.

Then, in step S262, when the number of P wave detection seismometers 2A to 2F is 6, the generation processing unit 314 P in the P wave detection seismometer 2F that last detected the P wave as the generation processing. Wave observation information and 4 P-wave observation information in 4 P-wave detection seismometers 2A-2D extracted in order of proximity to the source position among other P-wave detection seismometers 2A-2E excluding the P-wave detection seismometer 2F. Based on the above, seismic bulletin information is generated, and the output processing unit 315 outputs the seismic bulletin information.

Here, the processing content of step S262 will be described. The epicenter position (latitude, longitude, depth) can be calculated if the five P-wave observation information is known. Therefore, in step S262, the latest P wave observation information when the P wave is newly observed by the 6th P wave detection seismometer 2F is preferentially used, and the P wave detection intensity is close to the seismic source position. It was decided to use the four P wave observation information when the P wave was observed by the first to fourth P wave detection seismometers 2A to 2D, which are considered to be large. Therefore, the generation processing unit 314 calculates the epicenter position (latitude, longitude, depth) based on such five P-wave observation information.

Then, the generation processing unit 314 uses the detection intensity of the P wave detected by the first to fourth and sixth P wave detection seismometers 2A to 2D and 2F, respectively, and a predetermined maximum acceleration calculation formula. The maximum acceleration at each installation position of the 1st to 4th and 6th P wave detection seismometers 2A to 2D and 2F is estimated. Next, the generation processing unit 314 uses the maximum acceleration at each installation position of the first to fourth and sixth P wave detection seismometers 2A to 2D and 2F, the epicentral distance, and a predetermined distance attenuation formula. , The magnitude is estimated as the magnitude of the earthquake that occurred at the epicenter E1, and the intensity of S waves at each point or region is predicted from the magnitude. Further, the generation processing unit 314 predicts the arrival time of the S wave at each point or each area by using the epicenter position and the known travel-time table or the propagation speed of the seismic wave.

As described above, in step S262, the generation processing unit 314 generates seismic bulletin information including the intensity and arrival time of the S wave. As a result, the seismic monitoring device 3 can output more accurate seismic early warning information by taking in the latest P wave observation information while considering the calculation efficiency. In step S262, the magnitude estimation may be omitted, and in that case, the magnitude estimated in steps S232, S242 or S252 may be used. Further, in step S262, the P wave observation information in the P wave detection seismometer 2F that last detected the P wave and the P wave detection seismometer 2F are excluded as the seismic wave observation data by a part of the P wave detection seismometer. It was used with the four P-wave observation information in the four P-wave detection seismometers 2A to 2D extracted in the order of proximity to the seismic source position from the P-wave detection seismometers 2A to 2E, but the P was selected according to the conditions different from the above. Wave observation information may be used.

Although the number of P-wave detection seismometers increases as time elapses even after step S262, the seismic monitoring device 3 has step S262 when the number of P-wave detection seismometers is 7 or more. The seismic bulletin information may be output by executing the generation process in the same manner as in the above, or the generation process may not be executed.

As described above, the seismic monitoring device 3 executes the generation processing of the earthquake early warning information according to the number of P wave detection seismographs. As described in the description of the processing contents of each step S232, S242, S252, S262, the P wave observation information that can be used for various calculations of the seismic bulletin information generation processing depending on the number of P wave detection seismographs at each time point. The numbers are different. In response to such a situation, the seismic monitoring device 3 appropriately selects various calculation methods for the generation process at each time point according to the number of P wave detection seismographs, so that the P wave observation information acquired at each time point can be selected. It is possible to output earthquake early warning information by making effective use of.

Further, the seismic monitoring device 3 sequentially outputs seismic bulletin information by executing a generation process every time the number of P wave detection seismographs increases. As shown in FIGS. 3 and 4, as the number of P-wave detection seismographs increases with the passage of time, the number of P-wave observation information that can be used for various calculations in the generation process of earthquake flash information increases, resulting in an earthquake. The accuracy of breaking information is also improved. Therefore, the earthquake monitoring device 3 can output the earthquake bulletin information quickly and with high accuracy by sequentially outputting the earthquake bulletin information with higher accuracy while realizing the output of the earthquake bulletin information at an early stage.

FIG. 5 is a flowchart showing an example of the operation when the seismic monitoring device 3 identifies the P wave detection seismograph and then receives the external preliminary report information from the external engine 4. In FIG. 5, the seismic monitoring device 3 identifies the third P-wave detection seismograph 2C in step S230 shown in FIG. 3, and subsequently outputs seismic bulletin information in step S232, and then from the external engine 4. The case where the external bulletin information is received will be described.

First, in step S300, when the external organization 4 transmits the external breaking news information, the external breaking news information receiving processing unit 313 receives the external breaking news information. Then, in step S234, the generation processing unit 314 is based on the three P-wave observation information at the time when the external preliminary information is received and the epicenter position (latitude, longitude, depth) included in the external preliminary information. , Seismic bulletin information is generated, and the output processing unit 315 outputs the seismic bulletin information.

Here, the processing content of step S234 will be described. The three P-wave observation information are the P-wave observation information when the P-wave is observed by the first and third P-wave detection seismometers 2A to 2C, as in step S232. Further, in step S232, the epicenter position (latitude, longitude) was calculated using the typical seismic depth, but in step S234, the epicenter position (latitude, longitude) included in the external preliminary report information is not used. , Depth) is used instead.

Then, the generation processing unit 314 uses the detection intensity of the P wave detected by the first to third P wave detection seismometers 2A to 2C, respectively, and the predetermined maximum acceleration calculation formula, and uses the first to third P wave detection seismometers 2A to 2C. Estimate the maximum acceleration at each installation position of the P-wave detection seismographs 2A to 2C. Next, the generation processing unit 314 determines the maximum acceleration at each installation position of the first to third P-wave detection seismometers 2A to 2C, the epicentral distance (distance between the substitute epicenter position and the installation position), and predetermined. Using the distance attenuation formula, the magnitude is estimated as the magnitude of the earthquake that occurred at the epicenter E1, and the intensity of the S wave at each point or region is predicted from the magnitude. Further, the generation processing unit 314 predicts the arrival time of the S wave at each point or region by using the substitute epicenter position and the known travel-time table or the propagation speed of the seismic wave.

As described above, in step S234, the generation processing unit 314 generates seismic bulletin information including the intensity and arrival time of the S wave. As a result, the earthquake monitoring device 3 can output more accurate earthquake breaking news information by capturing the epicenter position of the external breaking news information by the external engine 4.

Next, when a predetermined time has elapsed after receiving the external preliminary report information, in step S240, the P wave detection unit 312 detects the P wave by analyzing the time series data of the seismic wave output from the seismograph 2D. Then, the generation processing unit 314 specifies the seismograph 2D as the fourth P-wave detection seismograph 2D.

Then, in step S244, the generation processing unit 314 generates four P-wave observation information and a seismic source included in the external preliminary information as the generation processing when the number of P-wave detection seismographs increases after receiving the external preliminary information. The seismic bulletin information is generated based on the position, and the output processing unit 315 outputs the seismic bulletin information.

Here, the processing content of step S244 will be described. The four P-wave observation information are P-wave observation information when P-waves are observed by the first to fourth P-wave detection seismometers 2A to 2D, as in step S242.

Then, the generation processing unit 314 uses the P wave detection intensity detected by the first to fourth P wave detection seismometers 2A to 2D, respectively, and a predetermined maximum acceleration calculation formula, and uses the P wave detection seismometer 2A. Estimate the maximum acceleration at each installation position of ~ 2D. Next, the generation processing unit 314 uses the maximum acceleration at each installation position of the P-wave detection seismometers 2A to 2D, the epicentral distance (distance between the substitute epicenter position and the installation position), and a predetermined distance attenuation formula. Then, the magnitude is estimated as the magnitude of the earthquake that occurred at the epicenter E1, and the intensity of the S wave at each point or region is predicted from the magnitude. Further, the generation processing unit 314 predicts the arrival time of the S wave at each point or region by using the substitute epicenter position and the known travel-time table or the propagation speed of the seismic wave.

As described above, in step S244, the generation processing unit 314 generates seismic bulletin information including the intensity and arrival time of the S wave. As a result, the seismic monitoring device 3 can output the earthquake early warning information with higher accuracy than that output in step S234 by taking in the latest P wave observation information together with the external preliminary information by the external engine 4. In step S244, the magnitude estimation may be omitted, and in that case, the magnitude estimated in step S234 may be used.

Even after step S244, the number of P-wave detection seismographs increases as time elapses. In that case, the seismic monitoring device 3 observes seismic waves with the P-wave detection seismograph as in step S244. Seismic bulletin information is output by executing generation processing based on the data and the location of the seismic source included in the external bulletin information.

FIG. 6 is a flowchart showing an example of the operation when the seismic monitoring device 3 identifies the P wave detection seismograph after receiving the external preliminary report information from the external engine 4. FIG. 6 describes a case where the seismic monitoring device 3 specifies the first P wave detection seismograph 2A in step S210 shown in FIG. 3 after receiving the external preliminary report information from the external engine 4. Further, here, as shown in FIG. 6, it is assumed that an earthquake has occurred in which the epicenter E2 is located at a position distant from the plurality of seismographs 2.

First, in step S300, when the external organization 4 transmits the external bulletin information, the external bulletin information reception processing unit 313 receives the external bulletin information. After that, in step S210, the P wave detection unit 312 detects the P wave by analyzing the time series data of the seismic wave output from the seismometer 2A, and the generation processing unit 314 uses the seismometer 2A as the first. It is specified as a P-wave detection seismograph 2A.

Then, in step S214, the generation processing unit 314 generates one P-wave observation information and the epicenter included in the external preliminary information as the generation processing when the number of P-wave detection seismographs increases after receiving the external preliminary information. The seismic bulletin information is generated based on the position, and the output processing unit 315 outputs the seismic bulletin information.

Here, the processing content of step S214 will be described. One P-wave observation information is P-wave observation information when a P-wave is observed by the first P-wave detection seismometer 2A. Further, in step S212 shown in FIG. 3, the preparatory process is executed, but in step S214, the generation process is executed by substituting the epicenter position (latitude, longitude, depth) included in the external preliminary report information.

Then, the generation processing unit 314 uses the detection intensity of the P wave detected by the first P wave detection seismometer 2A and a predetermined maximum acceleration calculation formula to install the first P wave detection seismometer 2A. Estimate the maximum acceleration in. Next, the generation processing unit 314 uses the maximum acceleration at the installation position of the first P-wave detection seismometer 2A, the epicentral distance (distance between the substitute epicenter position and the installation position), and a predetermined distance attenuation formula. Then, the magnitude is estimated as the magnitude of the earthquake that occurred at the epicenter E2, and the intensity of the S wave at each point or region is predicted from the magnitude. Further, the generation processing unit 314 predicts the arrival time of the S wave at each point or region by using the substitute epicenter position and the known travel-time table or the propagation speed of the seismic wave.

As described above, in step S214, the generation processing unit 314 generates seismic bulletin information including the intensity and arrival time of the S wave. As a result, the earthquake monitoring device 3 can output more accurate earthquake breaking news information by capturing the epicenter position of the external breaking news information by the external engine 4.

Even after step S214, the number of P-wave detection seismographs increases as time elapses. In that case, the seismic monitoring device 3 observes seismic waves with the P-wave detection seismograph as in step S214. Seismic bulletin information is output by executing generation processing based on the data and the location of the seismic source included in the external bulletin information.

As described above, according to the seismic bulletin system 1 according to the present embodiment, the seismic monitoring device 3 can output the seismic bulletin information quickly and with high accuracy based on the seismic wave observation data by the plurality of seismographs 2. ..

(Second embodiment)
FIG. 7 is an overall configuration diagram showing an example of the earthquake early warning system 1 according to the second embodiment. FIG. 8 is a schematic layout diagram showing an example of the earthquake early warning system 1 according to the second embodiment.

The earthquake early warning system 1 according to the first embodiment has been described as including one seismic monitoring device 3 connected to a plurality of seismographs 2. On the other hand, the earthquake early warning system 1 according to the second embodiment includes a plurality of seismic monitoring devices 3 connected to a plurality of seismographs 2.

As shown in FIGS. 7 and 8, the seismic bulletin system 1 according to the present embodiment is provided corresponding to a plurality of seismographs 2 distributed in a plurality of observation areas 10 and each of the observation areas 10. At the same time, a plurality of seismic monitoring devices 3 connected to a plurality of seismometers 2 in the corresponding observation area 10 and output seismic bulletin information based on seismic wave observation data by the plurality of seismographs 2. It is connected to the earthquake monitoring device 3 of the above and includes a management device 9 for managing earthquake flash report information output from a plurality of earthquake monitoring devices 3. Since the basic configuration and operation of the earthquake early warning system 1 according to the second embodiment are the same as those of the first embodiment, the differences from the first embodiment will be mainly described below.

The management device 9 transmits the earthquake flash report information output (transmitted) from the plurality of earthquake monitoring devices 3 to the earthquake flash report distribution device 5 via the network 6. Further, when the management device 9 receives the external preliminary report information from the external organization 4 via the network 6, the management device 9 transmits it to the plurality of earthquake monitoring devices 3.

The observation area 10 is divided into meshes in the example of FIG. 8, but the method for dividing the observation area 10 is not limited to the above example, and any method may be adopted. For example, the observation area 10 may be divided into eight regional divisions nationwide, may be divided according to administrative areas such as prefectures and municipalities, or may be divided into arbitrary shapes regardless of the administrative area. good. Further, the observation area 10 may be dynamically changeable. Further, the number and arrangement of the seismographs 2 in the observation area 10 are not limited to the example of FIG. 8, and can be changed as appropriate.

Each of the plurality of seismic monitoring devices 3 is configured in the same manner as the seismic monitoring device 3 according to the first embodiment, and operates according to the flowchart shown in FIGS. 3 to 6. Although the plurality of seismic monitoring devices 3 are provided corresponding to each of the observation areas 10, they do not need to be physically installed in the observation area 10, and a plurality of earthquakes in the observation area 10 need to be physically installed. It suffices if seismic wave observation data by a total of 2 can be acquired.

As described above, according to the earthquake early warning system 1 according to the present embodiment, since a plurality of earthquake monitoring devices 3 are provided, the generation process of the earthquake early warning information can be distributed and executed.

(Other embodiments)
Although the embodiment of the present invention has been described above, the present invention is not limited to the above embodiment and can be appropriately modified without departing from the technical idea of the present invention.

In the above embodiment, the seismic monitoring device 3 has been described as including the filter processing unit 311 and the P wave detection unit 312. On the other hand, for example, the observation data processing device connected to the seismograph 2 (for example, installed in the base station 70) may include at least one of the filter processing unit 311 and the P wave detection unit 312. In this case, the seismic monitoring device 3 may receive the time-series data of the seismic wave after the filter processing as the seismic wave observation data by the plurality of seismographs 2, or the P wave detection indicating that the P wave has been detected. Information may be received. The seismic monitoring device 3 or the observation data processing device does not have to include the filter processing unit 311.

In the above embodiment, the earthquake monitoring program 301 has been described as being stored in the storage unit 30, but it is a file in a format that can be installed on a computer-readable recording medium such as a USB memory or a DVD or a file in an executable format. It may be recorded and provided, or it may be provided by storing it on a computer connected to a network such as the Internet and downloading it via the network. Further, the earthquake monitoring device 3 may realize the functions of each unit realized by the control unit 31 executing the earthquake monitoring program 301 by hardware such as FPGA and ASIC.

1 ... Earthquake early warning system, 2 ... Seismometer, 2A-2F ... P wave detection seismograph,
3 ... Earthquake monitoring device, 4 ... External seismic observation organization (external organization), 5 ... Earthquake early warning distribution device,
6 ... network, 7 ... communication network, 8 ... wireless communication equipment, 9 ... management device, 10 ... observation area,
30 ... storage unit, 31 ... control unit, 32 ... communication unit,
70 ... base station, 71 ... repeater, 72 ... exchange equipment,
300 ... seismograph management information, 301 ... seismic monitoring program,
310 ... Seismic wave observation data reception processing unit, 311 ... Filter processing unit, 312 ... P wave detection unit 313 ... External flash information reception processing unit, 314 ... Generation processing unit, 315 ... Output processing unit,
700 ... Antenna radio, 701 ... Communication control unit, 710 ... Communication control unit

Claims (13)

With multiple seismographs,
It is equipped with one or more seismic monitoring devices that are connected to the plurality of seismographs and output seismic bulletin information based on seismic wave observation data by the plurality of seismographs.
The earthquake monitoring device is
Based on the seismic wave observation data, the seismograph that detected the P wave among the plurality of seismographs was sequentially identified as the P wave detection seismograph.
The earthquake early warning information is output by executing the seismic early warning information generation process according to the number of the specified P wave detection seismographs.
Earthquake early warning system. The earthquake monitoring device is
Each time the number of P-wave detection seismographs increases, the generation process is executed to sequentially output the earthquake early warning information.
The earthquake early warning system according to claim 1. The earthquake monitoring device is
The generation process is executed every time the number of P-wave detection seismometers increases, and when the number of P-wave detection seismometers exceeds a predetermined number, a part of the P-wave detection seismometers. By executing the generation process based on the seismic wave observation data by, the seismic bulletin information is sequentially output.
The earthquake early warning system according to claim 1 or 2 . The earthquake monitoring device is
When the P-wave detection seismometer is specified based on the seismic wave observation data, the installation position of the P-wave detection seismometer and the detection intensity and detection time of the P-wave detected by the P-wave detection seismometer are included. By acquiring P-wave observation information and executing the generation process based on the P-wave observation information, the seismic bulletin information including the intensity and arrival time of the S wave is generated.
The earthquake early warning system according to any one of claims 1 to 3 . As the plurality of seismographs, at least three or more of the seismographs are provided.
The earthquake monitoring device is
When the number of P-wave detection seismographs is three, as the generation process,
The earthquake early warning information is generated based on the three P-wave observation information and the typical seismic depth in the area where the P-wave detection seismometer is installed.
The earthquake early warning system according to claim 4 . As the plurality of seismographs, at least five or more of the seismographs are provided.
The earthquake monitoring device is
When the number of the P wave detection seismographs is 4 or 5, the generation process is as follows.
Generate the earthquake early warning information based on the four or five P-wave observation information.
The earthquake early warning system according to claim 4 or 5 . As the plurality of seismographs, at least six or more of the seismographs are provided.
The earthquake monitoring device is
When the number of the seismographs that have detected the P wave is 6 or more, the generation process is as follows.
The P-wave observation information in the P-wave detection seismometer that last detected the P-wave, and the four P-wave detection seismometers other than the P-wave detection seismometer, extracted in order of proximity to the epicenter position. The seismic bulletin information is generated based on the four P-wave observation information in the P-wave detection seismograph.
The earthquake early warning system according to any one of claims 4 to 6 . With multiple seismographs,
It is equipped with one or more seismic monitoring devices that are connected to the plurality of seismographs and output seismic bulletin information based on seismic wave observation data by the plurality of seismographs.
The earthquake monitoring device is
In addition to being configured to be able to receive external preliminary information from external seismic observation agencies,
Based on the seismic wave observation data, the seismograph that detected the P wave among the plurality of seismographs was sequentially identified as the P wave detection seismograph.
The earthquake early warning information is output by executing the seismic early warning information generation process according to the number of the specified P wave detection seismographs.
When the external preliminary information is received from the seismic observation organization after the P-wave detection seismometer is specified based on the seismic wave observation data, the P-wave detection seismometer at the time of the reception is performed as the generation process. The seismic bulletin information is generated based on the seismic wave observation data according to the above and the seismic source position included in the external bulletin information.
Earthquake early warning system. The earthquake monitoring device is
When the P-wave detection seismograph is newly specified after receiving the external preliminary information from the seismic observation organization, the seismic wave observation data by the P-wave detection seismograph at the specified time point is used as the generation process. And, the seismic bulletin information is generated based on the seismic source position included in the external bulletin information.
The earthquake early warning system according to claim 8 . With multiple seismographs,
It is equipped with one or more seismic monitoring devices that are connected to the plurality of seismographs and output seismic bulletin information based on seismic wave observation data by the plurality of seismographs.
The seismograph or the seismic monitoring device
As the seismic wave observation data, a P wave detection unit that acquires time series data of seismic waves observed by the seismograph at a predetermined sampling period and detects P waves based on the time series data is provided.
The P wave detection unit is
When the P wave index value based on the seismic wave observed in the monitoring period longer than the sampling period exceeds a predetermined first threshold value, the monitoring period is determined to be the seismic tentative candidate period.
When the earthquake tentative candidate period is continuous by a predetermined number, the continuous series of the earthquake tentative candidate periods is set as the earthquake candidate period.
When the P wave index value based on the seismic wave observed in the earthquake candidate period exceeds a predetermined second threshold value, it is determined that the P wave is detected in the earthquake candidate period.
Earthquake early warning system. The plurality of seismographs
It is distributed in multiple observation areas and is distributed.
The plurality of seismic monitoring devices are
It is provided corresponding to each of the observation areas, and is connected to each of the plurality of seismographs in the corresponding observation area, and the seismic bulletin information is obtained based on the seismic wave observation data by the plurality of seismographs. Output each,
The earthquake early warning system according to any one of claims 1 to 10 . The plurality of seismographs
Base stations or facilities that make up a communication network,
Buildings related to businesses that provide the communication network,
Buildings related to users who use the communication network, or
Installed in each mobile body capable of communicating with the communication network,
The earthquake early warning system according to any one of claims 1 to 11 . The placement density of the multiple seismographs is
Higher than the placement density of seismic stations in external seismic stations,
The earthquake early warning system according to any one of claims 1 to 12 .

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