JP2002334184A - System for collecting real time situation - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a real time situation collection system capable of performing urgent actions such as early assistance/rescue activity, etc., in accordance with a casualty situation by making a rescue system side grasp the casualty situation that changes by the minute just after an earthquake occurrence such as a large earthquake right under an urban area as quick and accurate real time information. SOLUTION: This real time situation collection system consists of a rescue side system server 2 bidirectionally communicable through the Internet 4 and an information collection side client 3, the information collection side client 3 side by a preselected information collector converts the casualty situations of a site that change every moment into electronic image data to collect the data, transmits the casualty situation information to the rescue side system server 2 side in real time with a portable information terminal to store the data in order to collect and grasp the casualty situation by the rescue side system server 2 just after the large earthquake occurrence as quick and accurate information, and the rescue side system server 2 side is provided with a map preparing means for preparing a casualty situation distribution diagram on the basis of the casualty situation information sent from the information collection side client 3.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is intended to enable quick and accurate collection and grasp of disasters and damages immediately after the occurrence of a disaster, for example, immediately after a major earthquake, such as a city directly below a city, thereby enabling measures for subsequent rescue operations. Real-time situation collection system.

[0002]

2. Description of the Related Art In recent years, many earthquake disaster prevention systems have been researched and developed for estimating ground motion, earthquake damage, and the like when an earthquake having a seismic intensity of 6 or more has occurred. The situation is becoming rescue. The seismic motion estimation includes a method using the time difference between the detection of the P wave and the arrival of the S wave, and a method using the time difference until the seismic wave arrives in consideration of the distance from the epicenter. A typical example is JR Uredas. In addition, earthquake damage estimation is to estimate damage from buildings, human damage, liquefaction, etc., assuming an earthquake. When an earthquake actually occurs, ground motion monitoring and GIS of ground, buildings, etc. are performed. There is one that estimates damage at an early stage based on a database or the like. These are means for estimating the overall picture of earthquake damage and ensuring the initial system and smoothly taking countermeasures during a time period when information immediately after the earthquake does not enter. Especially in the case of a large earthquake directly under the city, the damage is wide and wide, so it takes much time to grasp the damage. For example, a high-density strong seismograph network (RE
ADY) operates a real-time earthquake damage estimation system.

[0003]

However, in such a conventional real-time earthquake damage estimation system as described above,
The results of these seismic motion estimation and earthquake damage estimation are only estimations, and may be far from the actual damage situation. For example, an earthquake still contains a lot of unknown parts, and it is impossible to believe 100% of the conventional earthquake damage estimation system. The fact is that a clear method for collecting information on earthquake damage at an early stage has not been developed at this time. Therefore, it is necessary to collect the actual damage situation in the event of an actual earthquake at an early stage (for example, within about 72 hours, which is a time for determining whether the possibility of a survival rate after the earthquake has occurred). .

Accordingly, the present invention has been made in view of the above-described various existing circumstances, and enables quick and quick assessment of a damage situation that changes every moment immediately after a disaster occurs, for example, immediately after an earthquake such as a large earthquake directly under a city. An object of the present invention is to provide a real-time situation collection system that allows the rescue system to grasp as accurate real-time information and enables emergency actions such as early rescue and rescue activities according to the damage situation.

[0005]

According to the present invention, there is provided a rescue-side system server which is capable of bidirectional communication via an Internet network.
In order to make the rescue system server 2 collect and grasp the situation of the site as quick and accurate information, the information collecting client 3 by a pre-selected information collector is constantly changed. The site situation that changes is converted into electronic image data and collected, and this situation information is transmitted to the rescue system server 2 in real time to accumulate data.
It is provided with a map creating means for creating a site situation distribution map based on the site situation information sent from the information collecting client 3. It consists of a rescue system server 2 and an information collection client 3 that can communicate bidirectionally via the Internet network 4, and collects the damage situation at the site immediately after the occurrence of disaster as quick and accurate information on the rescue system server 2 side. In order to grasp the situation, the information collecting client 3 side by a pre-selected information collector collects the damage situation of the site which changes every moment by converting it into electronic image data and collects this damage situation information on the rescue system server 2.
To the data in real time and accumulate data,
The rescue system server 2 may be provided with a map creating means for creating a damage situation distribution map based on the damage situation information sent from the information collecting client 3. The information collecting client 3 has a WWW browser as an interface between the rescue system server 2 and a notebook / book capable of transmitting, as image data, a site situation photographed by a digital camera usable by an unspecified number of people. Type personal computer, mobile phone (I mode),
A portable information terminal capable of transmitting a real-time situation to the rescue-side system server 2 or receiving from the rescue-side system server 2 in real time by a PHS, a personal digital assistant (PDA) or the like can be used. The collected information of the site situation may be input of use of GPS for capturing the position of longitude and latitude, capture of an image by a digital camera, and damage recognition by ranking the risk degree of the damage result of the site. The information collection side client 3 by the disaster rescue professional organization accesses the Internet network 4 to obtain map data from the rescue side system server 2 side in advance, and maps the collected information on a map for each block of the damaged area. And re-access the network to transmit to the rescue system server 2 side. Information gathering client 3 by public civil society
Accesses the Internet network 4 to grasp the overall damage situation at the site from the rescue system server 2 side, accesses the situation around him again through a questionnaire, and transmits the situation to the rescue system server 2 side, The rescue system server 2 can process the information as accumulated data and reflect the information in the next access from the information collecting client 3. The map creating means ranks the degree of danger of the damage result for each affected area block based on the color of red, yellow, blue or the like based on the damage status information of the site sent from the information collecting client 3. Meanwhile, it is possible to create a damage situation distribution map at the site. The rescue-side system server 2 converts the site situation distribution map created by the map creating unit into electronic image data, publishes it on the Internet network 4 in real time, and provides the site situation information providing unit so that it can be shared with an unspecified number of people. It can be provided.

In the real-time situation collecting system according to the present invention configured as described above, the rescue system server 2 of the damage situation information by the information collecting client 3 is provided.
To store data on the side, access the Internet network 4 to transmit information. At this time, in an area where the damage situation is severe and the location of the information collecting client 3 itself is not known at present, position information is collected by GPS and transmitted to the rescue system server 2. On the other hand, the damage situation is not so bad and the information collecting client 3
In an area where the current location is known, the location information is collected by the portable information terminal of the information collecting client 3 and transmitted to the rescue system server 2. If the communication is disrupted, move to a place where the communication condition is good and the Internet network 4 can be accessed and then transmit, or send an external medium recording the damage status directly to the rescue system server 2 side. Read it after bringing it home. Based on the damage status information sent from the information collecting client 3, the rescue system server 2 uses the map creating means to classify the degree of risk of the damage result by color, such as red, yellow, or blue, for each affected area block. Create a distribution map of damage status while ranking the items. At this time, if no detailed damage situation is found even when collecting position information using GPS by an aerial reconnaissance aircraft such as a helicopter, fill in all blanks by collecting information by the information collecting client 3 itself. The whole damage situation distribution map is created. In addition, the damage situation distribution map is converted into electronic image data and converted into an Internet network 4
And publish it in real time, and let unspecified number of people share.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the accompanying drawings.
1 shows a configuration of a real-time situation collection system at the time of occurrence of a disaster. As shown in FIGS. 1 and 2, a rescue system established for the purpose of rescue at the time of a disaster, for example, capable of two-way communication via the Internet network 4. It consists of the hardware of the system server 2 on the side and the client 3 on the information collecting side, and collects and grasps the damage situation immediately after the occurrence of an earthquake such as a large earthquake directly below the city on the side of the rescue system server 2 as quick and accurate information. For this purpose, the information collecting client 3, which is a pre-selected information collector, collects the damage situation of the site, which changes from moment to moment, in the form of an electronic image using a digital camera, and collects the damage situation information, for example, by geostationary satellite communication or the like. Is transmitted in real time to the rescue-side system server 2 by the portable information terminal that has made available. The rescue system server 2 is provided with a map creating means for creating a damage situation distribution map based on the damage situation information sent from the information collecting client 3. Note that this system can of course be used as versatile application software.

As shown in FIGS. 4 and 6, the information collecting side client 3 has a WWW browser as an interface between the rescue side system servers 2 and is photographed by a digital camera which can be used by an unspecified number of people. For example, a notebook / book-type personal computer that can transmit the situation at the site as image data using, for example, geostationary satellite communication,
Mobile phones (I mode), PHS, personal information devices (PD
A portable information terminal capable of transmitting the damage status due to A) or the like to the rescue system server 2 in real time or receiving the information from the rescue system server 2 is used. Such portable information terminals are, for example, specialists, governments,
Disaster rescue agencies such as the SDF, fire brigade and volunteer rescue organizations,
It should be owned by an unspecified number of personnel, such as representatives of public civil society organizations, and by personnel and institutions specially trained in the event of a major earthquake.

[0009] Collected information on the damage status collected by an unspecified number of people is composed of three elements: position, image, and damage recognition. That is, the collected information is the use of GPS for capturing the position of longitude and latitude, the capture of images by a digital camera, and the input of damage recognition by ranking the degree of risk of the damage result. As shown in FIG. The information collection side client 3 by the rescue professional organization accesses the Internet network 4 to obtain map data from the rescue side system server 2 side in advance, maps the collected information on a map of the damaged area and displays it, and again. It accesses the Internet network 4 and sends it to the rescue system server 2 side.

[0010] As shown in FIG. 5, the information collecting client 3 by the public civil society accesses the Internet network 4, grasps the overall damage situation from the rescue system server 2, and conducts a questionnaire around the client 3. To the rescue system server 2 by accessing the Internet network 4 again, and the rescue system server 2 processes the information as accumulated data and reflects the information in the next access from the information collecting client 3. There is to be. The collected information is distributed to an unspecified number of people to share data. As described above, in this system, software that uses a map created by GPS, software that maps digital camera images onto a map, software that exchanges data between sub-hosts,
Each software such as damage input software is complete.

As shown in FIG. 3, when the information collecting client 3 stores the damage status information in the rescue system server 2, the information is transmitted by accessing the Internet network 4. In an area where the damage situation is severe and the location of the information collecting client 3 itself is not known at present, positional information is collected by GPS and transmitted to the rescue system server 2. However, in an area where the damage situation is not so bad and the location of the information collecting client 3 itself is known,
The position information is collected by the portable information terminal of the information collecting client 3 and transmitted to the rescue system server 2. If the communication is disrupted, move to a place where the communication condition is good and the Internet network 4 can be accessed and then transmit, or send an external medium recording the damage status directly to the rescue system server 2 side. Read it after bringing it home.

The contents of the damage status information to be collected include, for example, information such as complete, partial or no collapse of houses, factories, buildings, expressways, pedestrian bridges, railway bridges, power transmission towers, gas tanks, gas stations, chemical factories, and the like. And information on burning, partial burning, no burning, etc., and information on occurrence of ground cracking and liquefaction. For example, as shown in FIG. 4, the information input screen used by the specialized disaster rescue organization includes input fields for longitude / latitude data, a column for selecting a structural type such as wooden or RC in the individual damage tab, Damage information selection columns for damage, collapse, fire, sinking, gas leaks, liquefaction, landslides, landscaping, etc., image display columns with a digital camera, and the degree of risk of the damage results are classified by red, yellow, blue, etc. It has a map data display field that can be ranked for each regional block and that can be converted to raster and vector.

On the other hand, as shown in FIG. 6, on the information input screen used by the public citizen's organization, an outdoor damage questionnaire is selected, for example, according to the degree of risk of the damage result of the entire city as seen from indoors at the present time. Based on a collapse situation selection field, a fire situation selection field for selecting the extent of damage caused by the fire, an address input field, a damage map display field displaying the seismic intensity of each area by color, and a damage grasp questionnaire It has a created damage status map display field. The damage status map display field displays the damage status of each regional block, which changes every moment, in real time by ranking by color. The collapse status selection field and the fire status selection field can be selected, for example, in the form of an icon or a click button in which the damage state is represented by a picture.

The rescue-side system server 2 uses the map creation means to determine the degree of risk of the damage result in different colors such as red, yellow, and blue based on the damage status information sent from the information collecting client 3. The damage situation distribution map is created by displaying the data while ranking each area block and displaying the image of the damage situation by the digital camera captured through the communication by the geostationary satellite (see FIG. 7). At this time, if no detailed damage situation is found even when collecting position information using GPS by an aerial reconnaissance aircraft such as a helicopter, fill in all blanks by collecting information by the information collecting client 3 itself. Thus, a distribution map of the entire damage situation can be created. Further, a damage status information providing means is provided so that the damage status distribution diagram is converted into an electronic image and released on the Internet network 4 in real time, and can be shared with an unspecified number of people. In this way, information that fills the blank space for each affected area block is collected and provided to the decision materials for early rescue measures.

As shown in FIG. 2, the rescue-side system server 2 uses a real-time seismic motion estimation system that estimates point-wise measured seismic intensity information of strong-motion network data as surface seismic intensity distribution using surface ground data. Damage estimation distribution in the real-time earthquake damage estimation system,
It superimposes on the rescue system server 2 side obtained from the portable information terminal of the information collection side client 3 via the Internet network 4 and the real-time information of the damage situation of the site, which changes every moment after the earthquake, and changes with the time history. It has created a distribution map of the damage situation that is being carried out, and enables emergency actions such as early rescue and rescue activities according to this damage situation.

Although the present embodiment has been described assuming a situation after the occurrence of a large earthquake directly below a city, the present invention is not limited to such a disaster. For example, congestion on expressways, regular roads, railways, etc.
In order for the system server to collect and grasp information on traffic congestion, road traffic management, and the congestion of ships on the sea as quick and accurate information, the information collection client by the information collector selected in advance is constantly changing. The site situation that changes is converted to electronic image data and collected, and this status information is transmitted to the system server in real time to accumulate data, and the system server side receives the site situation information sent from the information collection side client It is also possible to construct a real-time situation collection system which is provided with a map creating means for creating a site situation distribution map.

[0017]

Since the present invention is configured as described above, the instantly changing damage situation immediately after the occurrence of a disaster, for example, immediately after an earthquake such as a large earthquake directly under a city, is rescued as quick and accurate real-time information. It is possible to provide a real-time situation collection system that allows the system to understand and enables urgent actions such as early rescue and rescue activities according to the damage situation.

[Brief description of the drawings]

FIG. 1 is a system schematic diagram according to an embodiment of the present invention.

FIG. 2 is a block diagram of the same.

FIG. 3 is a flowchart illustrating a system operation.

FIG. 4 is a plan view showing a display example of an information input screen.

FIG. 5 is a flowchart illustrating another system operation.

FIG. 6 is a plan view showing another display example of the information input screen.

FIG. 7 is a plan view showing a display example of a damage distribution screen on the system server side.

[Explanation of symbols]

 1 Real-time situation collection system 2 Rescue system server 3 Information collection client 4 Internet network

 ──────────────────────────────────────────────────続 き Continuation of the front page (71) Applicant 500124781 Yoshitaka Yamaoka 5-10-10 Midorioka, Ageo City, Saitama Prefecture (71) Applicant 500124552 Netwave Inc. 1-11-3 Shinjuku, Shinjuku-ku, Tokyo (72) Invention Person Yoshiaki Hisada 3-17-8-306 Kaminoga 3-17-8-306, Setagaya-ku, Tokyo −107 F term (reference) 5B050 AA08 BA11 BA17 BA18 CA05 CA06 CA08 FA02

Claims (8)

[Claims] 1. A system server comprising a system server capable of bidirectional communication via a network and an information collecting client, which is selected in advance in order for the system server to collect and grasp the situation at the site as quick and accurate information. The information gathering side by the information gathering client collects the scene situation that changes every moment by converting it into electronic image data, transmits this situation information to the system server side in real time and accumulates the data. A real-time situation collection system comprising a map creating means for creating a situation situation distribution map based on the situation situation information sent from the collecting client. 2. A system server for rescue, which can communicate bidirectionally via a network, and a client on the information collection side, and collects the damage situation at the site immediately after the occurrence of the disaster as quick and accurate information on the system server side. In order to grasp the situation, the information gathering client by a pre-selected information collector gathers the damage situation of the site that changes every moment by converting it into electronic image data, and transmits this damage situation information to the system server side in real time. In addition to data storage, the system server is equipped with map creation means for creating a damage situation distribution map based on the damage situation information sent from the information gathering client. system. 3. The information collecting side client has a WWW browser as an interface between the system servers, and is a notebook type client capable of transmitting, as image data, the situation of a site photographed by a digital camera usable by an unspecified number of people.・ Book type personal computer, mobile phone (I mode),
The real-time situation according to claim 1 or 2, wherein the real-time situation is based on a portable information terminal capable of transmitting a site situation by a PHS, a personal digital assistant (PDA) or the like to the system server in real time or receiving the situation from the system server. Collection system. 4. The collected information of the site situation is input of the use of GPS for capturing the position of longitude and latitude, the capture of an image by a digital camera, and the input of damage recognition by ranking the risk degree of the damage result of the site. 4. The real-time situation collection system according to any one of 1 to 3. 5. An information collecting side client by a disaster rescue specialized agency accesses a network, obtains map data in advance from a system server side, and maps the collected information on a map for each block of a damaged area. The real-time status collection system according to any one of claims 1 to 4, wherein the information is displayed, and the network is accessed again and transmitted to the system server. 6. The information collection side client by the public civic group accesses the network, grasps the overall damage situation at the site from the system server side, and accesses the network again by using the questionnaire to find out the situation around the system server. 6. The real-time status collection system according to claim 1, wherein the information is transmitted to the information server, the system server processes the information as accumulated data, and reflects the information on the next access from the information collection-side client. 7. The map creating means, based on the on-site damage status information sent from the information collecting client,
7. The real-time situation according to any one of claims 1 to 6, wherein a damage situation distribution map at the site is created while ranking the degree of risk of the damage result according to the color of red, yellow, blue, etc. for each affected area block. Collection system. 8. A system server includes a site situation information providing unit that converts the site situation distribution map created by the map creating unit into electronic image data, publishes it on a network in real time, and shares it with an unspecified number of people. The real-time situation collection system according to any one of claims 1 to 7, comprising: