JP2007198813A - Seismograph - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a seismograph which accurately provides the seismic intensity of an earthquake by clearly distinguishing vibrations caused by the earthquake from vibrations attributed to causes other than the earthquake. <P>SOLUTION: The seismograph 1 comprises: a detection section 2 for detecting information on vibrations; and an arithmetic section 3 which is electrically connected to the detection section 2 and calculates seismic intensity on the basis of the information on the vibrations detected by the detection section 2. The seismograph 1 comprises a plurality of detection sections 2a to 2f. When a difference among the information on the vibrations detected by the detection sections 2a to 2f is within a predetermined range, the detected information on the vibrations is judged to be caused by an earthquake. The arithmetic section 3 calculates the seismic intensity of the earthquake on the basis of the information on the vibrations detected by the detection sections 2. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a seismometer that detects an earthquake and calculates its intensity.

  In recent years, when a house is damaged by an earthquake, it is necessary to collect various data related to earthquakes such as seismic intensity and acceleration in order to determine how much damage has been applied to the house. It is desirable to install. In addition, there is a demand for householders to know data relating to earthquakes when an earthquake occurs, and seismometers for ordinary houses are required.

For example, Patent Document 1 below discloses a seismometer (seismic intensity meter) that can be easily installed in a general house by downsizing.
JP 2003-302473 A

  However, with conventional seismometers, when a person is installed in a building and used, the person simply walks near the seismometer, and the vibration is detected as acceleration. Could not be distinguished. For this reason, accurate data on the earthquake could not be obtained, and it was difficult to accurately grasp the damage caused by the earthquake.

  Therefore, an object of the present invention is to provide a seismometer that can clearly distinguish the seismic intensity of the earthquake by clearly distinguishing the vibration caused by the earthquake and the vibration caused by a cause other than the earthquake.

  In order to solve the above-described problem, in the invention of claim 1, a detection unit that detects information related to vibration, and the detection unit is electrically connected to the detection unit, and the seismic intensity is detected based on the information related to vibration detected by the detection unit. In the seismometer having a calculation unit in which the calculation is performed, the seismometer includes a plurality of detection units, on the condition that the difference in information regarding vibration detected by each detection unit is within a predetermined range, The information on the detected vibration is determined to be due to an earthquake, and the calculation unit calculates the seismic intensity of the earthquake based on the information on the vibration detected by each detection unit. .

  Thus, in the seismometer according to the first aspect of the present invention, when the same vibration-related information is detected by all the detection units, it is determined that the vibration is a vibration due to an earthquake. In addition, when vibration-related information is detected by only a part of the detection units, or when the magnitude of information regarding the vibration detected by each detection unit is different, it is determined that the vibration is caused by a cause other than an earthquake. . For this reason, the vibration caused by the earthquake and the vibration caused by a cause other than the earthquake are clearly distinguished, and the seismic intensity of the earthquake can be accurately grasped.

  Here, in general, in the vibration due to an earthquake, the acceleration in the horizontal direction is larger than the acceleration in the vertical direction. Accordingly, the invention of claim 2 provided on the basis of such knowledge is that, in the invention of claim 1, the detection unit detects the acceleration in the vertical direction and the acceleration in the horizontal direction, and is detected by the detection unit. The information on the detected vibration is due to an earthquake, provided that the horizontal acceleration is greater than the vertical acceleration by comparing the vertical acceleration and the horizontal acceleration magnitude. It was judged that.

  Thereby, it is clearly determined whether the information about the vibration detected by the detection unit is due to an earthquake or a cause other than an earthquake, and the seismic intensity of the earthquake can be accurately grasped.

  Moreover, in the vibration caused by an earthquake, a horizontal acceleration component (S wave) is detected after detection of a vertical acceleration component (P wave). Accordingly, the invention of claim 3 provided on the basis of such knowledge is that, in the invention of claim 1 or claim 2, the detection unit detects the acceleration in the vertical direction and the acceleration in the horizontal direction. On the condition that the horizontal acceleration is detected after the direction acceleration is detected, the information on the detected vibration is judged to be due to an earthquake.

  Thereby, it is determined whether the information on the vibration detected by the detection unit is due to an earthquake or a cause other than an earthquake, and the seismic intensity of the earthquake can be accurately grasped.

  In the vibration caused by an earthquake, vibration having a predetermined frequency (for example, 0.5 Hz) or more continuously occurs. Accordingly, the invention of claim 4 provided based on such knowledge is detected in the inventions of claims 1 to 3 on the condition that acceleration of a predetermined frequency or higher is continuously detected for a certain period or longer. It is characterized that the information on vibration is judged to be due to an earthquake.

  Thereby, it is determined whether the information on the vibration detected by the detection unit is due to an earthquake or a cause other than an earthquake, and the seismic intensity of the earthquake can be accurately grasped.

  According to a fifth aspect of the present invention, in the first to fourth aspects of the present invention, the plurality of detection units are respectively installed at different locations in the building.

  As a result, even when a seismometer is installed in a building such as a house, it is possible to determine with high accuracy whether the information about the detected vibration is due to an earthquake or a cause other than an earthquake. .

  The seismometer of the present invention can clearly distinguish vibrations caused by earthquakes from vibrations caused by causes other than earthquakes. Therefore, by using the seismic intensity meter according to the present invention, it is possible to accurately grasp the seismic intensity based on the information related to the vibration caused by the earthquake.

  FIG. 1 is a block diagram of a seismic intensity meter 1 according to the present embodiment, and FIG. 2 is a diagram showing an installation state of the seismic intensity meter 1 according to the present embodiment. As shown in FIG. 1, a seismometer 1 according to the present embodiment includes a detection unit 2 that detects an earthquake, a calculation unit 3 that calculates a seismic intensity, a storage unit 5 that stores various data related to the earthquake, a calculated seismic intensity, and the like. A display unit 6 for displaying various data is provided. As shown in FIG. 2, a plurality of detection units 2 are installed at different locations in a building 11 such as a house. In the present embodiment, it is assumed that one building 11 in which a plurality of detection units 2 are installed is a unit.

  The detection unit 2 includes an acceleration sensor 7 capable of detecting acceleration due to vibration, an A / D conversion circuit 8 that converts an analog signal output from the acceleration sensor 7 into a digital signal, and the converted digital signal to the calculation unit 3. It comprises a wired or wireless communication unit 10 for communication.

  The acceleration sensor 7 is a semiconductor acceleration sensor, and can detect accelerations in the X, Y, and Z axis directions orthogonal to each other. For example, a piezoresistive type or a capacitance type can be used. When acceleration due to vibration is applied to the acceleration sensor 7, the acceleration data is output as an electrical signal at a voltage level corresponding to the magnitude of the acceleration.

The electrical signal output from the acceleration sensor 7 is converted into a digital signal by the A / D conversion circuit 8 and input to the arithmetic unit 3 via the communication unit 10, and all the following conditions (1) to (4) are satisfied. When satisfied, it is determined that the acceleration detected by the detection unit 2 is caused by an earthquake.
(1) The difference in acceleration detected by the plurality of detection units 2 is within a predetermined range.
(2) The acceleration in the horizontal direction is larger than the acceleration in the vertical direction.
(3) After the acceleration in the vertical direction is detected, the acceleration in the horizontal direction is detected.
(4) An acceleration of a predetermined frequency or higher is continuously detected for a certain period or longer.

  More specifically, the acceleration sensor 7 used in the detection unit 2 detects not only the acceleration due to an earthquake but also the vibration generated in daily life such as movement of a person or object, dropping of an object, opening or closing of a door, etc. Will be. Therefore, in order to clearly distinguish the vibration caused by the earthquake from the vibration caused by a cause other than the earthquake, the calculation unit 3 determines whether or not the conditions (1) to (4) are satisfied.

  Condition (1) considers the difference in the generation range between the vibration caused by the earthquake and the vibration generated in daily life. That is, vibrations caused by earthquakes occur throughout the building 11, whereas vibrations that occur in daily life occur locally. Therefore, in the condition (1), the magnitudes of accelerations detected at the same time are compared in a plurality of detection units 2 installed at different locations in the building 11, and the difference between the detected values is within a predetermined range. If it is, it is determined that the vibration may be caused by an earthquake. Further, when the difference between the detected values is outside the predetermined range, it is determined that the vibration is caused by a cause other than the earthquake.

  The condition (2) takes into account the difference in properties between the acceleration of vibration caused by an earthquake and the acceleration of vibration generated in daily life. That is, in general, vibrations generated in daily life such as movement of a person or falling of an object often have a larger vertical acceleration component than a horizontal acceleration component. On the other hand, the vibration caused by the earthquake is greater in the horizontal acceleration than in the vertical acceleration. Therefore, in the condition (2), when the horizontal acceleration is larger than the vertical acceleration, it is determined that the vibration may be caused by an earthquake. Further, when the horizontal acceleration is smaller than the vertical acceleration, it is determined that the vibration is caused by a cause other than an earthquake.

  The condition (3) takes into account the difference in the transmission speed of seismic waves. In general, it is known that P waves (longitudinal waves) and S waves (lateral waves) are observed during an earthquake. P-waves are waves that have the property of alternating between sparse and dense states, just like sound waves that travel in the air. They are also called sparse and dense waves, and S waves are waves that carry the state of displacement and twist. Also called torsional wave. Since the P wave travels faster in the crust than the S wave, if the detected vibration is caused by an earthquake, the S wave is detected after the P wave is detected. That is, if the detected vibration is a vibration caused by an earthquake, the acceleration in the vertical direction (P wave) is detected and then the acceleration in the horizontal direction (S wave) is detected. Therefore, in the condition (3), if the horizontal acceleration (S wave) is detected after detecting the vertical acceleration (P wave), it is determined that the vibration may be caused by an earthquake. In addition, when the horizontal acceleration is detected before the vertical acceleration is detected, it is determined that the vibration is caused by a cause other than the earthquake.

  The condition (4) takes into account the difference in frequency characteristics between the acceleration of vibration caused by earthquakes and the acceleration of vibrations generated in daily life. That is, in vibrations in earthquakes, vibrations having a predetermined frequency (for example, 0.5 Hz) or more are continuously generated, but such vibrations in daily life are rare. In general, when calculating the seismic intensity, the calculation unit 3 of the seismic intensity meter 1 performs a filtering process on the digital acceleration record input from the detection unit 2 by a procedure of Fourier transform / filter processing / inverse Fourier transform. Therefore, in the condition (4), when acceleration is continuously detected for a certain period, the acceleration record is Fourier-transformed at the time of calculating the seismic intensity. It is determined whether or not an acceleration component having a frequency or higher is included. When an acceleration component having a predetermined frequency (0.5 Hz) or higher is included, it is determined that the vibration may be caused by an earthquake. Also, even if acceleration is not detected at a predetermined frequency or higher, or if acceleration is detected at a predetermined frequency or higher, if the intensity does not continue for a certain period of time, the seismic intensity is due to a cause other than an earthquake. It is judged to be a thing.

  Next, a series of operations for determining an earthquake will be described based on the flowchart of FIG. First, in step 1, it is determined whether the difference in acceleration detected by each detector is within a predetermined range (condition (1)). As a result, if the difference in acceleration detected by each detector is within a predetermined range, the process proceeds to step 2 because the vibration may be caused by an earthquake. If it is outside the predetermined range, it is determined that the vibration is caused by a cause other than an earthquake.

  In step 2, the magnitude of the detected acceleration in the horizontal direction is compared with the magnitude of the acceleration in the vertical direction (condition (2)). As a result, if the horizontal acceleration is greater than the vertical acceleration, the process proceeds to step 3. If the acceleration in the vertical direction is larger, it is determined that the vibration is caused by a cause other than an earthquake.

  In step 3, the order of detection of the acceleration in the vertical direction and the acceleration in the horizontal direction is determined (condition (3)). As a result, if the horizontal acceleration is detected after the vertical acceleration is detected, the process proceeds to step 4 because the vibration may be caused by an earthquake. If the horizontal acceleration is detected first, the vibration is determined to be a vibration other than an earthquake.

  In step 4, the acceleration is continuously detected for a certain period or more, and it is determined whether or not an acceleration having a predetermined frequency or more is included (condition (4)). As a result, if the acceleration is continuously detected for a certain period or longer and an acceleration of a predetermined frequency or higher is included, it is determined that the detected acceleration is caused by vibration caused by an earthquake. In other cases, it is determined that the vibration is caused by a cause other than an earthquake.

When the conditions (1) to (4) are satisfied, the calculation unit 3 calculates the seismic intensity calculated by the Japan Meteorological Agency, that is, by performing the following processes A to D.
A. Each of the acceleration data in the horizontal direction (X and Y axis directions) and the vertical direction (Z axis direction) input from the detection unit 2 is subjected to a predetermined filter by a procedure of Fourier transform, filter processing, and inverse Fourier transform.
B. A vector waveform is synthesized from the obtained filtered three recorded components.
C. When the total time for which the absolute value of the vector waveform is greater than or equal to a value a is calculated, a is calculated such that this is exactly 0.3 seconds.
D. From this a, the measured seismic intensity I is calculated from I = 2log a + 0.94.

  When data relating to earthquakes such as seismic intensity and acceleration recording is derived from the calculation unit 3, these are respectively sent to and stored in the storage unit 5. The memory | storage part 5 should just be what can preserve | save a some data, and is comprised by the non-volatile memory in the present Example. The information stored in the storage unit 5 can be displayed on the display unit 6. Moreover, you may make it display the seismic intensity calculated by the calculating part 3 on the display part 6 automatically.

  In this embodiment, the seismic intensity is calculated after it is determined that the vibration is caused by an earthquake. However, the seismic intensity is calculated regardless of the seismic discrimination, and the discrimination result is calculated. You may memorize | store in the memory | storage part 5 with a seismic intensity.

  In addition, when an earthquake occurs, the shaking of the earthquake becomes larger as the floor becomes higher. Therefore, for condition (1), for example, when acceleration is detected on the first floor of a two-story house, it is compared with the detected acceleration value on the second floor, and when acceleration is not detected on the second floor, If the acceleration value is smaller than the value detected at the floor, the vibration may be determined to be caused by a cause other than an earthquake.

  Furthermore, not all of the conditions (2) to (4) are essential, and any one of them can be selected. As the conditions for determination increase, the accuracy of determination of whether or not the input signal is due to an earthquake can be improved. Moreover, even if not all of the conditions (2) to (4) are satisfied, if some of them are satisfied, it is determined that the information on the detected vibration is due to an earthquake. Also good.

  In the seismic intensity meter 1 according to the present embodiment, one building 11 such as a house is assumed as one unit, but the present invention is not limited to such an embodiment. For example, by using a plurality of neighboring houses as a unit, the acceleration record detected by the detection unit 2 installed in each house can be transmitted and received through a communication line such as the Internet, and the detection values for each house are compared. The detected vibration may be discriminated whether it is a vibration caused by an earthquake or a vibration other than an earthquake.

It is a block diagram of the seismometer according to the present invention. It is the figure which showed the installation state of the seismic intensity meter which implemented this invention. It is a flowchart of the operation | movement which discriminate | determines whether the detected acceleration is a thing by the cause other than an earthquake.

Explanation of symbols

1 Seismic intensity meter 2 Detector 3 Calculation unit

Claims (5)

In a seismometer having a detection unit that detects information related to vibration, and a calculation unit that is electrically connected to the detection unit and that calculates a seismic intensity based on information related to vibration detected by the detection unit,
The seismic intensity meter includes a plurality of detection units, provided that the difference in information regarding vibration detected by each detection unit is within a predetermined range.
The detected vibration information is determined to be due to an earthquake,
The seismic intensity meter according to claim 1, wherein the calculation unit calculates a seismic intensity of the earthquake based on information on vibration detected by the detection units. The detection unit detects vertical acceleration and horizontal acceleration,
Compare the vertical acceleration detected by the detector and the horizontal acceleration,
As long as the horizontal acceleration is greater than the vertical acceleration,
The seismic intensity meter according to claim 1, wherein the information on the detected vibration is determined to be due to an earthquake. The detection unit detects vertical acceleration and horizontal acceleration,
On the condition that the acceleration in the horizontal direction is detected after the acceleration in the vertical direction is detected,
The seismic intensity meter according to claim 1, wherein the information on the detected vibration is determined to be due to an earthquake. On condition that acceleration of a predetermined frequency or higher is continuously detected for a certain period of time,
The seismometer according to claim 1, wherein the information on the detected vibration is determined to be due to an earthquake.   5. The seismometer according to claim 1, wherein the plurality of detection units are respectively installed at different locations in a building.

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