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[MEGA Earthquake Prediction/Prediction System]
1. Optical remote sensing based on sanitary optoelectronics.
2. For sanitary reasons, all of Japan is scanned once an hour.
3. Continuous real-time observation of vertical and horizontal changes in the ground surface on a scale of one day, one week, one month, and one year.
4. In addition to uplift/subsidence and horizontal displacement, abnormal vibrations (earthquake precursor tremors) and ejected gas are simultaneously measured in real time to predict earthquake precursors.
5. Realizing dynamic real-time observation by laser application remote sensing, unlike conventional satellite photography and observation point measurement, which is static observation of crowds of people.
Part 2
1. Optical remote sensing that monitors and quantitatively analyzes changes in ground surface shape using quantum interference.
2. Developed "Vector Dynamic Technology" that digitizes the time variation, vibration, and acceleration of the ground surface shape (unevenness) by tens of thousands of points in real time.
3. By using the above-mentioned quantum interference vector dynamic technology, it is possible to quantify and visualize not only displacement of the ground surface, fault formation, cracks, upheaval, and depression, but also the occurrence and accumulation of strain near the ground surface in real time, 24 hours a day. .
4. This makes it possible to predict not only earthquake signs but also volcanic eruption signs.
5. The economic effect of this system will not be less than 100 trillion yen.
6. It can bring about a revolutionary evolution in the prediction of earthquake signs and eruption signs that rely on conventional human knowledge.
MEGA Earthquake Prediction/Prediction System
Part 1
Artificial Evolution Research Institute (AERI) as a national resilience solutionhttps://www.aeri-japan.com/) provides the "MEGA Earthquake Prediction/Prediction System"It is possible to detect volcanic eruption precursor phenomena in situ,In addition to earthquake precursors, it is possible to predict volcanic eruption precursors.
The economic effect of this system is at least 100 trillion yen.
It can bring about a revolutionary evolution in the prediction of earthquake and eruption signs that rely on conventional human knowledge.
1. Conventionally, the earthquake prediction adopted by the Japan Meteorological Agency was based on past earthquake data, and human knowledge was used to predict an earthquake that was thought to occur in the near future.
2. In other words, in conventional earthquake prediction, it is considered essential for earthquake prediction and prediction.
(1) Changes in the ground surface, that is, changes in the vertical direction of the ground surface (uplift/sinking),
(2) horizontal fluctuations, and
③Earthquake motion (vibration of ground surface)
Such vital data was not taken into consideration, and it was extremely difficult to foreshadow and predict an approaching earthquake.
3. Artificial Evolution Research Institute (AERI) as a national resilience solutionhttps://www.aeri-japan.com/) is researching and developing the "MEGA Earthquake Prediction/Prediction System" (https://www.aeri-japan.com/megaearthquakeforecasts),
Using artificial satellites equipped with a satellite optoelectronic system and quantum interference vector dynamics technology, we can obtain key data on the ever-moving ground surface (1 to 3), which is one of the important earthquake precursor phenomena (perspective phenomena). ),
Abnormal fluctuations directly linked to earthquakes (earthquake motion at observation points, ie, abnormal vibrations (earthquake premonitor tremors)) are detected in situ 24 hours a day to predict and predict earthquakes.
And, in addition to earthquake predictions,Possible to predict volcanic eruption precursors by detecting eruption precursors in situbecomes.
The economic effect of this system will not be less than 100 trillion yen.
It can bring about a revolutionary evolution in the prediction of earthquake signs and eruption signs that rely on conventional human knowledge.
4. Our firm (https://www.aeri-japan.com/) national resilience solution “MEGA Earthquake Prediction/Prediction System” (https://www.aeri-japan.com/megaearthquakeforecasts)teeth
satellite optoelectronicsby applyingFull scan of Japan once an hour from satellitedeath,Observation of vertical and horizontal variations of the ground surface in real time on a daily, weekly, monthly, and yearly scale, and predicting the possibility of earthquake occurrence (earthquake precursor) based on the results. It is.
5. MEGA Earthquake Prediction and Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts) directly linked to earthquakes detected in situAbnormal fluctuations (earthquake motion at earthquake prediction stations),
In other words, abnormal vibrations (earthquake precursor tremors) are vertical and horizontal vibrations (swaying movements) of the ground surface in an earthquake.
The seismic motion at the observation point of interest isQuantum interference type vector dynamic technologyis treated as a vibration phenomenon (amplitude, period, velocity/acceleration of vibration point, etc.).
Seismic motion, which is one of the important earthquake precursor phenomena (perspective phenomena), is the vibration of the ground.https://www.aeri-japan.com/), the unique period called the predominant period that exists for each ground is measured in situ all the time in real time and used as an earthquake precursor/prediction parameter.
6.Dynamic characteristics of seismic ground motion and earthquake precursors:
(1)Precursor phenomena of earthquakes (perspective phenomena)Seismic motion, which is one of the important factors inIt is characterized by a short period of motion or a vibration that repeats many irregular motions..
A major part of the repetitive oscillations is in the faults that generate the earthquakes.
Pressurization (fixation) ➡ release (displacement) ➡ pressurization (fixation) ➡ release (displacement) ➡ ……….
(2) In the fault that causes earthquakes, the fault planes are displaced by a strong force when an earthquake occurs. An earthquake) is several m2 (square meters), and an earthquake with a magnitude of M9 or higher is about 10,000 km2.The speed of slippage is not constant, and the speed of slippage and ease of slippage vary depending on the location, resulting in discontinuous, irregular and non-uniform vibration..
(3) The generated seismic motion propagates to the surroundings at a propagation speed of about 3 to 7 km/s.
The speed and ease of transmission are determined by the nature of the vibration. The speed and ease of transmission of seismic motion are also affected by the properties (geology) of the ground.
(4) Depending on the nature of the ground and the nature of vibration, seismic motions interfere and synthesize, and the period of seismic motions changes regularly or irregularly (periodic seismic motions, pulse-like seismic motions, and irregular oscillatory waves).
Periodical and pulsed seismic motions are wave motions.
Therefore, MEGA earthquake prediction and prediction system (https://www .aeri-japan.com/megaearthquakeforecasts)Quantum interference type vector dynamic technologyThenSeismic motion, which is a vector, is treated as a scalar for each direction, and measured into three components: vertical motion component, north-south motion component, and east-west motion component.
The characteristics of pitching and rolling are not due to differences in seismic waves, but to differences in the directions of seismic motions, such as up and down, north, south, east and west.
7.Characteristics of seismic wave oscillations and earthquake precursors, which are one of the important earthquake precursor phenomena (cosmetic anomalies):
(1) Due to the nature of vibration (seismic waves), which is one of the important earthquake precursor phenomena (perspective phenomena), there are cases where certain rules are created in the ground shaking pattern. many.
Earthquake motions (seismic waves) generated at the epicenter are transmitted to the surroundings at a finite speed.
Its speed is about 3 to 7 km/s, which is 10 to 20 times faster than sound waves, but it is only 1/50,000 to 1/100,000 of the speed of light, so earthquakes It takes time for the surrounding ground to shake after an earthquake occurs, and the longer the distance from the epicenter, the longer the time.
(2) Artificial evolution research institute (AERI) promoted by national resilience solutionshttps://www.aeri-japan.com/)’s MEGA Earthquake Prediction/Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts) has adoptedQuantum interference type vector dynamic technologyappliedoptical remote sensing, the change motion of the ground surface shape isMonitor in situQuantitative analysis of changes in ground surface shape.
(3) Of the seismic motions detected by dynamic real-time observation technology, i.e., abnormal vibrations (earthquake precursor tremors), P waves with a short period and a fast propagation velocity of around 7 km/s are , which arrives first and produces a small rattling tremor, called the primary tremor.
The shaking is small because the period is very short and the attenuation is large. Sound waves) are often generated.
(4) Artificial Evolution Research Institute (AERI)https://www.aeri-japan.com/) provides a national resilience solution, applying quantum interference to monitor and quantitatively analyze changes in the ground surface shape in situ.optical remote sensingThe MEGA Earthquake Prediction and Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts) detect this seismic ground motion (irregular oscillatory wave) in situ using quantum interference vector dynamics technology, and obtain the response spectrum or power spectrum.
(5) The S-wave, which has a relatively long period and propagates at about half the speed of the P-wave, arrives after the initial tremor and causes violent shaking accompanied by acceleration. is
Earthquakes have different S-wave periods, and the dominant seismic motion period (the period of the seismic motion with the largest amplitude) also changes, which greatly affects the damage situation.
(6) In addition, the surface wave, which is a composite wave (irregular vibration waveform) composed of multiple cycles and with different propagation velocities for each cycle, is a vibration with a period that causes damage. arrives slightly later than the S wave.
This surface wave has low attenuation, so it can reach a long distance and generate long-period vibrations of earthquakes even at points thousands of kilometers away from the epicenter (especially high-rise buildings such as tower apartments). easily shaken inside).
This surface wave is also included in the above main motion, together with the P wave that follows the arrival of the S wave.
(7) The difference between the first arrival times of the P wave and the S wave is called initial tremor duration.
MEGA Earthquake Prediction and Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts),We detect this seismic motion (irregular oscillating wave) in situ using vector dynamics technology that applies quantum interference, and estimate the location of the epicenter from the initial tremor duration of the irregular oscillating wave.
In addition, the propagation of seismic motion (earthquake waves) whose propagation speed changes depending on the ground is measured using quantum interference vector dynamic technology andLaser application remote sensingaccording toDynamic real-time observation technologyis used to measure in situ and estimate the detailed epicenter position (epicenter and depth).
8.Seismic motion/period of seismic waves and earthquake precursors:
(1) Monitor and quantitatively analyze changes in ground surface shape using quantum interferenceoptical remote sensingThe MEGA Earthquake Prediction and Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts),Quantum interference type vector dynamic technologyBy using theDetect in situ.
Earthquake motions (irregular oscillatory waves) are more difficult to attenuate the longer their period is, and they travel long distances over a long period of time.
In addition, the harder the ground that transmits the seismic motion, the shorter the period of the seismic motion.
Buildings have a unique resonance frequency due to the rigidity and height of their building materials, and can cause great damage when they resonate with the period of seismic motion. Depending on which frequency is dominant in the seismic motion that reaches it, there will be differences in damage to structures that receive resonance.
Earthquake waves have an irregular vibration waveform, but peaks appear when the response spectrum or power spectrum is obtained. Although not as sharply peaked as the resonance curve for harmonic input, this is the swayable frequency of the ground. This frequency is the dominant frequency.
(2) Monitor and quantitatively analyze changes in ground surface shape using quantum interferenceoptical remote sensingMEGA Earthquake Prediction/Prediction System (National Resilience Solutionhttps://www.aeri-japan.com/megaearthquakeforecasts), this phenomenon is considered as an earthquake precursor phenomenon (perspective anomaly) that causes enormous human damage.In situ detection of seismic motion at the dominant frequency (killer pulse)and predict earthquakes.
(3) In addition, the higher the rigidity and the lower the building, the higher the resonance frequency, and the more likely it is to be severely damaged by an inland earthquake with many high frequencies.
Conversely, the lower the rigidity and the higher the building, the lower the resonance frequency.
It becomes more susceptible to damage from long-term, long-period seismic motion.
This long-period seismic motion is difficult to attenuate and reaches far away, and is often included in large-scale earthquakes. .
(4) The frequencies that have the greatest impact on humans (human damage) are 4 to 8 Hz for vertical components and 1 to 2 Hz for horizontal components when sitting in a chair, and are more sensible than 55 dB.
It is easier to feel longer-period shaking when standing and shorter-period shaking when lying down.
(5) Seismic motion is an irregular oscillatory wave, which can be divided into six types according to the period.
MEGA Earthquake Prediction and Prediction System (National Resilience Solutionhttps://www.aeri-japan.com/megaearthquakeforecasts), causing enormous human damage,Precursor phenomena of earthquakes (perspective phenomena)We detect these 6 types of irregular oscillatory waves (pervasive anomaly) in situ to predict earthquakes.
(a) Extremely short period ground motion:
Seismic motion with a period of 0.5 seconds or less. The period in which indoor furniture and objects are most likely to sway. This seismic motion is the one to which instrumental seismic intensity meters are most sensitive, so it is considered to be the cause of discrepancies between the seismic intensity and the damage and perceived seismic intensity.Seismic motion with a period of 0.5 seconds or less. The period in which indoor furniture and objects are most likely to sway.This seismic motion is the one to which instrumental seismic intensity meters are most sensitive, so it is considered to be the cause of discrepancies between the seismic intensity and the damage and perceived seismic intensity.
(b) Short-period ground motion:Seismic motion with a period of 0.5 to 1 second. Short-period seismic ground motion may also be included.
(c) Slightly short-period ground motion:Seismic motion with a period of 1 to 2 seconds. Wooden houses and non-wooden middle- and low-rise buildings are the most susceptible to seismic ground motion. During the Hyogo-ken Nanbu Earthquake (Great Hanshin-Awaji Earthquake), this seismic motion was dominant in the immediate vicinity and caused enormous damage.
(d) Short-period ground motion:Seismic motion with a period of 2 to 5 seconds. Medium-sized and medium-rise buildings, such as huge tanks and steel towers, are the most susceptible to seismic motion.
(e) Long-period ground motion:Seismic motion with a period of 5 seconds or more. Somewhat long-period ground motion is also included. High-rise buildings and super-high-rise buildings are the most susceptible to seismic ground motion. Compared to short-period earthquakes, buildings shake more widely, and heavy objects move at high speeds along with the shaking of buildings, causing damage to people and objects.
(f) Very long-period ground motion:Seismic motion with a period of 100 seconds. Earthquake motion that causes the earth to shake the most.
9.Seismic ground motion (earthquake precursor phenomenon (perspective anomalous phenomenon)) and earthquake precursor as seen by ground surface vibration and amplitude:
(1) MEGA Earthquake Prediction and Prediction System (National Resilience Solution), which is an optical remote sensing that monitors and quantitatively analyzes changes in ground surface shape using quantum interferencehttps://www.aeri-japan.com/megaearthquakeforecasts)teethamountThis seismic motion (irregular oscillatory wave) is detected using interferometric vector dynamics technology, and the magnitude and inclination of the seismic motion, which is one of the important premonitory phenomena of earthquakes (perspective anomalous phenomena), is measured, and the displacement is measured. , seismic intensity, velocity, acceleration, etc.
(2) Displacement is the magnitude of amplitude that can be seen from the waveform of seismic waves.
The seismic intensity is calculated by considering the magnitude of the earthquake motion on the ground and the degree of damage.
Velocity simply represents the speed of seismic motion.
Acceleration indicates changes in seismic motion, and the greater the acceleration, the more violent the shaking.
(3) MEGA Earthquake Prediction and Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts)teeth,One of the national resilience solutionsBy using quantum interference type vector dynamic technology,It is possible to digitize and visualize not only displacement of the ground surface, fault formation, cracks, upheaval, and depression, but also the occurrence and accumulation of strain near the ground surface, and the response spectrum or power spectrum in real time and in situ for 24 hours.
10.Seismic ground motion seen in the rumbling of the earth
(1) Subterranean rumbling (earthquake sound) is one of the important earthquake precursor phenomena (perspective phenomena).
Ground vibration (earthquake motion), which is mainly caused by earthquakes, is considered to be a phenomenon that propagates through the air as sound (sound waves).
Ground rumbling, which is one of the important earthquake precursor phenomena (perspective phenomena), is the above-mentioned irregular oscillatory wave, Short-period ground motion, (d) slightly long-period ground motion, (e) long-period ground motion, and (f) very long-period ground motion)(b) Short-period vibrationis a phenomenon in which sound is heard through the air,"Go" or "Dawn"and so on.
Often heard from near the epicenter.
Shattered earthquakes and swarms of earthquakes often cause rumblings, and during the Matsushiro swarm earthquakes, rumblings reminiscent of explosions have been observed.
In addition, the rumbling of the earth is often heard especially in areas with solid rocky ground, and in Japan, areas around Mt.
The rumbling of the earth can be heard even in very small earthquakes that people cannot feel.
Artificial Evolution Research Institute (AERI)https://www.aeri-japan.com/) provides as a national resilience solution, it is an optical remote sensing that applies quantum interference to monitor and quantitatively analyze changes in the shape of the ground surface in situ.MEGA Earthquake Prediction/Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts), it is possible to quantify and visualize the ground rumble, which is one of the important earthquake precursor phenomena (perspective anomalous phenomena), in real time and in situ, using quantum interference vector dynamic technology.
Kazuto Kamuro Ph.D. & Dr. Visiting Professor, Department of Physics, California Institute of Technology
MEGA Earthquake Prediction/Prediction System
Part 2
1.Example of conventional (current) earthquake prediction technology (1st conventional technology)as,
Terrain data (surface data) read from satellite photographs,
Location information (mainly the epicenter) from earthquake observation points (seismic intensity meters, seismometers, seismic observation devices such as electronic reference points),
Based on basic information such as earthquake scale (magnitude) information and GPS information,
Near-future earthquake occurrence (epicenter, seismic intensity, tsunami occurrence, expected damage, etc.)Knowledge and empirical knowledge of Japan Meteorological Agency staff and seismologists, statistical analysis of seismometer data,And it is about predicting (fortune-telling) by making full use of AI etc.
2. again,Example of the above prior art (second prior art)as,Applying the magnetotelluric method to detect anomalies in weak currents (earth currents) flowing underground near the epicenter from seismic observation stations (seismic intensity meters, seismographs, electronic reference points, and other seismic observation devices) There is also a prior art that predicts the occurrence of an earthquake with a probability of about 60% by monitoring .
3.Another example of the above prior art (third prior art)as,
(1) Pre-earthquake data, which is real physical data with strong correlation to earthquakes, collected from seismic observation points (seismic intensity meters, seismometers, seismic observation devices such as electronic reference points), etc.;
(2) Sensors and antennas detect electromagnetic waves radiated from weak currents (geoelectric currents) associated with micro-fractures near the epicenter from about one month before the occurrence of an earthquake.
①Earthquake precursor data from electromagnetic observation (real physical data with strong correlation to earthquakes),
(2) Correlation information extracted by integrating the results of statistical analysis of seismometer data
Based on
There are those that make full use of the knowledge and empirical knowledge of analysts and seismologists to predict (predict) the occurrence of earthquakes with a hit accuracy of about 60%.
4.In the above first to third conventional techniques,
Seismographs such as seismometers, seismometers, and electronic reference points are installed discretely and scatteredly at the epicenter and its surrounding areas in Japan, or electromagnetic waves radiated with the generation of electric currents (earth currents) are detected. It is difficult to accurately grasp the occurrence and growth of the epicenter because sensors and antennas are installed discretely, and earthquake precursor data is discretely sampled and used as basic information for predictor judgment.
Therefore, there is a problem that there is a limit to the earthquake sign angle.
That is, it is very difficult to achieve high prediction accuracy and accuracy because the earthquake precursor data is discretely sampled and used as basic data to detect the earthquake precursor and predict the earthquake.
5. Artificial Evolution Research Institute (AERI)https://www.aeri-japan.com/) is conducting research and developmentMEGA Earthquake Prediction/Prediction System (https://www.aeri-japan.com/megaearthquakefor),
Using artificial satellites, the constantly moving ground surface of the entire country of Japan, including the epicenter, can be captured in real time and continuously without being limited to the installation location of seismic observation equipment such as seismic intensity meters, seismometers, and electronic reference points. By continuing to observe in situ and continuous scanning, the AI in the system detects abnormal changes that can lead to earthquake precursors and predicts earthquakes.
So to speak, we carry out a “health checkup of the earth” every day and make predictions based on the results.
6. Earthquake prediction/prediction system developed by our laboratory (https://www.aeri-japan.com/megaearthquakeforecasts)teeth,Based on innovative and ultimate optical remote sensing technology (quantum interference type vector dynamic technology) that applies satellite optoelectronic engineering, which is completely different from the past (1st to 3rd conventional technologies), we have a strong correlation with earthquakes. Always collect (for example, collect once an hour) earthquake precursor data, which is real physical dataBy
① 24 hours a day,
(2) real-time and
③ Realize in situ observation,
The AI in the system realizes prediction and prediction of earthquake signs by AI that does not depend on human wave tactics and individual differences, variations, and irregularities in earthquake prediction judgments.
7. In the above remote sensing technology (quantum interference type vector dynamic technology) researched and developed by our office,Real physical data with strong correlation to "ground surface fluctuations" that was not possible in the pastof,
① 24 hours a day,
(2) real-time and
(3) Realizes in situ observation.
100% of the statistical methods that rely on the individual abilities of conventional experts and the Mahalanobis distance are excluded. By being able to add it to the earthquake prediction process, real-time and highly accurate earthquake predictions and predictions, such as an earthquake prediction accuracy rate of 95% or more, have been realized.
8. Our firm (https://www.aeri-japan.com/) researched and developed the aboveRemote Sensing Technology (Quantum Interference Vector Dynamic Technology)Then, instead of the statistical method using the Mahalanobis distance,Careful observation of crustal uplift and subsidenceis doing.
This is because subsidence of the earth's crust can lead to earthquakes.
For example, before the Great East Japan Earthquake, large subsidence was observed along the Pacific coast of the Tohoku region.
"Crust deformation with subsidence of the crust", which is representative of earthquake precursor data, which is real physical data that has a strong correlation with earthquakes, is measured by the above remote sensing technology (quantum interference vector dynamic technology) before a major earthquake. .
9. Even in the case of the so-called Kumamoto earthquakes, which occurred one after another in Kumamoto and Oita prefectures after 21:26 on April 14, 2016, the MEGA Earthquake Prediction and Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts) replaces the statistical method using the Mahalanobis distance with the above-mentioned remote sensing technology (quantum interference vector dynamic technology) to install earthquake observation equipment such as seismic intensity meters, seismometers, and electronic reference points. Because it scans all over Japan without being constrained by location,
about 6 months ago
(1) Together with the detection of signs of the epicenter of the Kumamoto earthquake,
(2) Abnormal changes and ground surface changes (abnormal vibrations, subsidence, etc.) that are likely to lead to earthquake precursors in the predicted epicenter and surrounding areas
is detected.
10. Specifically, ground surface subsidence changes and volcanic irregular vibration waveforms (earthquake motion) that are thought to be due to volcanic activity in the Aso eruption area, and ground surface changes that indicate earthquake precursors in the area around the Aso eruption area (subsidence ➡ uplift). It also detects irregular vibration waveforms (earthquake motion) and predicts the occurrence of earthquakes.
11. The MEGA Earthquake Prediction/Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts), instead of statistical methods using the Mahalanobis distance, the AI earthquake prediction system in the Minoh area of Osaka Prefecture, the Kyoto Kamo area of Kyoto Prefecture, and the Takarazuka area of Hyogo Prefecture, from about 4 months before the earthquake occurred, Detects earthquake precursor data, which is real physical data that has strong correlation with earthquakes, such as horizontal and vertical abnormal fluctuations and seismic motion, and issues warnings and calls for MEGA earthquake precursors and predictions.
12. Above, the Institute (https://www.aeri-japan.com/) was developed by
MEGA Earthquake Prediction/Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts).
(1)satellite optoelectronicsBased on this, optical remote sensing that monitors changes in the shape of the ground surface by applying quantum interference and collects and quantitatively analyzes earthquake precursor data, which is real physical data that has a strong correlation with earthquakes.
(2) Real-time quantification of tens of thousands of points of time variation, vibration, and acceleration of the ground surface shape (unevenness)"Vector dynamic technology" adoption.
(3) By using the above-mentioned quantum interference vector dynamic technology, it has a strong correlation with earthquakesAs earthquake precursor data, which is real physical data, not only displacement of the ground surface, fault formation, cracks, upheaval, and depression, but also the occurrence and accumulation of strain near the ground surface are quantified and visualized in real time 24 hours a day.Can.
(4)Full scan of Japan once an hour from satellite.
(5) Pre-earthquake data, which is real physical data strongly correlated with earthquakes (e.g. vertical and horizontal variations of the ground surface), on a scale of one day, one week, one month and one year.Continuous real-time observation.
(6) In addition to uplift/subsidence and horizontal displacement, earthquake precursor data, which is real physical data that has a strong correlation with earthquakes,Simultaneous real-time measurement of abnormal vibrations (earthquake precursor tremors) and ejected gas at observation pointsThen, instead of the statistical method using the Mahalanobis distance, the earthquake precursor AI in the system predicts the precursors of earthquakes and eruptions.
(7) Earthquake precursor data, which is real physical data with strong correlation to earthquakes, instead of statistical methods using Mahalanobis distance, instead of conventional satellite photographs and observation point measurements, which use human seas and static observations. to collect realRealization of dynamic real-time observation by laser-applied remote sensing.
(8) In addition to earthquake precursors,Possible to predict volcanic eruption signs.
(9) By this systemEconomic effect is at least 100 trillion yennot less than
(10) A revolutionary evolution can be brought about in predictions of earthquake signs and eruption signs that rely on conventional human knowledge.
Kazuto Kamuro Ph.D. & Dr. Visiting Professor, Department of Physics, California Institute of Technology
MEGA Earthquake Prediction/Prediction System
Part 3
Eruption prediction
1. Examples of conventional (current) earthquake prediction technology (first conventional technology) include topographic data (surface data) read from satellite photographs, seismic observation points (seismometers such as seismic intensity meters, seismometers, and electronic reference points) Based on basic information such as location information (mainly the epicenter), earthquake scale (magnitude) information, GPS information, etc. from It is just a prediction (prediction) using the knowledge and experience of people and seismologists, statistical analysis of seismometer data, AI, etc.
2. In addition, as an example of the above-mentioned prior art (second prior art), a seismic source can be detected from a seismic observation point (seismic intensity meter, seismometer, seismic observation device such as an electronic reference point) by applying the magnetotelluric method. There is also a conventional technology that predicts the occurrence of an earthquake with a probability of about 60% by monitoring anomalies in weak electric currents (earth currents) flowing through the ground near locations.
3. As another example of the above prior art (third prior art),
(1) Earthquake precursor data (perspective anomaly data), which is real physical data highly correlated with earthquakes, collected from seismic observation points (seismic intensity meters, seismometers, seismic observation devices such as electronic reference points), etc. as well as
(2) Sensors and antennas detect electromagnetic waves radiated from weak currents (geoelectric currents) associated with micro-fractures near the epicenter from about one month before the occurrence of an earthquake.
①Earthquake precursor data (perspective anomaly data) from electromagnetic observation (real physical data with strong correlation to earthquakes),
(2) Based on the correlation information extracted by integrating the results of statistical analysis of seismometer data, we make full use of the knowledge and empirical knowledge of analysts and seismologists to predict the occurrence of earthquakes with a hit accuracy of about 60%. (Fortune-telling) There is something about it.
4. In the above first to third prior arts, seismic observation devices such as seismic intensity meters, seismographs, and electronic reference points are installed discretely and scatteredly in the epicenter and its surrounding areas in Japan, or electric currents (earth currents) Sensors and antennas are installed discretely to detect the electromagnetic waves radiated with the occurrence of an earthquake. It is difficult to grasp the occurrence and growth.
Therefore, there is a problem that there is a limit to the earthquake sign angle.
In other words, earthquake precursor data (perspective anomaly data) are discretely sampled and used as basic data to detect earthquake precursors and predict earthquakes, making it extremely difficult to achieve high prediction accuracy and accuracy. .
5. Artificial Evolution Research Institute (AERI) as a national resilience solutionhttps://www.aeri-japan.com/) is researching and developing the MEGA earthquake prediction/prediction system (https://www.aeri-japan.com/megaearthquakefor) uses artificial satellites to continuously monitor the constantly moving ground surface of Japan, including the epicenter, in real time without being limited to the installation locations of seismic observation devices such as seismometers, seismometers, and electronic reference points. By continuously observing the whole system in situ and continuously scanning, the AI in the system detects abnormal changes that can lead to earthquake precursors and predicts earthquakes.
so to speakDaily “Earth Health Checkups” and predictions based on the resultsis doing.
6. Earthquake prediction/prediction system (https://www.aeri-japan.com/megaearthquakeforecasts) is completely different from the conventional technologies (1st to 3rd conventional technologies), and is based on innovative and ultimate optical remote sensing technology (quantum interference type vector dynamic technology) that applies satellite optoelectronic engineering as a core technology. By constantly collecting (for example, once an hour) earthquake precursor data (perspective anomaly data), which is real physical data with strong correlation,
① 24 hours a day,
(2) real-time and
③ Realization of in situ observationHowever, the artificial intelligence program in the system realizes prediction and prediction of earthquake signs that does not depend on human wave tactics, the knowledge and intuition of experts in earthquake prediction judgment, individual differences, variations, irregularities, etc.
7. The above-mentioned remote sensing technology (quantum interference type vector dynamic technology) researched and developed by our office has a strong correlation with "changes in the earth's surface" that was not possible in the past.real physical data,
(1) 24 hours a day, (2) real time, and (3) in situ observation.
100% of the statistical methods that rely on the individual abilities of conventional experts and the Mahalanobis distance are eliminated. By being able to participate in the earthquake prediction process,Earthquake prediction accuracy rate of 95% or moreReal-time and highly accurate earthquake predictions and predictions have been realized.
8. MEGA Earthquake Prediction/Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts), which is the core technology of the above-mentioned remote sensing technology (quantum interference type vector dynamic technology), instead of the statistical method using the Mahalanobis distance, we carefully observe the uplift and subsidence of the crust.
This is because subsidence of the earth's crust can lead to earthquakes.
For example, before the Great East Japan Earthquake, large subsidence was observed along the Pacific coast of the Tohoku region.
The above remote sensing technology (quantum interference vector dynamic technology), which is a representative of earthquake precursor data (perspective anomaly data), which is real physical data that has a strong correlation with earthquakes, is used before a major earthquake. ) has been measured in situ.
9.The so-called Kumamoto earthquake that occurred in Kumamoto and Oita prefectures after 21:26 on April 14, 2016Even in the case ofhttps://www.aeri-japan.com/megaearthquakeforecasts), the AI earthquake prediction system in ) installs seismic observation equipment such as seismic intensity meters, seismographs, and electronic reference points using the above remote sensing technology (quantum interference vector dynamic technology) instead of the statistical method using the Mahalanobis distance. Because we were scanning all over Japan 24 hours a day in situ (satellite laser application remote sensing) without being constrained by location,about 6 months agofrom
(1) Together with the detection of signs of the epicenter of the Kumamoto earthquake,
(2) Detecting abnormal changes and ground surface changes (abnormal vibrations, subsidence, etc.) that are likely to lead to earthquake precursors in the predicted epicenter and its surrounding areas.
10. Specifically, ground surface subsidence changes and volcanic irregular vibration waveforms (earthquake motion) that are thought to be due to volcanic activity in the Aso eruption area, and ground surface changes that indicate earthquake precursors in the area around the Aso eruption area (subsidence ➡ uplift). And the irregular vibration waveform (earthquake motion) is detected in situ in real time without time delay to predict earthquake occurrence.
11.Northern Osaka earthquake on June 18, 2018(Earthquake scale Mj6.1, epicenter depth 13km, maximum seismic intensity 6 lower), the MEGA earthquake prediction/prediction system (https://www.aeri-japan.com/megaearthquakeforecasts) replaces the statistical method using the Mahalanobis distance, the AI earthquake prediction system in the Minoh area of Osaka Prefecture, the Kyoto Kamo area of Kyoto Prefecture, and the Takarazuka area of Hyogo Prefecture.From about 4 months before the earthquake, we will collect in situ earthquake precursor data (perspective anomaly data), which is real physical data that has a strong correlation with earthquakes, such as abnormal horizontal and vertical changes in the ground surface and seismic motion. Detects and issues warnings and calls for MEGA earthquake signs and predictions.
12. The Institute (https://www.aeri-japan.com/) developed by MEGA Earthquake Prediction/Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts).
(1) Based on satellite optoelectronic engineering, monitor changes in the ground surface shape by applying quantum interference, and collect in situ earthquake precursor data (perspective anomaly data), which is real physical data that has a strong correlation with earthquakes.・Optical remote sensing for quantitative analysis.
(2) "Vector data group" that constantly quantifies earthquake precursor data groups (general perspective anomaly data groups) such as time variation of ground surface shape (unevenness), vibration, acceleration, etc. in situ and in real time at a rate of 10K to 100G points/minute Uses dynamic technology.
(3) By using the above-mentioned quantum interference vector dynamic technology, earthquake precursor data (perspective anomaly data), which is real physical data that has a strong correlation with earthquakes, can be generated as displacement of the ground surface, fault formation, cracks, and upheaval. , It is possible to quantify and visualize not only the collapse but also the occurrence and accumulation of distortion near the ground surface in real time and in situ 24 hours a day.
(4) From the satellite, all of Japan's earthquake occurrence prediction point group ● is scanned once every hour.
(5) Earthquake precursor data (perspective anomaly data), which are real physical data strongly correlated with earthquakes (for example, vertical and horizontal variations of the ground surface, etc.), are collected for one day, one week, one month, Continuous real-time, in situ observation on a yearly scale.
(6) As earthquake precursor data (perspective anomaly data), which is real physical data that has a strong correlation with earthquakes, in addition to uplift/subsidence and horizontal displacement, abnormal vibrations at observation points (earthquake precursor tremors) and ejected gas At the same time, real-time measurements are taken, and instead of the statistical method using the Mahalanobis distance, the earthquake precursor AI in the system predicts the precursors of earthquakes and eruptions.
(7) Reality with strong correlation to earthquakes instead of statistical methods using Mahalanobis distance, instead of the personal views of experts, human seas and static observations such as conventional satellite photos and observation point measurements. Realizing dynamic real-time observation by laser application remote sensing that actually collects earthquake precursor data (perspective anomaly data), which is physical data.
(8) In addition to earthquake predictions, parallel/coordinated prediction of volcanic eruption predictions is possible.
(9) The economic effect of this system will not be less than 100 trillion yen.
(10) A revolutionary evolution can be brought about in predictions of earthquake signs and eruption signs that rely on conventional human knowledge.
Kazuto Kamuro Ph.D. & Dr. Visiting Professor, Department of Physics, California Institute of Technology
Satellite-based eruption warning/prediction system
§1 Prediction and prediction of signs of volcanic eruptions
1. [Precursor phenomenon of eruption]
(1) In general, volcanic eruptions are accompanied by precursors. The general process of a volcanic eruption is that magma at the foot of a volcano accumulates in a magma chamber 1 to 10 km underground, then rises from there and moves to the surface. This accumulation and movement of magma is the source of eruption precursor phenomena.
(2) Volcanic earthquakes, which are precursors of the first eruption, occur when magma breaks and intrudes into the bedrock. If the epicenter gradually becomes shallower, it is thought that the eruption time is approaching. If there is a place where the epicenter is concentrated, the probability that an eruption can occur there is considerably high. Many volcanic eruptions are seen months to hours before the eruption.
(3) Volcanic tremors, which are precursors of the second eruption, are low-frequency vibrations with a longer vibration period than volcanic earthquakes. In addition, the duration of vibration is long, and it has the characteristics of continuous vibration. Volcanic tremors are thought to be caused by pressure build-up in magma chambers and movement of magma.
(4) The third prelude to eruptions, “changes in topography,” occurs when magma rises to shallow depths as the volcanic edifice suddenly rises, slopes steeply, and cracks in the ground. If there is a significant change in topography, an eruption is likely to occur there.
(5) Other premonitory phenomena of eruption include the following.
(1) Electromagnetic anomalies: Earth currents, geomagnetism, abnormal changes in underground electrical resistance, etc.
(2) Abnormal phenomena of heat: Abnormal rise in groundwater temperature, etc.
(3) Abnormal phenomenon of volcanic gas (volcanic plume): Abnormal changes in the composition and emission amount of volcanic gas, emission temperature, etc.
2. [Current status and issues]
[1] Current status of prediction of volcanic eruption
Current signs and predictions of volcanic eruptions refer to predicting signs such as the timing, place, and style of eruptions in advance to some extent in order to mitigate disasters caused by volcanic eruptions. By accumulating precursor data of past volcanic eruptions, an observation system using various high-precision observation devices such as seismometers, inclinometers, and extensometers was developed. can be predicted to some extent.
[2] Prediction and prediction of volcanic eruption signs: Current status and issues
(1) In order to evacuate and prevent disasters and prevent damage from becoming more serious, it is necessary to ensure that sufficient time is required from the time the occurrence of precursory phenomena and the issuance of an eruption warning to the actual eruption, which serves as the basis for “prediction and prediction of signs of volcanic eruptions.” Securing a grace period for evacuation is an issue (difficulty in issuing warning timing). There is a problem (first problem) that it is more difficult to foresee and forecast volcanic eruption signs and issue early eruption warnings for "insignificant eruptions" such as steam explosions that do not involve eruption precursors or magma ejections.
(2) Issues in prediction and prediction of signs of volcanic eruptions for "significant eruptions" as well, such as the need for greater precision and accuracy with respect to eruption patterns and transitions in eruptive activity, as well as the need for early and optimized warnings (Part 2 problem).
(3) Many cases of volcanic eruptions are accompanied by precursors that have a clear causal relationship with the eruption. However, it is difficult to predict (1) the start of an eruption, (2) how the activity will change after that, (3) whether another large eruption can occur (difficulty in activity transition), and (4) when it will end. There is also a problem that prediction is difficult (difficulty in predicting the end of the crisis). On the other hand, there is a problem (the third problem) that the causal relationship between earthquakes and phenomena that are considered precursors is not clear.
(4) The “declaration of the end” of volcanic eruptions cannot be made with a carefree judgment and overlooked the danger that will cause casualties. often continue. Since an eruption lasts for a few days at the shortest and several years at the longest, in some cases the warning will be continued for several years (difficulty in the warning period). The social and economic impact of the evacuation of residents and traffic restrictions will also last for a long time, and this is a major issue (fourth issue) in tourist areas near volcanoes.
(5) In addition, even if an increase in activity is confirmed due to precursory phenomena of an eruption, and even if an alarm is issued, an eruption does not occur and the activity continues to decline, often resulting in a "failure" (Problem 5). ).
[3] Current status of volcanic eruption monitoring system
Currently, government agencies, universities, and researchers in municipalities, prefectures, and municipalities with volcanoes are using human-wave tactics to install various types of seismometers, inclinometers, and extensometers scattered (fixed-point installations) in volcano warning areas. Eruptions are monitored through instrumental observations using high-precision observation equipment and field observations by humans. In Japan, there are about 30 active volcanoes that are judged to require special attention, and the Japan Meteorological Agency, universities and other research institutes have established observatories and are constantly observing them. These volcano observation areas are covered by observations of upheaval and ground temperature by GPS installed scattered, as well as regular seismic observations, but the density and number of observations made by the observation equipment is completely insufficient, and the accuracy of the observation equipment is insufficient.・There is a problem that accuracy and speed are lacking. In addition, even if an anomaly is detected, there is a problem that there is no other way but to take a slow response such as dispatching an observation team to the installation location of the observation device that detected the anomaly (problem 6).
§2 Satellite-based eruption prediction/prediction system
1. Overview
(1) The femtosecond laser, which is the light source of the satellite-mounted eruption prediction/prediction system, which is a solution for national resilience and a solution for realizing sustainable social infrastructure, is used by the satellite-mounted MEGA earthquake prediction/prediction system (https:// www.aeri-japan.com/megaearthquakeforecasts ), as well as anti-fighter aircraft and Ultra-high-power laser common to next-generation interceptor laser systems for anti-missile and anti-ICBM (AERI/HEL surface-to-air defense system/missile defense system https://www.aeri-japan.com/anti-icbm-interceptor-lasersystem) (HEL) module is used.
(2) The Artificial Evolution Research Institute (AERI https://www.aeri-japan.com/) has a wide range of ultra-high energy lasers (AERI/HEL technology), including soft X-rays, ultraviolet regions, visible light rays, and far infrared regions. It can extract light of any wavelength, and the output can be arbitrarily selected up to over MW (megawatt). At our office (https://www.aeri-japan.com/), we are also conducting research aimed at practical application in the field of military weapons as an important application of the ultra-high energy laser (AERI/HEL technology).
(3) The above ultra-high energy laser (AERI/HEL technology) as the light source for the satellite-mounted eruption prediction/prediction system has a super power of over 50 MW, a spatial resolution of 10 square μm to 10 square mm, and a variable wavelength ultraviolet light. Any wavelength in the mid-infrared region can be selected, and ultra-short pulses with high resolution and high temporal resolution such as ultra-short pulse widths of CW to femtoseconds (about 10 fs) can be arbitrarily generated at ultra-long distances of about 200 km. .
2. Optional equipment for eruption prediction
(1) The satellite-mounted eruption prediction/prediction system can be equipped with a volcanic tremor detection laser remote sensing module] and a volcanic eruption gas detection infrared (IR) spectroscopic/FT-IR spectroscopic laser remote sensing module].
(2) [Volcanic tremor detection laser remote sensing module]
Artificial Evolution Research Institute (AERI https://www.aeri-japan.com/) provides satellite-mounted MEGA earthquake prediction and prediction as a solution for national resilience, global warming prevention, and sustainable social infrastructure. The system (https://www.aeri-japan.com/megaearthquakeforecasts) is an eruption prediction satellite optoelectronic engineering technology that detects volcanic tremors and has a strong correlation with eruptions by applying quantum interference vector dynamic technology. Volcanic tremors, which are one of the precursor phenomena of eruptions, which are real physical data, are constantly collected (for example, once an hour) as eruption precursor data (perspective anomaly data). And (3) the volcanic tremor detection laser remote sensing module, which is a laser remote sensing technology for in situ observation, is installed as standard.
(3) [Optional equipment: Infrared (IR) spectroscopy/FT-IR spectroscopy laser remote sensing module for detecting volcanic eruption gas]
The satellite-mounted MEGA Earthquake Prediction/Prediction System (https://www.aeri-japan.com/megaearthquakeforecasts) has a strong correlation with eruptions as an eruption prediction satellite optoelectronic engineering technology that detects volcanic eruption precursor gases. As eruption precursor data (perspective anomaly data), which is one of the precursor phenomena of an eruption, which is real physical data, in addition to water vapor and carbon dioxide, which are the main components, sulfur dioxide (sulfurous acid gas), hydrogen sulfide and hydrogen chloride By constantly collecting various volcanic eruption precursor gases (for example, once an hour), satellite optoelectronic engineering application volcanic eruption gas detection infrared (IR) spectroscopy/FT-IR spectroscopy laser remote sensing module can be installed as an option.
3. Detection, prediction, and prediction of eruption precursors
(1) In the satellite-mounted MEGA earthquake prediction/prediction system (https://www.aeri-japan.com/megaearthquakeforecasts), quantum interference vector dynamic technology and the optional laser remote sensing module for detecting volcanic tremors The above volcanic tremor information, which is eruption precursor data (pervasive anomaly data) remotely sensed by , and the optional volcanic eruption gas detection infrared (IR) spectroscopy / FT-IR spectroscopy laser remote sensing module remotely sensed Using the two types of volcanic eruption precursor gas information, which is eruption precursor data (perspective anomaly data), the artificial intelligence program in the system uses human wave tactics and eruption prediction judgment specialist knowledge and intuition, individual differences and Realizes 24-hour, real-time, in-situ prediction and prediction of eruption signs that do not depend on variations and unevenness.
(2) By installing the satellite optoelectronics applied infrared (IR) spectroscopy/FT-IR spectroscopy laser remote sensing module, water vapor (HO), hydrogen fluoride (HF), hydrogen chloride (HCl), sulfur dioxide ( SO2), hydrogen sulfide (H2S), carbon dioxide (CO2), hydrogen (H2), nitrogen (N2), carbon monoxide (CO), methane (CH4) and other volcanic eruption gases (1) 24 hours a day, (2) real time, and (3) in situ observation is feasible. By installing (installing) the satellite optoelectronics application infrared (IR) spectroscopy/FT-IR spectroscopy laser remote sensing module as an option, the concentration of carbon dioxide, methane, and water vapor (e.g., column mean concentration) can be estimated.
4. Functions of the eruption warning/prediction system
(1) MEGA Earthquake Prediction/Prediction System (https://www.aeri-japan.com/megaearthquakefor) In addition to using the quantum interference vector dynamic module used for earthquake prediction, volcanic tremor laser remote sensing It is possible to predict and forecast modules and volcanic eruption signs.
(2) "MEGA Earthquake Prediction/Prediction System" (https:/ /www.aeri-japan.com/megaearthquakeforecasts), in addition to the volcanic tremor detection laser remote sensing module (equipped with the first option) that applies quantum interference vector dynamic technology, which is the basic module, volcanic eruption gas detection By installing an infrared (IR) spectroscopy / FT-IR spectroscopy laser remote sensing module (equipped with the second option), we can detect changes and fluctuations in the ground surface, one of the precursors of volcanic eruptions, using quantum interference. It is a laser applied remote sensing that is applied and numerically analyzed, and it is a satellite laser applied remote sensing (satellite optoelectronic engineering applied technology) that monitors the whole of Japan on a 24-hour basis and performs quantitative analysis.
(3) “MEGA Earthquake Prediction/Prediction System” (https://www.aeri-japan.com/megaearthquakeforecasts): (Displacement of the ground surface, fault formation, cracks, upheaval, and subsidence, as well as the occurrence and accumulation of distortions near the ground surface); It is digitized and visualized in real time and in situ.
(b) Detection of volcanic eruption gas by infrared (IR) spectroscopy/FT-IR spectroscopy laser remote sensing module (3) Changes and fluctuations in the type and concentration of erupting gas, (c) Detected by satellite optoelectronic infrared sensors (4) Quantitatively analyze changes and fluctuations in the ground surface temperature as precursors of volcanic eruptions. By default, 24-hour, real-time, in situ observation of vertical and horizontal variations of the ground surface on a scale of 1 day, 1 week, 1 month, and 1 year.
(4) In addition to uplift/subsidence and horizontal displacement, abnormal vibrations (earthquake precursor tremors) and ejected gas are simultaneously measured in real time to predict earthquake precursors. In other words, the volcanic micro-laser remote sensing module detects precursor phenomena of eruptions such as vibration and acceleration in addition to time displacement of ground surface changes and fluctuations (unevenness), 24 hours a day, 2) in real time, and 3) in situ. Digitize by 10,000 points.
Specifically, (1) displacement of the ground surface, fault formation, cracks, upheaval, subsidence, generation and accumulation of distortion near the ground surface, etc. (1) changes and fluctuations in the shape of the ground surface, and (2) ground surface vibration (earth rumbling) The volcanic micro-laser remote sensing module measures changes and fluctuations in the volcanic eruption with an accuracy of several millimeters. Volcanic eruption gas detection with an accuracy of several ppm Infrared (IR) spectroscopy / FT-IR spectroscopy Laser remote Sensing modules (3) (4) Precursor phenomena of volcanic eruptions with an accuracy of 0.1°C for changes and fluctuations in ground surface temperature. It is possible to digitize and visualize the volcanic area in real time at a pitch of several mm to several meters in situ for 24 hours.
(5) As a result, in addition to predicting earthquakes, dynamic real-time observations using artificial satellite laser application remote sensing (satellite optoelectronic engineering application technology) will be possible, instead of conventional satellite photography and observation point measurement, which are human seas and static observations.・Prediction of signs of volcanic eruption by in situ observation. The economic effect of this system will not be less than 100 trillion yen. It can bring about a revolutionary evolution in the prediction of earthquake signs and eruption signs that rely on conventional human knowledge.
5. Effects of this system
(1) Effect 1: By implementing a quantum interference vector dynamic module and a volcanic tremor detection laser remote sensing module, it is possible to "predict and predict signs of volcanic eruptions" for evacuation and disaster prevention actions and to prevent damage from becoming more serious. It is possible to secure a sufficient evacuation grace period from the issuance of an eruption warning to the actual eruption (solution of the issue of warning issuance timing). In addition, by installing infrared (IR) spectroscopy and FT-IR spectroscopy laser remote sensing modules, it is possible to predict and predict volcanic eruption precursors for "unmarked eruptions" such as steam explosions that do not involve eruptions or magma eruptions. and issuance of early eruption warning becomes easier.
(2) Effect 2: Prediction and forecasting of signs of volcanic eruptions for "significant eruptions" will also be possible to further improve the accuracy and accuracy of eruption patterns and changes in eruptive activity, and to advance and optimize warnings. .
(3) Effect 3: From satellites, together with GPS/GLONASS information, volcanic eruption precursor data is digitized and digitized in real time in situ at a pitch of several millimeters to several meters for volcanic areas scattered throughout the country, 24 hours a day. Since eruption predictions and forecasts are performed using visualization, it is possible to predict (1) not only the start of an eruption, but also (2) how activity will change after that, and (3) whether another large eruption is likely to occur. gender resolution). And (4) it becomes easy to predict when it will end (solving the difficulty of predicting the end). AI can quantify the causal relationship between eruptions and phenomena that are considered precursors and objectively judge them.
(4) Effect 4: The “declaration of the end” of volcanic eruptions cannot be overlooked and cause casualties with an easy decision. It will be possible to continue long-term warnings and warnings for eruptions, which often continue to be issued for a period of time (solution of the difficulty of the warning period). It will be possible to minimize the social and economic impact of tourist spots near volcanoes, evacuation of residents, and traffic restrictions.
(5) Effect 5: It is possible to solve the "missing" problem of the alarm. In other words, it is possible to solve the problem that even if an increase in activity is confirmed by a precursory phenomenon of an eruption and an alarm or the like is issued, an eruption does not occur and the activity continues to decline.
§3 Summary
(1) Artificial Evolution Research Institute (AERI https://www.aeri-japan.com/) satellite-mounted MEGA earthquake prediction/prediction system (https://www.aeri-japan.com/megaearthquakeforecasts) Realizes revolutionary advances in the volcanic eruption monitoring system, which enables 24-hour, real-time, in-situ digitization and visualization of volcanic eruptive gas emission detection points for quick and accurate response. become able to.
(2) Conventionally, government agencies, universities, and researchers in municipalities of prefectures and municipalities that have volcanoes have used man-wave tactics to install seismometers and inclinometers (fixed points) in volcano warning areas. Eruptions are monitored through instrumental observations using various high-precision observation devices called extensometers, and through field observations by humans. In Japan, there are about 30 active volcanoes that are judged to require special attention, and research institutes such as the Japan Meteorological Agency and universities have established observatories and are constantly observing them. These volcano observation areas are covered by observations of upheaval and ground temperature by GPS installed scattered, as well as regular seismic observations, but the density and number of observations made by the observation equipment is completely insufficient, and the accuracy of the observation equipment is insufficient.・There was a problem of lack of accuracy and speed. This satellite-mounted MEGA earthquake prediction/prediction system (https://www.aeri-japan.com/megaearthquakeforecasts) is an innovative technology that can solve this problem.
(3) As mentioned above, "MEGA Earthquake Prediction/prediction system” (https://www.aeri-japan.com/megaearthquakeforecasts) is currently being used by government agencies, universities, and researchers to prevent volcanoes by using human wave tactics in each prefecture and municipality that has a volcano. The eruption is monitored through instrumental observation using various high-precision observation devices such as seismometers, tiltmeters, and extensometers scattered (fixed-point installation) in the warning area, as well as manual on-site observation. In Japan, there are about 30 active volcanoes that are judged to require special attention, and the Japan Meteorological Agency, universities and other research institutes have established observatories and are constantly observing them. These volcano observation areas are covered by observations of upheaval and ground temperature by GPS installed scattered, as well as regular seismic observations, but the density and number of observations made by the observation equipment is completely insufficient, and the accuracy of the observation equipment is insufficient.・There is a problem that accuracy and speed are lacking. Also, even if an anomaly is detected, there is no other way but to take a slow response, such as dispatching an observation team to the installation location of the observation equipment that detected the anomaly. become able to.
that's all
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Remarks: Infrared spectroscopy
1. 【Overview】
1. Infrared spectroscopy (abbreviated as IR) When a molecule is irradiated with light in the infrared region of 0.8 to 1000 μm, if the vibration period of the infrared rays and the vibration period of the atoms match, individual atoms and atomic groups It absorbs energy according to the period, and the vibration changes from the ground state to the excited state. This absorption appears as absorption in the infrared spectrum. A method of obtaining knowledge about molecular structures by analyzing absorption spectra, since atoms have unique vibrations according to their molecular structures. The most commonly used is the mid-infrared region (2.5-25 μm), where absorption spectra are vibrational spectra caused by vibrations involving changes in the dipole moment among other molecular vibrations. It is used to know the molecular structure and state of the object.
2. When a substance is irradiated with infrared rays, the molecules that make up the substance absorb the energy of the light, and the state of quantized vibration or rotation changes. Therefore, the infrared rays transmitted through (or reflected by) a certain substance are weaker than the irradiated infrared rays by the energy used for the state transition of the molecular motion. By detecting this difference, the energy absorbed by the molecule, in other words, the energy required to excite the vibration and rotation of the target molecule can be obtained.
3. The energy required to excite the vibration and rotation of a molecule varies depending on the chemical structure of the molecule. Therefore, the infrared absorption spectrum obtained by plotting the wave number of the irradiated infrared rays on the horizontal axis and the absorbance on the vertical axis shows a shape unique to the molecule. This makes it possible to know what kind of structure a target substance has, and is often used to determine the structure of organic compounds in particular. In the spectrum, the portion with a wavenumber of 1500 cm-1 or more is called the diagnostic region, and the other portion is called the fingerprint region. The former results from vibrational excitation of single bonds, while the former binds double bonds, triple bonds and hydrogen atoms. Also, even for the same molecule, the infrared spectrum changes slightly depending on the temperature and surrounding conditions (whether it is moving freely, whether it is adsorbed on a surface, etc.). From this, it is possible to know the surface structure of the substance.
2. [Method]
Infrared spectroscopy includes (1) thermal infrared spectroscopy (TIR), (2) near-infrared spectroscopy (NIRS), and (3) FTIR (Fourier transform infrared spectroscopy). There are methods such as
1. Thermal infrared spectroscopy (TIR)
TIR is a type of infrared spectroscopy that is widely used to determine the composition of matter. The constituent materials can be determined by measuring the thermal infrared radiation emitted from the entire object or surface, analyzing its electromagnetic spectrum, and comparing it to the spectra of known materials.
2. near-infrared spectroscopy (NIRS)
NIRS is a spectroscopic method in the near-infrared region. Equipped with a near-infrared diffuse reflectance spectrum analysis function that irradiates the measurement target with near-infrared rays and calculates the components from changes in absorbance. As a feature, absorption of near-infrared rays is extremely small compared to mid-infrared rays and far-infrared rays, so non-destructive and non-contact measurement can be performed without preparing sections.
Difficulties for practical use include the observation of overtones and triple overtones with near-infrared spectroscopy, and the difficulty of direct association with components due to the combination of various factors in light absorption. there were. However, due to the low cost of computers and the development of multivariate analysis (chemometrics), it has become possible to apply it to quantitative analysis.
3. FTIR (Fourier Transform Infrared Spectroscopy)
FTIR is IR (infrared spectroscopy) in which the FTIR principle is applied (signals are recorded in the time domain and then Fourier transformed into the frequency domain). FTIR does not irradiate the sample with infrared rays of varying wavelengths, but rather irradiates the sample with continuous light and Fourier transforms the interference pattern to acquire an absorption spectrum corresponding to the molecular structure, and to identify the atomic groups ( method of obtaining information on The ability to simultaneously measure incident light over the entire wavenumber range of continuous light enables high-sensitivity measurements in a short period of time.
FTIR has transmission reflection method and measurement method. Permeation methods include the KBr tablet method, the Nujol method, the KBr plate method, the thin film method, the liquid film method, the solution method, and the gas measurement method. Reflection methods include the ATR method, the diffuse reflection method, the regular reflection method (regular reflection light), the regular reflection method (transmission reflection light), the high sensitivity reflection (RAS) method, and the like.