JP2987435B2 - Geographic weather mobile monitoring system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a terrain weather monitoring system for monitoring terrain and weather.

[0002]

2. Description of the Related Art Since ancient times, it has been reported that various changes in terrain and weather occur as precursors before a large earthquake. For example, in the previous Hyogoken-Nanbu Earthquake, the generation of charged aerosols, rumbling, radon and other gases, and changes in the color of clouds and the moon have been reported (Hiroyoshi Umihara, Aura Testimony 1519). , Tokyo Publishing (1
995)). Therefore, if such changes in terrain and weather can be captured, there is a possibility that it can be used for earthquake prediction. Therefore, research institutes are currently observing minute displacements of the crust, groundwater levels, ground currents, etc., aiming at earthquake prediction.

[0003]

However, the above observations are mainly performed by fixed-point observation, and the fixed-point observation has the following problems.

[0004] One of them is that the fixed point observation site is
It is not always the same as the place where the precursor of the earthquake appears remarkably. That is, when an abnormal terrain / weather change occurs at a place other than the fixed point, the observation may not be started. In such a case, an earthquake may occur before the precursor phenomenon can be detected.

In this fixed-point observation, it is necessary to increase the number of fixed points in order to map signal information on a map to increase the area and density of information. There are difficulties such as enormous costs for securing land and installing facilities.

As an example, the fixed point observation of the pulsed earth current in the range of 100 KHz to 10 MHz, which is performed by the Institute of Mechanical Engineering, is continuously observed at about 20 points from Hokkaido to Hiroshima. In this fixed-point observation, the Akita-ken Nanbu Earthquake occurred on August 11, 1996 (M = 5.9, 5.4,
Approximately 66 hours before the quake swarm including 5.7), abnormal signals, which are considered precursors, were simultaneously observed at several locations in the Kanto area, such as Erimo and Tsukuba. In the case of the M = 6.2 earthquake off the east coast of Chiba Prefecture, which occurred on September 11, the same year, two abnormal signals were observed at each point in the Kanto area about 100 hours before the occurrence of the earthquake (Y.
Enomoto et al., Geophysical Jour
nal International (1997) 13
1,485-494). And these studies have revealed that: 1) In order to identify the source, it is necessary to set up observation points at a higher density. 2) Even if the observation point is set up in a wide area, 20-30% of the data cannot be used practically because there is noise peculiar to the area depending on the place.

[0007] The present invention has been proposed in view of the above,
It is an object of the present invention to provide a geo-meteorological mobile monitoring system that can be constructed at low cost and can monitor changes in geo-meteorology and weather from a wider area at a higher density.

[0008]

According to one aspect of the present invention, a sensor for detecting a terrain / weather is provided in a terrain / weather movement monitoring system for monitoring a terrain and the weather. And, a moving body equipped with a position detecting device for detecting the position of the moving body, and provided in the moving body, when the level of the sensor signal received from the sensor exceeds a predetermined threshold, the sensor signal, A sensor signal transmitting unit that adds and transmits the position information detected by the position detecting device, and receives the sensor signal and the position information transmitted from the sensor signal transmitting unit, and displays the position information on the map corresponding to the position information. Mapping means for mapping the sensor signal and showing the sensor signal according to the level.

According to a second aspect of the present invention, in addition to the configuration of the first aspect, the sensor signal transmitted by the sensor signal transmitting means is obtained by ranking signal levels. It is characterized by rank information.

[0010]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a diagram schematically showing the entire configuration of a geographical weather mobile monitoring system of the present invention, and FIG. 2 is a block diagram of the same. In these figures, an observation device 1 is mounted on a moving body 4 which is a vehicle, and a sensor group 20, a position detection device 3, and a sensor signal transmission device 10 are arranged in the observation device 1.

The moving object 4 is a vehicle such as an automobile, a railway, a motorcycle, a model airplane, an airship, and the like. The automobile includes a regular bus, a long-distance truck, a luggage delivery vehicle, a taxi, a dedicated observation vehicle, and the like. Can be used.

The above-mentioned sensor group 20 is various sensors for detecting terrain and weather. For example, as shown, a radon measuring device 21, a charged aerosol observing device 22, a carbon dioxide measuring device 23, an electromagnetic field noise measuring device 24 , A noise measuring device 25, and a combustible gas detector 26 for detecting a combustible gas such as methane gas.

The above-mentioned position detecting device 3 is a GPS (global post) which is a positioning system using a satellite.
ioning system), or by the PHS method using a communication network of a simplified mobile phone,
This is a device that detects the current position of the moving body 4.

The above-described sensor signal transmission device 10 is composed of a personal computer or a workstation, and performs transmission processing in the following procedure. First, from which sensor the sensor signal received from the various sensors 21 to 26 is a signal,
That is, the type of the signal is recognized, and it is determined whether or not the signal level exceeds a predetermined threshold value set in advance. The threshold is set for each type of sensor signal. When the sensor signal exceeds a predetermined threshold, ranking is performed on the sensor signal.
This ranking is, for example, such that the threshold is divided into three stages of 10 times or less, between 10 times and 100 times, and 100 times or more of the threshold value.

After the above-mentioned ranking is completed, the type of the sensor signal, the rank information to which the sensor signal belongs, and the position information indicating the observation position received from the position detection device 3 are transmitted. This transmission is performed using, for example, the mobile phone 11, and the modem 12 on the receiving side receives the rank information and the position information via the telephone line and sends the information to the mapping device 6.
To communicate.

FIG. 3 is a flow chart of the transmission process performed by the sensor signal transmitting device. Sensor signal sending device 10
First, in step S1, a process of receiving a sensor signal and position information is performed, and a process of sequentially storing the information on a hard disk is performed. Thereafter, the process proceeds to step S2. If the amount of information recorded on the hard disk exceeds a certain amount, the oldest recording is sequentially deleted and replaced with new information.

In step S2, the types of sensor signals such as a radon concentration signal, a charged aerosol detection signal, and an electromagnetic field detection signal are recognized, and the flow advances to the next step S3.

In step S3, it is determined whether or not the sensor signal has exceeded the threshold. If the sensor signal has exceeded the threshold, the process proceeds to the next step S4, otherwise, the transmission process is completed.

In step S4, the sensor signals are ranked, and the flow advances to the next step S5.

In step S5, the type information, the rank information, and the position information of the sensor signal are transmitted, and then the transmission processing ends.

The mapping device 6 is composed of a work station, and functions as a host computer for information sent from the mobile units 4 around the country. The hard disk of the mapping device 6 stores wide-area map information (map), for example, map information of all over Japan, one by one according to the type of sensor signal. The mapping device 6 performs the mapping process in the following procedure when the signal type information, rank information, and position information are input.

First, a map is selected and an observation position is searched. If the type of the sensor signal is, for example, a radon concentration signal from the radon observation device 21, the mapping device 6 selects a map for the radon concentration signal, and determines an observation position from the map based on the input position information. Search for. Next, the sensor signals are illustrated at the observation positions obtained by the search according to the rank. This illustration is a symbol such as a black circle if the sensor signal rank belongs to three of the three stages, and a hatched circle if it belongs to the second stage. Alternatively, a color-coded display may be performed according to the rank.

FIG. 4 is a flowchart of a mapping process performed by the mapping device. The mapping device 6 first performs a process of receiving the signal type information, rank information, and position information transmitted from the sensor signal transmission device 10 in step S11, and then proceeds to step S12.

In step S12, a map is selected according to the type of signal, and thereafter, the flow advances to step S13.

In step S13, an observation position is searched based on the position information, and the flow advances to the next step S14.

In step S14, the observation positions on the map are shown according to the ranks, and then the mapping process ends.

As described above, in this embodiment, the terrain / weather is detected while moving, and the result of the detection is mapped on the host computer side. In addition, changes in geographical features and weather can be monitored from a wider area at a high density. Further, it is not necessary to secure land and equipment required for fixed-point observation, and an observation system can be constructed at low cost.

Further, when the sensor signals are transmitted, the sensor signals are ranked and the rank information is transmitted, so that the amount of information to be transmitted can be reduced. Can be sent.

If a taxi, a courier truck, a long-distance truck, a regular route bus, a train, or the like that travels widely over a wide area on a daily basis is used as the mobile unit 4, daily geographical phenomena can be spread over a wide area. Monitor by density. Also,
Since an observation network can be set up over a wide area, it is possible to detect a local change without overlooking it.

This terrain weather mobile monitoring system can be used for prediction immediately before an earthquake. For example, 1
In the Hyogoken-Nanbu Earthquake that occurred on January 17, 995, the radon concentration in groundwater at Nishinomiya began to increase gradually from November 1994, about two months before the earthquake, and rose sharply about a week ago ( Igarashi et al., Sciencec
e, vol. 269, p60.61, 1995). Also, about 45 minutes before the occurrence of the earthquake, the electromagnetic phenomena became inaudible due to noise in the medium-wave broadcasting band.
(Yoshio Yoshino, CA Anomaly Study Group, 1997 Transactions, pp. 82-89). In addition, as abnormal phenomena in the past earthquakes, in the 1847 (Kokka 4th year) Zenkoji earthquake and the 1855 (Ansei 2nd year) Ansei Edo earthquake, natural gas spewed from the ground or Hyogo. It has been reported that natural gas such as methane had been emitted since the prefecture's Nanbu Earthquake had a rotten smell before the earthquake.

In the geographical weather mobile monitoring system of the present invention, such geographical phenomena of various items are constantly observed in a wide area, and the observation results are immediately recorded. For example, the radon concentration in a certain area increases. If, at the same time, the electromagnetic phenomenon becomes remarkable, it is possible to predict the earthquake precursor phenomenon with a considerably high probability, and the prediction immediately before the earthquake can be further ensured.

From such a mobile wide-area observation,
If continuous observation is performed so that precursor phenomena can be detected with high sensitivity, an effective so-called “pot” can be found, and feedback to fixed-point observation, such as efficient determination of fixed-point observation points, is also possible.

[0033]

Since the present invention has the above-described configuration,
The following effects can be obtained. According to the first aspect of the present invention, the terrestrial terrain / weather is detected while moving, and the detection result is mapped on the host computer side. -It is possible to monitor weather changes from a wider area at high density. Further, it is not necessary to secure land and equipment required for fixed-point observation, and an observation system can be constructed at low cost.

In addition, since the geometeorological phenomena over a wide range of items are constantly observed in a wide area and at a high density, and the observation results are immediately recorded, for example, the radon concentration in a certain area increases,
At the same time, if the electromagnetic phenomenon becomes remarkable, it is possible to predict the earthquake precursor phenomenon with a considerably high probability, and the prediction immediately before the earthquake can be further ensured.

Further, according to the second aspect of the present invention, when the sensor signal is transmitted, the sensor signal is ranked and the rank information is transmitted, so that the amount of information to be transmitted can be reduced. , So it can be sent quickly and at low cost.

[Brief description of the drawings]

FIG. 1 is a diagram schematically showing an overall configuration of a geometeorological mobile monitoring system of the present invention.

FIG. 2 is a block diagram of a geographical weather mobile monitoring system of the present invention.

FIG. 3 is a flowchart of a transmission process performed by the sensor signal transmission device.

FIG. 4 is a flowchart of a mapping process performed by the mapping device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Observation apparatus 3 Position detection apparatus 4 Moving body 6 Mapping apparatus 10 Sensor signal transmission apparatus 11 Mobile phone 12 Modem 20 Sensor group 21 Radon measurement apparatus 22 Charged aerosol observation apparatus 23 Carbon dioxide measurement apparatus 24 Electromagnetic field noise measurement apparatus 25 Noise measurement apparatus 26 Combustible gas detector

Continuation of front page (56) References JP-A-2-13057 (JP, A) JP-A-49-105595 (JP, A) JP-A-6-14250 (JP, A) JP-A-9-189760 (JP, A) , A) JP-A-9-112200 (JP, A) JP-A-10-104247 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) G01W 1/00 G01V 1/00

Claims (2)

(57) [Claims] 1. A Chisho and Chisho weather mobile monitoring system for monitoring the weather, a sensor for detecting Chisho & weather, equipped with a position detecting device according to the GPS for detecting the position of the vehicle, daily To
A vehicle that performs wide-area movement, and a sensor signal provided in the vehicle , the sensor signal being received when a level of a sensor signal received from the sensor exceeds a predetermined threshold.
Rank information to which the level belongs, and the above GPS position
A sensor signal transmitting means for transmitting the position information detected by the detection device, a rank information and position information transmitted from the sensor signal transmitting means, and a position on a map corresponding to the position information And a mapping means for mapping the rank information to the map according to the rank . 2. The vehicle according to claim 1, wherein the sensor is a radon.
Measurement device, charged aerosol observation device, carbon dioxide measurement device
Equipment, electromagnetic field noise measuring device, noise measuring device, combustible gas
Equipped with at least one detection device, The geographical weather movement type monitor according to claim 1, wherein
Taring system.