JP5317102B2 - Seismic motion index calculation device, seismic motion index calculation system and seismic motion index calculation method using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide: an apparatus for computing an earthquake motion index, which can prevent an uncertain judgment on the cessation of an earthquake from causing a gradual increase in value; a system for computing an earthquake motion index using the apparatus; and a method for computing an earthquake motion index. <P>SOLUTION: An apparatus 1 for computing an earthquake motion index from the acceleration of an earthquake measured includes: CAV computing means 2 having time-series earthquake acceleration acquiring means 4 for arranging acceleration data on earthquake motions in an chronological order and integrating means 5 for calculating the time integral of the absolute values of acceleration for each single sampling segment of a sampling interval set in the preparation of the chronological order; and time window computing means 3 having time window setting means 6 for setting a predetermined range of time and the number of samples in that range and adding means 7 for adding the time integral of the absolute values of acceleration for each segment corresponding to the number of samples contained within the time window. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a seismic motion index calculation device that measures seismic motion and calculates a seismic motion index from the measured value, a seismic motion index calculation system using the seismic motion index, and a seismic motion index calculation method.

  In recent years, in Japan, nuclear power plants such as Onagawa, Shiga, and Kashiwazaki Kariwa have been urgently stopped due to earthquake motion. In Japan, if the acceleration of seismic motion exceeds the threshold set at each site, the nuclear power plant is to be shut down urgently.

  However, when the seismic motion is dominated by high frequency components, large acceleration may be observed even though the energy is not large. For example, the Onagawa and Shiga nuclear power plants are thought to have had no problem even if they were operated continuously. Therefore, at present, a stable index that can replace acceleration is being sought.

  In the United States, the NRC (Nuclear Regulatory Authority) recommends an emergency shutdown of a nuclear power plant when the CAV exceeds a threshold of 0.16 Gs, and the IAEA (International Atomic Energy Agency) ) As an alternative to acceleration. Here, CAV is a value that is sequentially integrated when the absolute value of the acceleration waveform exceeds a certain threshold (see Non-Patent Document 1).

“Reports on tests and surveys related to seismic evaluation technology for nuclear facilities, etc., and post-earthquake impact assessment of nuclear facilities”, Incorporated Administrative Agency, Japan Nuclear Energy Safety Organization, October 2007

However, in an actual earthquake, aftershock ground motion arrives after the main shock, and the CAV that performs successive addition gradually increases forever. Therefore, even if it does not exceed the regulation value set by the main shock, there is a risk that the regulation value will be exceeded by a later aftershock. For this reason, there is a method of determining the end of an earthquake and resetting the calculation when it is determined that one earthquake has ended, but there is no guarantee that the end of the earthquake can be determined when earthquakes occur frequently.

  In order to solve the above-mentioned problem, the present invention provides a seismic motion index calculation device that calculates a seismic motion index that can prevent a gradual increase in value due to an uncertain earthquake end determination, a seismic motion index calculation system, and a seismic motion index calculation method The purpose is to provide.

In order to solve the above-described problem, the earthquake motion index calculation device according to the present invention is a seismic motion index calculation device that calculates an earthquake motion index from measured earthquake acceleration, and obtains acceleration sample values by making the earthquake motion acceleration data time-series. A CAV calculation means comprising: a seismic acceleration time series acquisition means; an integration means for obtaining a time integral of an absolute value of an acceleration sample value for each sample section of a sampling interval set at the time series creation; a predetermined time range; Time window setting means for setting the number of samples of the acceleration sample value within the range, and addition means for adding the time integral of the absolute value of the acceleration sample value for each section included in the time window. It includes a time window calculation means having, a, said integrating means when an acceleration in the threshold value determination time set separately from the sampling interval set at series creation When even one absolute value of sample values exceeds a predetermined threshold value, an integral of absolute values of all acceleration sample values within the threshold determination time is obtained, and the adding means calculates an acceleration sample value exceeding the predetermined threshold value. It is characterized in that an addition process is performed every time the value is obtained and a subtraction is performed every predetermined time .

The seismic motion index calculation device according to the present invention is a seismic motion index calculation device that calculates a seismic motion index from measured earthquake acceleration. A CAV calculating means having means, an integrating means for obtaining a time integral of an absolute value of the acceleration sample value for each sample interval of a sampling interval set at the time of creation of the time series, a predetermined time range, and an acceleration within the range A time window setting means for setting the number of samples of the sample value, and an adding means for adding the time integral of the absolute value of the acceleration sample value for each section corresponding to the number of samples included in the time window. The integration means includes an acceleration sample value within a threshold determination time set separately from the sampling interval set at the time series creation. When even one pair of values exceeds a predetermined threshold, an integral of absolute values of all acceleration sample values within the threshold determination time is obtained, and the adding means obtains a value obtained every time an acceleration sample value is obtained. In addition, the second time value is the same as the value obtained by the time window calculating means, and other than the second time value, there is a real-time calculating means that does not exceed the value obtained by the time window calculating means. And

  Furthermore, a ground motion index calculation system using the ground motion index calculation device of the present invention includes a power supply device that drives the ground motion index calculation device and a sensor that measures the ground motion, and outputs an acceleration of the ground motion to the ground motion index calculation device. And an output means for outputting to the outside when the seismic motion index calculated by the seismic motion index calculating device exceeds a predetermined threshold value.

Further, according to the present invention , there is provided a method for calculating an earthquake motion index according to the present invention , the method for calculating an earthquake motion index from an acceleration of a measured earthquake, wherein the acceleration data of the earthquake motion is time-series and an acceleration sample value is obtained; A step of obtaining a time integral of an absolute value of an acceleration sample value for each sample interval of a sampling interval set at the time of creation, a step of setting a predetermined time range, and the number of samples of the acceleration sample value within the range; time possess a step of adding an acceleration sample values included in the window, the absolute value of the step of obtaining a time integration of the acceleration, when the acceleration threshold value determination time within set separately from the sampling interval set at series creation When even one absolute value of sample values exceeds a predetermined threshold, all acceleration sample values within the threshold determination time Obtains the integral of relative value, the step of adding the acceleration sample values contained in the time window performs addition processing for each acceleration sample value exceeds a predetermined threshold value is obtained, it performs a subtraction for each predetermined time It is characterized by that.

Further, according to the present invention, there is provided a method for calculating an earthquake motion index according to the present invention, the method for calculating an earthquake motion index from an acceleration of a measured earthquake, wherein the acceleration data of the earthquake motion is time-series and an acceleration sample value is obtained; A step of obtaining a time integral of an absolute value of an acceleration sample value for each sample interval of a sampling interval set at the time of creation, a step of setting a predetermined time range, and the number of samples of the acceleration sample value within the range; time Adding the acceleration sample value included in the window, and the step of obtaining the time integral of the absolute value of the acceleration includes acceleration within a threshold determination time set separately from the sampling interval set at the time series creation time When even one absolute value of sample values exceeds a predetermined threshold, all acceleration sample values within the threshold determination time In the step of obtaining the integral of the pair value and adding the acceleration sample value included in the time window, the value obtained every time the acceleration sample value is obtained is the same as the value obtained by the time window calculating means for each second value. The value obtained by the time window calculation means is not exceeded except for the value per second .

  With such a seismic motion index calculation device, a seismic motion index calculation system and a seismic motion index calculation method using the seismic motion index calculation device, it is possible to prevent a gradual increase in value due to an uncertain earthquake end determination. In addition, it is possible to quickly know whether the regulation value set in the facility has been exceeded. Furthermore, the memory capacity and calculation amount of earthquake motion can be reduced.

  An embodiment of the present invention will be described. FIG. 1 is a diagram showing a main configuration of a seismic motion index calculation apparatus and a seismic motion index calculation system using the same according to the present invention. In the figure, 1 is an earthquake motion index calculation device, 2 is a CAV calculation means, 3 is a time window calculation means, 10 is an earthquake motion index output system, 11 is a measurement device, 12 is a communication device, 13 is a display device, 14 is an alarm device, Reference numeral 15 denotes a time calibration unit, 16 denotes a power source unit, 17 denotes a power source, and 18 denotes a storage battery.

  The earthquake motion index calculation device 1 calculates and outputs an index of earthquake motion by inputting the acceleration measured by the measurement device 11 to the CAV calculation means 2 and the time window calculation means 3. Details of the earthquake motion index calculation device 1 will be described later.

  The seismic motion index output system 10 has a seismic motion index calculation device 1 and is constructed by inputting and outputting various signals to and from the seismic motion index calculation device 1.

  The measuring device 11 includes a sensor 11a that measures seismic motion, and an AD converter 11b that converts the seismic motion measured by the sensor 11a into a digital signal, and transmits a seismic motion signal to the seismic motion index calculating device 1. .

  The communication device 12 outputs the earthquake motion index calculated by the earthquake motion index calculation device 1 to another system or device such as a nuclear power plant via a communication line. In particular, it is preferable that the setting is made so as to be outputted urgently when the seismic motion index calculated by the seismic motion index calculating apparatus 1 exceeds a predetermined threshold. In addition, it is preferable that the communication device 12 has a function of inputting a signal from the outside and is set so as to be able to perform a remote operation or the like.

  The display device 13 is a device that displays the earthquake motion index calculated by the earthquake motion index calculation device 1 to the outside via a display. In particular, it is preferable that the setting is always displayed when the seismic motion index calculated by the seismic motion index calculating apparatus 1 exceeds a predetermined threshold.

  The warning device 14 outputs a warning when the earthquake motion index calculated by the earthquake motion index calculation device 1 exceeds a predetermined threshold value.

  The communication device 12, the display device 13, and the alarm device 14 constitute output means.

  The time calibration unit 15 obtains an accurate time through a GPS signal, a line, etc., and accurately sets the time in the earthquake motion index calculation device 1.

  The power supply unit 16 is a part that receives power from a power supply device 17 that combines commercial power and power from the storage battery 18.

  Note that the measurement device 11, the communication device 12, the display device 13, the alarm device 14, the time calibration unit 15, the power supply unit 16, and the like may be formed integrally with the earthquake motion index calculation device 1 or separately. Also good.

  Next, a first embodiment of the earthquake motion index calculation device 1 will be described. FIG. 2 is a diagram illustrating the configuration of the CAV calculation unit 2, and FIG. 3 is a diagram illustrating the configuration of the time window calculation unit 3.

  As shown in FIG. 2, the CAV calculation means 2 includes a seismic acceleration time series acquisition means 4 and an integration means 5, and calculates the CAV shown in Non-Patent Document 1. The CAV calculation unit 2 of the embodiment calculates a CAV (corresponding to the expression (1) in Non-Patent Document 1 and hereinafter referred to as an original CAV (CAVo)) without providing a threshold.

  The seismic motion acceleration time series acquisition means 4 makes the seismic motion acceleration data time series. The integrating means 5 calculates the time integral of the absolute value of acceleration for each sample interval of the sampling interval set at the time series creation.

  As shown in FIG. 3, the time window calculating unit 3 includes a time window setting unit 6 and an adding unit 7.

  The time window setting means 6 is for setting a predetermined time range for calculating the earthquake motion index and the number of samples within the range. The adding means 7 is means for adding the sample values included in the time window. Note that it is more efficient and preferable to calculate sequentially corresponding to the sample added to the time window and the sample out of the time window.

  Next, a procedure for calculating the earthquake motion index of the first embodiment from the earthquake motion acceleration data will be described. FIG. 4 is a flowchart illustrating the earthquake motion index calculation method according to the first embodiment.

First, in step 1, a time series of digital signals obtained by AD-converting the seismic acceleration data measured by the measuring device 11 as shown in FIG. 5 is a [i] (i = 0, 1, 2, 3,...). (ST1). Here, the sampling interval of the digital value is Δt. The actual value is, for example, 0.01 s.

  Next, in step 2, after obtaining the time integral s [i] of the absolute value of acceleration in one sample section, the original CAV (CAVo) at the time when the nth acceleration sample value is obtained is obtained (ST2). ).

In the CAV calculation, it is assumed that the discrete acceleration data is interpolated with a straight line. At this time, if the time integral of the absolute value of acceleration in one sample section (time (i-1) · Δt to i · Δt) is s [i], as shown in FIG. 6 and FIG. (1) and Equation (2).
If a [i-1] and a [i] have the same sign,
s [i] = (| a [i-1] | + | a [i] |) · Δt / 2 (1)
If a [i-1] and a [i] are different signs,
s [i] = (a [i-1] ・ a [i-1] + a [i] ・ a [i]) / (| a [i-1] | + | a [i] |) ・ Δt / 2 (2)
When i ≦ 0, s [i] = 0.

Therefore, the original CAV (CAVo) at the time when the nth acceleration sample value is obtained is obtained by the following equation (3).

  If the equation (3) is maintained, the value of the original CAV (CAVo) becomes infinitely large. In order to avoid this, a time window is provided, and only values included in the time window are added to obtain a time window setting original CAV (CAVot).

  First, in step 3, a time window is set (ST3).

If the number of samples corresponding to the time window of T seconds is N (N = T · p, where p is the number of samples of acceleration data included in one second, for example, p = 100 if Δt = 0.01).

  Next, in step 4, the sample values included in the time window are added (ST4).

Steps 3 and 4 are expressed by the following formula (4).

In order to calculate more efficiently, it is preferable to calculate sequentially as shown by the following formula (5) corresponding to the sample added to the time window and the sample outside the time window.
CAVot [n] = CAVot [n-1] + s [n] -s [nN] (5)

  FIG. 8 shows the value of the original CAV (CAVo) obtained by the equation (3), and FIG. 9 shows the value of the time window setting original CAV (CAVot) obtained by the equation (5).

  As shown in FIG. 9, the value of the time window setting original CAV (CAVot) obtained by the equation (5) does not continue to increase gradually.

  Next, a second embodiment of the earthquake motion index calculation device 1 will be described. The CAV calculation means 2 and the time window calculation means 3 of the second embodiment have the same means as in FIGS. 2 and 3, but the method is different.

  As shown in FIG. 2, the CAV calculation means 2 includes a seismic acceleration time series acquisition means 4 and an integration means 5, and calculates the CAV shown in Non-Patent Document 1. The CAV calculation means 2 in the form calculates a CAV (corresponding to equation (2) in Non-Patent Document 1, hereinafter referred to as standardized CAV (CAVs): standardized CAV) provided with a threshold.

  The seismic motion acceleration time series acquisition means 4 makes the seismic motion acceleration data time series. The integrating means 5 calculates the integral of the absolute value of the acceleration whose maximum value exceeds the threshold value a0 in one sample interval of the sampling interval set at the time series creation time.

  As shown in FIG. 3, the time window calculating unit 3 includes a time window setting unit 6 and an adding unit 7.

  The time window setting means 6 sets a time range for calculating the earthquake motion index and the number of samples within the range. The adding means 7 is means for adding the sample values included in the time window. Note that it is more efficient and preferable to calculate sequentially corresponding to the sample added to the time window and the sample out of the time window.

  Next, the procedure for calculating the earthquake motion index of the second embodiment from the earthquake motion acceleration data will be described. FIG. 10 is a flowchart showing the earthquake motion index calculation method of the second embodiment.

First, in step 11, a time series of a digital signal obtained by AD-converting seismic acceleration data measured by the measuring device 11 as shown in FIG. 5 is a [i] (i = 0, 1, 2, 3,...). (ST11). Here, the sampling interval of the digital value is Δt. The actual value is, for example, 0.01 s.

ここで、x[j]は、[(j-1)*p≦k≦j*p] とした場合、|a[k]|≧a0 となるa[k]が、
ある場合、
x[j] = 1
ない場合、
x[j]=0
とする。 Next, when the maximum absolute value of acceleration in one sample section exceeds a threshold value a0 (for example, 0.025G, G = 1,000 gal) in step 12, as shown in the following formula (6), All s [i] belonging to a threshold judgment section different from the section are added (ST12). In this embodiment, the threshold determination interval is 1 second.

Here, when x [j] is [(j-1) * p ≦ k ≦ j * p], a [k] satisfying | a [k] | ≧ a0 is
If there is
x [j] = 1
If not,
x [j] = 0
And

Then, the standard CAV (CAVs) at the time when the acceleration sample value at the m second is obtained is obtained as Expression (7).

  Thus, the standard CAV (CAVs) is a value for every second because of the threshold determination section division. FIG. 11 is a schematic graph of | a [i] |, s [i], z [j], and CAVs [j] when Δt = 0.2 and a0 = 0.025G.

  However, as is clear from the equation (7), the value of the standard CAV (CAVs) can be increased infinitely as it is. In order to avoid this, it is only necessary to provide a time window and add only the values included in the time interval.

  Therefore, a time window of M seconds is provided in step 13 (ST13).

Next, in step 14, only the values included in the time interval set in step 13 are added as shown in the following equation (8) (ST14).

It should be noted that the equation (8) is efficient if it is calculated sequentially as shown in the following equation (9).
CAVst [m] = CAVst [m-1] + z [m] -z [mM] (9)

  FIG. 12 shows the value of standard CAV (CAVs) obtained by Expression (7), and FIG. 13 shows the value of time window setting standard CAV (CAVst) obtained by Expression (9).

  As shown in FIG. 13, the value of the time window setting standard CAV (CAVst) obtained by the equation (9) does not continue to increase gradually.

  Here, a calculation method using the real-time calculation means 8 for providing real-time characteristics will be described.

In the method of formula (9), a value can be obtained every second. The standard CAV defined in Non-Patent Document 1 is considered to obtain a value after the earthquake has ended, and no consideration is given to obtaining the value during the earthquake. For this reason, in order to provide real-time properties, it is considered that the real-time computing means 8 is provided in the adding means 7 and a real-time standard CAV (CAVhs) value is obtained every time an acceleration sample value is obtained.

  Since the value obtained by Expression (9) is an important value used as a regulation value for stopping the system, the value of the real-time standard CAV (CAVhs) obtained every time the acceleration sample value is obtained is a value per second. In this case, it is assumed that the value is the same as the value obtained by Expression (9), and the value of Expression (9) is not exceeded except for the value per second. At this time, it is desirable that the value of the real-time standard CAV (CAVhs) changes smoothly.

From the equation (9), it can be seen that the processing of the portion added within the time window and the processing of the portion subtracted from the time window are performed. Therefore, these two portions may be made to correspond to processing for each sampling.

ただし、q=int(i/p) とし、int(A)はAの整数部を表すものとする。
ここで、y[i]は、[p*q≦k≦i]、とした場合、 (|a[k]|≧a0) となるa[k]が、
ある場合、
y[i] = 1
ない場合、
y[i] = 0
とする。 First, the processing of the portion added within the time window by the real-time computing means 8 will be described. In this process, w [i] represented by the following equation (10) is obtained instead of z [j] obtained by equation (6).

However, q = int (i / p) and int (A) represents the integer part of A.
Here, when y [i] is [p * q ≦ k ≦ i], a [k] which becomes (| a [k] | ≧ a0)
If there is
y [i] = 1
If not,
y [i] = 0
And

  Expression (10) corresponds to performing addition processing retroactively as soon as the acceleration exceeds the threshold value a0. FIG. 14 is a schematic graph of w [i] when p = 5.

  Next, the process of the part subtracted from the time window by the real-time calculation means 8 will be described.

  In order to perform subtraction of a portion outside the time window, it is necessary to store a value to be subtracted. If M = 60 and p = 100, the storage area required to perform this subtraction for each sample is 6000 samples, and a large area for storing values is required. For this reason, it is preferable to perform subtraction every second as shown in the equation (9) instead of every sampling. This requires M storage areas.

  Further, the subtraction is performed every second, as will be described later, in order to achieve consistency between the value obtained by Equation (9) and the value obtained for each sample.

In summary, the real-time standard CAV (CAVhs) when the acceleration sample value a [i] is obtained is the same as the time window setting standard CAV (CAVst) when i = p * q (every second). Therefore, the following equation (11) is obtained using CAVst of equation (9).
CAVhs [i] = CAVst [q] (11)

In other cases, the following expression (12) is first obtained so as not to exceed the value of expression (9) except for the value per second.
CAVhs0 [i] = CAVst [q] -z [q-M + 1] + w [i] (12)

In order to prevent the value from changing in a sawtooth shape by decreasing the value immediately after every second (p * q + 1st sampling) and then increasing it by adding w [i] Is less than the value of the positive second immediately before (p * q-th sampling) calculated by Expression (11), the following Expression (13) held at that value is adopted.
CAVhs [i] = max [CAVhs0 [i], CAVst [q]] (13)
Here, max [A, B] represents the larger one of A and B.

Or Formula (12) and Formula (13) can also be expressed like the following Formula (14).
CAVhs [i] = CAVst [q] + max [0, w [i] -z [q-M + 1]] (14)

  FIG. 15 shows a schematic graph of the calculation result of Expression (14) when p = 5. If the subtraction of z [q-M + 1] is not performed from the p * q + 1-th sampling time as shown in equation (12), the time when the real-time standard CAV (CAVhs) is defined by equation (9) The value of the window setting standard CAV (CAVst) may be exceeded.

According to the equations (11) and (14), the value of the method of the equation (9) coincides with the value of the equation (9) every second, and the value of the equation (9) is not exceeded on the way. That is, the threshold can be determined at a timing earlier than the official method while obtaining a value that matches the officially defined method. Furthermore, the fluctuation of the value is reduced.

It is a figure which shows the main structures of the earthquake motion index calculation apparatus of this invention and the earthquake motion index calculation system using the same. It is a figure which shows the structure of a CAV calculation means. It is a figure which shows the structure of a time window calculation means. It is a figure which shows the flowchart which shows the seismic-motion-index calculation method of 1st Embodiment. It is a figure which shows the seismic-motion acceleration data which the measuring device measured. It is a figure which shows the time integration of the absolute value of the acceleration in 1 sample area (time (i-1) * t to i * Δt) in case a [i-1] and a [i] have the same sign. It is a figure which shows the time integration of the absolute value of the acceleration in 1 sample area (Time (i-1) * Δt to i * Δt) when a [i-1] and a [i] are different signs. It is a figure which shows the value of the original CAV (CAVo) calculated | required by Formula (3). It is a figure which shows the value of the time window setting original CAV (CAVot) calculated | required by Formula (5). It is a figure which shows the flowchart which shows the seismic-motion-index calculation method of 2nd Embodiment. FIG. 6 is a diagram schematically showing | a [i] |, s [i], z [j], and CAVs [j]. It is a figure which shows the value of the standard CAV (CAVs) calculated | required by Formula (7). It is a figure which shows the value of the time window setting standard CAV (CAVst) calculated | required by Formula (9). It is a figure which shows typical w [i]. It is a figure which shows the typical graph of the calculation result of Formula (14).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Earthquake motion index calculation apparatus, 2 ... CAV calculation means, 3 ... Time window calculation means, 4 ... Earthquake motion acceleration time series acquisition means, 5 ... Integration means, 6 ... Time window setting means, 7 ... Addition means, 10 ... Earthquake motion index Output system 11 ... Measurement device 12 ... Communication device 13 ... Display device 14 ... Alarm device 15 ... Time calibration unit 16 ... Power source unit 17 ... Power source 18 ... Storage battery

Claims (5)

In the ground motion index calculation device that calculates the ground motion index from the measured acceleration of the earthquake,
Seismic motion acceleration time-series acquisition means for time-series seismic motion acceleration data and acquiring acceleration sample values;
Integration means for obtaining a time integral of the absolute value of the acceleration sample value for each sample interval of the sampling interval set at the time series creation;
CAV calculation means having
A time window setting means for setting a predetermined time range and the number of acceleration sample values within the range;
An adding means for adding the time integral of the absolute value of the acceleration sample value for each section of the number of samples included in the time window;
A time window calculating means having
Equipped with a,
The integration means calculates the total acceleration within the threshold determination time when even one absolute value of acceleration sample values within the threshold determination time set separately from the sampling interval set at the time series creation exceeds a predetermined threshold. Find the integral of the absolute value of the sample value,
The earthquake motion index calculation device according to claim 1, wherein the addition means performs an addition process every time an acceleration sample value exceeding a predetermined threshold is obtained, and performs a subtraction every predetermined time . In the ground motion index calculation device that calculates the ground motion index from the measured acceleration of the earthquake,
Seismic motion acceleration time-series acquisition means for time-series seismic motion acceleration data and acquiring acceleration sample values;
Integration means for obtaining a time integral of the absolute value of the acceleration sample value for each sample interval of the sampling interval set at the time series creation;
CAV calculation means having
A time window setting means for setting a predetermined time range and the number of acceleration sample values within the range;
An adding means for adding the time integral of the absolute value of the acceleration sample value for each section of the number of samples included in the time window;
A time window calculating means having
Equipped with a,
The integration means calculates the total acceleration within the threshold determination time when even one absolute value of acceleration sample values within the threshold determination time set separately from the sampling interval set at the time series creation exceeds a predetermined threshold. Find the integral of the absolute value of the sample value,
The adding means assumes that the value obtained every time the acceleration sample value is obtained is the same as the value obtained by the time window calculating means for each second value, and the time window calculating means for the value other than every second value. Has real-time computing means to prevent exceeding the obtained value
An earthquake motion index calculation device characterized by the above. A power supply device for driving the earthquake motion index calculation device;
A measuring device that has a sensor for measuring seismic motion and outputs acceleration of seismic motion to the seismic motion index calculating device;
The earthquake motion index calculation device according to claim 1 or 2 , further comprising an output unit that outputs to the outside when the earthquake motion index calculated by the earthquake motion index calculation device exceeds a predetermined threshold value. Earthquake motion index calculation system using In the ground motion index calculation method for calculating the ground motion index from the measured earthquake acceleration,
Time-series acceleration data of seismic motion and obtaining acceleration sample values;
Obtaining a time integral of the absolute value of the acceleration sample value for each sample interval of the sampling interval set at the time series creation;
Setting a predetermined time range and the number of acceleration sample values within the range; and
Adding acceleration sample values contained within a time window;
I have a,
The step of obtaining the time integral of the absolute value of the acceleration is when the absolute value of the acceleration sample value within the threshold determination time set separately from the sampling interval set at the time series creation exceeds a predetermined threshold, Find the integral of the absolute values of all acceleration sample values within the threshold determination time,
Adding the acceleration sample values included in the time window,
An earthquake motion index calculation method characterized in that an addition process is performed each time an acceleration sample value exceeding a predetermined threshold is obtained, and a subtraction is performed every predetermined time . In the ground motion index calculation method for calculating the ground motion index from the measured earthquake acceleration,
Time-series acceleration data of seismic motion and obtaining acceleration sample values;
Obtaining a time integral of the absolute value of the acceleration sample value for each sample interval of the sampling interval set at the time series creation;
Setting a predetermined time range and the number of acceleration sample values within the range; and
Adding acceleration sample values contained within a time window;
Have
The step of obtaining the time integral of the absolute value of the acceleration is when the absolute value of the acceleration sample value within the threshold determination time set separately from the sampling interval set at the time series creation exceeds a predetermined threshold, Find the integral of the absolute values of all acceleration sample values within the threshold determination time,
In the step of adding acceleration sample values included in the time window,
The value obtained every time the acceleration sample value is obtained is the same as the value obtained by the time window calculation means for each second value, and exceeds the value obtained by the time window calculation means for values other than every second. A method for calculating an earthquake motion index, characterized in that it does not exist .

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