JP2005257578A - Real-time earthquake information disaster prevention radio system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To meet the request of a method for improving transmission time of information in a real-time earthquake information disaster prevention radio system and the need of a high-speed real-time earthquake information disaster prevention radio system. <P>SOLUTION: A real-time earthquake information use council 2 receives earthquake information from seismic wave observation network seismometers 1 set all over the country. The council 2 converts the received earthquake information to real-time earthquake information, and transmits it to the real-time earthquake information disaster prevention radio system. The real-time earthquake information disaster prevention radio system comprises a real-time earthquake information analysis server 11, an earthquake information transmitting/receiving and arithmetic unit 12, a data receiving management device 13 and a data transmitting management device 15. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

In an environment where the seismic network is at a certain level and data is collected immediately (real-time) or near real-time, the information is communicated to the user after the earthquake occurs and before the seismic wave arrives. The present invention relates to a real-time earthquake information disaster prevention radio system that performs warning or automatic disaster prevention measures.

  For real-time earthquake information disaster prevention radio based on data from the occurrence of an earthquake, a simultaneous communication system and a disaster prevention broadcast radio system have been proposed.

Japanese Patent Application No. 2003-32182 Japanese Patent Application No. 2003-8528

However, in such a real-time earthquake information disaster prevention radio system, a method for improving the information transmission time is required, and a high-speed real-time earthquake information disaster prevention radio system is required. Such information can be used for disaster prevention officials in local governments and other public institutions to immediately grasp the dangers of residents and to minimize or minimize earthquake damage. Therefore, by transmitting real-time earthquake information (also referred to as emergency earthquake information) to disaster prevention radio systems used by local government disaster prevention workers and public / life related personnel, it promotes the smooth actions of the concerned parties. The purpose is to enhance disaster prevention activities.
In this invention, the real-time earthquake information disaster prevention radio system method which solves the problem of the transmission time of these information is presented.

The present invention meets the above-described problems by presenting a new method.
In order to achieve this object, the present invention is configured as described in the claims. That is, the present invention as described in claim 1,
A method for utilizing real-time earthquake information by earthquake observation, which has communication control / calculation functions, data transmission management functions, and reception functions, and uses a disaster prevention radio system as a means of secondary distribution of earthquake disaster prevention information A real-time earthquake information disaster prevention radio system is constructed.
Further, the present invention provides the following, as described in claim 2.
A method for utilizing real-time earthquake information by seismic observation, wherein in the disaster prevention radio system, in order to shorten the rise time until the start of broadcasting, the call signal is made to be a single transmission and the idling switching is made serial transmission. The real-time earthquake information disaster prevention radio system according to claim 1 is configured.

  The effect obtained by the method of the real-time earthquake information disaster prevention radio system according to the present invention will be described for each claim.

First, in the invention of claim 1, since the disaster prevention radio system is a private network, the line is less likely to be congested, and the information necessary for disaster prevention workers can be transmitted more reliably. .
In the invention of claim 2, it is possible to shorten the calling time and

  Examples are shown below.

FIG. 1 is a diagram showing a configuration of a real-time earthquake information disaster prevention radio system according to the present invention. As shown in FIG. 1, the earthquake information from the seismometer 1 installed in the whole country is sent to the epicenter information distribution center (actually in charge of the Japan Meteorological Agency) 3 and the real-time earthquake information utilization council 2 Receive. The real-time earthquake information utilization council 2 converts the received earthquake information into real-time earthquake information and transmits it to the real-time earthquake information disaster prevention radio system. The real-time earthquake information disaster prevention wireless system includes a real-time earthquake information analysis server 11, earthquake information transmission / reception and calculation device 12, data reception management device 13, and data transmission management device 15.

Then, the data transmission management device 15 outputs the earthquake disaster prevention sound from the outdoor loudspeaker station 17 and the individual receiver 18 as the disaster prevention radio. Moreover, the outline | summary of the function of the real-time earthquake information analysis server 11 is shown below.
(1) Communication control / calculation function Real-time earthquake information is received from the real-time earthquake information utilization council 2 and the measured seismic intensity equivalent value and main motion arrival time are calculated and displayed together with the display of the epicenter information. This immediate information is converted into data that can be received by the disaster prevention radio system and transmitted.
(2) Data transmission management function It is assumed that the data includes contents for identifying a receiving partner station and contents corresponding to seismic intensity, and the transmission conditions thereof can be set.
(3) Reception function The receiving station side shall be able to announce information equivalent to measured seismic intensity, and the display unit attached to the receiving station shall be capable of displaying measured seismic intensity equivalent information. It is assumed that announcements and display contents are registered in advance. In addition, assuming a digital system, it will also be produced taking into account the display of the main movement arrival time.

FIG. 2 is a diagram showing the configuration of the real-time earthquake information analysis server 11 shown in FIG. As shown in FIG. 2, the real-time earthquake information analysis server 11 includes a router 21, a data transmission / reception device 22, a predicted seismic intensity scale, a main motion arrival time calculation device 23, a log and history management device 24, a display output device 25, and a past The data reproduction display device 26 is used. Details of the functions of the router 21, the data transmitter / receiver 22, the predicted seismic intensity scale, the main motion arrival time calculation device 23, the log and history management device 24, the display output device 25, and the past data reproduction display device 26 will be described below. To do.
(1) Earthquake information transmission / reception and calculation device 13
(1-1) Outline The functions of this earthquake information transmission / reception and calculation device 13 are the real-time earthquake information received from the real-time earthquake information utilization council 2 and the seismic intensity information and the measured seismic intensity equivalent value and the main motion arrival time. calculate.
The function is shown below.
(A) The epicenter information and fault information are received by the receiving device via a dedicated line (for example, NTT digital).
(B) Calculate and display the measured seismic intensity equivalent value and main motion arrival time from the received source information.
(C) Send the measured seismic intensity equivalent value and the result of the main motion arrival time to the radio etc. via the disaster prevention radio.
(1-2) Configuration The functional specifications of each device are as follows.
(A) Router 21
The router must have a function of converting transmission via the NTT digital leased line to a LAN (Ethernet (registered trademark)) in data transmission / reception between the real-time earthquake information utilization council 2 and earthquake information transmission / reception and the arithmetic unit 13.
(B) Data transmitter / receiver 22, predicted seismic intensity scale, and main motion arrival time calculator 23
The data transmission / reception device 22 and the predicted seismic intensity scale and the main motion arrival time calculation device 23 take into consideration the processing speed and measures for avoiding operation stoppage at the time of failure. It has a function to calculate the value and main movement arrival time.
Details are as follows.
a. The data transmission / reception device 22 receives earthquake information from the function real-time earthquake information utilization conference 2.
The fact that it has been received normally is transmitted (returned) to the real-time earthquake information utilization conference 2
The earthquake information from the real-time earthquake information utilization council 2 is displayed.
b. In the seismic information received by the function of the predicted seismic intensity scale and the main motion arrival time calculating device 23, the following values are calculated from the epicenter information.
Major motion arrival time measured seismic intensity equivalent value c. It is possible to manage the history by outputting the function calculation history and system management history of the log and history management device 24 to a log file.
Have a history search function. It has a function to display a list on the screen based on the specified search conditions. The year, month, day, magnitude, predicted seismic intensity scale, earthquake arrival time, epicenter distance, and epicenter distance should be used as an index, and the range can be specified using the upper and lower limits.
d. Main motion arrival time measurement seismic intensity equivalent value that displays the following on the function monitor of the display output device 25 (the display color is changed according to the measured seismic intensity equivalent value for alerting)
e. Functions of the past data reproduction display device 26. A function of performing reproduction display using earthquake information received and accumulated.
f. Other ・ Make each function modular so that it has flexibility and expandability for function addition, partial version upgrade and maintenance.
-The data transfer format for transmission and reception with the real-time earthquake information utilization council shall be in XML (Extensible Markup Language) format.
-To prevent transmission / reception other than a specific IP (Internet Protocol) address and port.
-The system clock must be synchronized with GPS (Global Positioning System).
As a result, since the disaster prevention radio system is a self-supporting network, the line is less likely to be congested, and the information necessary for disaster prevention workers can be transmitted more reliably.

  FIG. 3 is a diagram illustrating a timing chart of the analog communication system call signal. As shown in FIG. 3, the activation of the disaster prevention radio is input from the earthquake information transmission / reception and arithmetic unit 12 to the high frequency system. After the activation input, the call signal is input to the signal system after an idle time of 1 sec and a prepress time of 1 sec. Then, in the signal system, the voice is output after 3 seconds and the idle time 1 second in the reception processing of the calling signal. Therefore, it takes about 6 seconds from when the activation of the disaster prevention radio is input to the high frequency system until the signal system outputs sound such as broadcast.

  The above is the time required for disaster prevention radio in a normal analog communication system, but the single continuous transmission system according to the present invention is as shown in FIG. That is, the idle time can be shortened to 0.5 sec and the call signal receiving process can be shortened to 1 sec. Therefore, the speed can be increased to 3.5 seconds from the start of the disaster prevention radio to the high frequency system until the signal system outputs sound such as broadcast.

The elemental technologies are as follows.
(1) The three continuous transmissions of the call signal are shortened to the shortest with the single continuous transmission.
(2) Serial transmission for idling switching.

In addition, it takes 2.5 seconds on average for the real-time earthquake information analysis server 11 to collect the observation data and issue the epicenter information first. Therefore, the total processing time of the real-time earthquake information disaster prevention radio system is 6 seconds in total.
FIG. 5 is a diagram showing a timing chart of interrupt processing in the analog communication system. As shown in FIG. 5, when an interrupt is input to the high frequency system while the signal system is outputting voice, the idle time is 1 sec, the end signal is 3 sec, the idle time is 7 sec, the paging signal is 3 sec, and the idle time is 1 sec. Therefore, if an interrupt is input while the signal system is outputting sound, it takes 15 seconds in total to output new sound.

FIG. 6 is a diagram showing a timing chart of interrupt processing in the analog communication system according to the present invention. As shown in FIG. 6, the idle time is 0.5 sec, the end signal is 1 sec, the idle time is 4 sec, the call signal is 1 sec, and the idle time is 1 sec. Therefore, if an interrupt is input while the signal system is outputting sound, it takes 7.5 seconds in total to output new sound.
As described above, as a means for improving the time for interrupt processing in analog communication, normal communication can be achieved by shortening the three continuous transmissions of the calling signal to the shortest with single continuous transmission and serializing idling switching. So, it can be shortened from 4 seconds to 4 seconds. Also, in the case of interrupt processing, the conventional process that takes 15 seconds can be shortened to 7.5 seconds.

FIG. 7 is a timing chart of the digital communication system call signal. As shown in FIG. 7, the earthquake information transmission / reception and operation device 12 inputs disaster prevention radio activation to the control system. A call signal is input to the signal system 0.5 seconds after the start input. Actually, it takes 0.5 seconds for the calling signal and the processing time of the signal system until the signal system outputs sound such as broadcasting. Therefore, the time required for the sound to be output by the earthquake information transmission / reception and calculation device 12 is 1.5 sec. In the case of a conventional analog disaster prevention radio, this requires 6 sec. By using a digital communication system, the speed can be increased by about 4 times compared to an analog disaster prevention radio.

  Furthermore, by applying (1) shortening the three continuous transmissions of the calling signal to a single continuous transmission according to the present invention, and (2) serializing the idling switching, it is possible to obtain a voice output from the start input. The required time can be shortened to about 1 sec.

Then, it takes 2.5 seconds on average for the real-time earthquake information analysis server 11 to collect the observation data and issue the epicenter information first. Therefore, the total processing time of the real-time earthquake information disaster prevention wireless system is 4 seconds in total.
FIG. 8 is a diagram showing a timing chart of interrupt processing in the digital communication system. As shown in FIG. 8, earthquake information transmission / reception and the activation of the disaster prevention radio are input from the arithmetic unit 12 to the control system. A call signal is input to the signal system 0.5 seconds after the start input. Actually, it takes 0.5 seconds for the calling signal and the processing time of the signal system until the signal system outputs sound such as broadcasting. Up to this point, the timing chart of the call signal shown in FIG. 7 is the same. However, as shown in FIG. 8, in the interrupt processing timing chart, since the activation is input to the control system while the signal system is outputting sound, the control system end process 0.5 sec is added.
Therefore, the time required for the sound to be output by the earthquake information transmission / reception and arithmetic unit 12 is 2 sec. Therefore, by applying (1) shortening the three continuous transmissions of the calling signal to single transmission and (2) serializing the idling switching according to the present invention, the process from interrupt input to voice output is applied. The required time can be shortened to about 1.5 seconds.
As in the timing chart of the call signal, it is necessary to change the end process from three continuous transmissions to single transmission.

FIG. 9 is a diagram showing the processing time of the disaster prevention radio system according to the present invention. As shown in FIG. 9, in normal and interrupt processing in an analog communication system, by shortening the three continuous transmissions of the call signal according to the present invention to the shortest with single continuous transmission, and serializing idling switching, A speedup of about twice is realized. Further, in the digital communication system, the speed is increased by about 2.5 to 4 times that of the analog communication system.

It is a figure which shows the structure of the real-time earthquake information disaster prevention radio system which concerns on this invention. It is a figure which shows the structure of the real-time earthquake information analysis server 11 shown in FIG. It is a figure which shows the timing chart of an analog communication type call signal. It is a figure which shows the timing chart of the analog communication type | system | group calling signal of the single continuous transmission by this invention. It is a figure which shows the timing chart of an interruption process. It is a figure which shows the timing chart of the interruption process of the single continuous transmission by this invention. It is a figure which shows the timing chart of a digital communication system call signal. It is a figure which shows the timing chart of the interruption process in a digital communication system. It is a figure which shows the processing time of the disaster prevention radio | wireless system which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Seismic observation network seismometer 2 Real-time seismic information utilization meeting 3 Seismic center information distribution center 11 such as the Japan Meteorological Agency Real-time seismic information analysis server 12 Earthquake information transmission and reception device 13 Data reception management device 15 Data transmission management device 17 Outdoor loudspeaker station 18 Individual Receiver 21 Router 22 Data transceiver 23 Predicted seismic intensity scale and main motion arrival time calculator 24 Log and history management device 25 Display output device 26 Past data reproduction display device

Claims (2)

A method of utilizing real-time earthquake information by earthquake observation, which has communication control / calculation functions, data transmission management functions, and reception functions, and uses a disaster prevention radio system as a means of secondary distribution of earthquake disaster prevention information Real-time earthquake information disaster prevention radio system characterized by that. A method of utilizing real-time earthquake information by earthquake observation, wherein in the disaster prevention radio system, in order to shorten the rise time until the broadcast is started, the call signal is made to be a single transmission and the idling switching is made serial transmission. The real-time earthquake information disaster prevention radio system according to claim 1, wherein

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