JP3576911B2 - Debris flow judgment diagram display device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a debris flow determination diagram display device for automatically displaying a debris flow determination diagram (snake curve) used when determining the possibility of occurrence of debris flow.
[0002]
[Prior art]
In order to protect human lives from landslides such as debris flows and landslides caused by rainfall, it is necessary to foresee the occurrence of landslides in advance, and to evacuate residents and others in the disaster-prone area before the occurrence of landslides There is.
Conventionally, a debris flow determination diagram (snake curve) has been used to predict the occurrence of a landslide disaster. This debris flow determination diagram shows, on two-dimensional coordinates, a curve indicating the state of rainfall and a reference line for identifying the possibility of occurrence of debris flow. The curve indicating the state of rainfall represents information such as time rainfall, effective rainfall, effective rainfall intensity, and the like.
[0003]
[Problems to be solved by the invention]
In the debris flow determination diagram currently used, occurrence of debris flow is predicted based on only the past actual rainfall. Therefore, when the occurrence of the debris flow is predicted, the possibility of the occurrence of the debris flow is already high, and it is considered that there is little time margin in consideration of the time required for notification and evacuation.
[0004]
An object of the present invention is to provide a debris flow determination diagram display device capable of displaying a debris flow determination diagram useful for early prediction of occurrence of a debris flow.
[0005]
[Means for Solving the Problems]
Claim 1 displays a debris flow determination diagram showing a correspondence relationship between first rainfall information according to past rainfall during the first period and second rainfall information according to past rainfall during the second period. A debris flow determination diagram display device, comprising: a time acquisition unit configured to acquire information on calculation times of first rainfall information and second rainfall information; and a first rainfall information and a second rainfall information for each of a plurality of different time points. Time storage means for associating the second rainfall information with the information of the time at which the information was obtained, and each display point on the debris flow determination diagram determined from the first rainfall information and the second rainfall information at each time point And a time display means for acquiring and displaying time information associated with the first rainfall amount information and the second rainfall amount information from the time storage means, near the position.
[0006]
On the debris flow determination diagram, rainfall information at various points of time indicating the corresponding relationship between the first rainfall information (for example, effective rainfall) and the second rainfall information (for example, one-hour rainfall intensity) is sequentially displayed. However, a forecaster who uses the apparatus cannot read a time-series change of past rainfall information from a general debris flow determination diagram.
According to the first aspect, the information on the time associated with each display point is displayed near the display point, so that the forecaster can read the time series change of the past rainfall information from the arrangement order of the displayed times. .
[0007]
Disasters such as debris flows are caused by accumulation of past rainfall. In addition, it is considered that the influence of the past rainfall changes according to the magnitude of the time difference from the present. Therefore, by grasping the time-series change of the past rainfall information in the debris flow determination diagram, it becomes possible to predict before the possibility of the occurrence of the debris flow increases.
For example, the forecaster can also predict a future change to some extent based on a time-series change pattern of past rainfall information, a moving amount of a display point per unit time, and the like.
[0008]
According to a second aspect of the present invention, there is provided the debris flow determination diagram display device according to the first aspect, wherein coordinates of the display points are displayed according to a comparison result between a position of each display point on the debris flow determination diagram and a predetermined reference position on the display area. Coordinate comparing means for determining a relative position with respect to coordinates for displaying time, and instruction line displaying means for displaying a line connecting the position of each display point on the debris flow determination diagram and the display position of time are further provided. It is characterized by.
[0009]
If the display position of the time is too close to each display point on the debris flow determination diagram, there is a possibility that the debris flow determination diagram becomes difficult to read based on the time information.
According to a second aspect, the coordinate comparing means determines the coordinates of the display point and the coordinates for displaying the time in accordance with the comparison result between the position of each display point on the debris flow determination diagram and a predetermined reference position on the display area. Since the relative position is determined, the time can be displayed at a position apart from the debris flow determination diagram.
[0010]
For example, the center position of the two-dimensional coordinates is set to the reference position, and when each display point on the debris flow determination diagram is located below the reference position, the time is displayed above the reference position, and each time on the debris flow determination diagram is displayed. If the time is displayed below the reference position when the display point is located above the reference position, it is possible to increase the interval between the debris flow determination diagram and the time display position.
[0011]
Also, since the indication line display means displays a line segment connecting the position of each display point on the debris flow determination diagram and the display position of the time, the correspondence between the position of each display point and the time is determined based on the connection state of the line segment. Easy to read.
According to a third aspect of the present invention, in the debris flow determination diagram display device according to the first aspect, a plurality of display points are sequentially displayed on the debris flow determination diagram, and a time display area of each display point displayed in the past and a display to be displayed next are displayed. It is characterized by further comprising a display position changing means for examining whether or not the point overlaps the time display area, and automatically moving the time display position of the next displayed display point when the overlap is detected. .
[0012]
When the time is displayed at a relatively short time interval, the time information of a plurality of adjacent display points may overlap each other, and the display time may be illegible.
According to the third aspect, when the display position changing means detects an overlap, the time display position of the next display point to be displayed is automatically moved, so that the times of a plurality of adjacent display points are prevented from overlapping each other. it can.
[0013]
Claim 4 The debris flow determination diagram display device according to claim 1, Predicted rainfall input means for inputting predicted rainfall information relating to rainfall after the current time, and debris flow including predicted rainfall information after the current time based on the predicted rainfall information input by the predicted rainfall input means. And a prediction display means for displaying a judgment diagram.
[0014]
For example, by observing the current rainfall conditions and weather conditions such as rain clouds, it is possible to predict a short-time rainfall one hour or two hours after the current time. In claim 4, such predicted rainfall is input by the predicted rainfall input means, and the prediction display means displays a debris flow determination diagram including information on predicted rainfall after the current time so as to reflect the predicted rainfall. .
[0015]
By using the debris flow judgment diagram including the information of the predicted rainfall, the forecaster can predict the debris flow with sufficient time before the risk of occurrence of the debris flow increases. Therefore, it is possible to effectively prevent occurrence of a disaster due to a delay in notification or evacuation.
Claim 5 The debris flow determination diagram display device according to claim 1, Disaster result data holding means for holding at least result data of rainfall information relating to a disaster that occurred in the past, and disaster result display means for displaying information of the result data input from the disaster result data holding means on the debris flow determination diagram in a superimposed manner. Is provided.
[0016]
According to the fifth aspect, the disaster result display means superimposes and displays the information of the result data input from the disaster result data holding means on the debris flow determination diagram. Information on the disaster that actually occurred in the past is displayed on the debris flow judgment diagram, so the forecaster can compare the past disaster with the current debris flow judgment diagram and predict it before the risk of debris flow occurrence becomes high it can.
According to a sixth aspect of the present invention, in the debris flow determination diagram display device of the fifth aspect, the disaster result data holding device The steps are It holds result data indicating the type of each disaster that occurred in the past, and the disaster result display means changes the display according to the type of disaster of the result data input from the disaster result data holding means. I do.
[0017]
According to claim 6, the results of a plurality of types of past disasters can be displayed for each type. For example, by displaying disasters that caused debris flow, disasters that frequently occurred, and disasters that caused some collapse, etc., on the debris flow judgment diagram, the forecaster could more accurately determine the likelihood of a disaster occurring. Can be recognized.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
(First Embodiment)
One embodiment of the debris flow determination diagram display device of the present invention will be described with reference to FIGS. This embodiment corresponds to claims 1 to 4.
[0019]
FIG. 1 is a flowchart showing details of the display processing (1) of this embodiment. FIG. 2 is a flowchart showing details of the display processing (2) of this embodiment. FIG. 3 is a block diagram showing the configuration of the device of this embodiment. FIG. 4 is a flowchart showing the operation (1) of the device of this embodiment. FIG. 5 is a flowchart showing the operation (2) of the device of this embodiment.
[0020]
FIG. 6 is a schematic diagram illustrating a configuration example of the actual rainfall DB. FIG. 7 is a schematic diagram illustrating a configuration example of the calculated rainfall information DB (1). FIG. 8 is a schematic diagram illustrating a configuration example of the predicted rainfall DB. FIG. 9 is a front view showing a display example of the debris flow determination diagram of this embodiment. FIG. 10 is a front view showing an example of determining display coordinates of time. FIG. 11 is a front view showing an example of changing the time display coordinates.
[0021]
In this embodiment, the time acquisition means of claim 1 corresponds to step S47, the time storage means of claim 1 corresponds to the actual rainfall DB 16, and the time display means of claim 1 corresponds to step S62.
Further, the coordinate comparing means of claim 2 corresponds to steps S13 to S16, and the indicating line display means of claim 2 corresponds to step S33. Further, the display position changing means of claim 3 corresponds to steps S20 to S30. The predicted rainfall input means in claim 4 corresponds to step S50, and the predicted display means in claim 4 corresponds to step S64.
[0022]
Referring to FIG. 3, this device includes a computer main body 10, a communication interface 11, a network interface 12, a clock circuit 13, a display device 14, and a storage device 15.
As the computer main body 10, for example, a personal computer or a workstation can be used. In this example, a telemeter is used to observe the actual rainfall at a specific point. A communication interface 11 is provided for performing communication between the telemeter and the computer main body 10.
[0023]
Further, in this example, data of a predicted value of future rainfall (such as one hour rainfall n hours later) is obtained from a provider of various weather information and used. This data is input from the information provider server 22 to the computer main body 10 via the network 21 and the network interface 12.
The clock circuit 13 outputs current date and time information. The display device 14 is a device capable of displaying two-dimensional image information and character information like a CRT monitor. The storage device 15 can be composed of, for example, a hard disk.
[0024]
In a storage area on the storage device 15, an actual rainfall DB (database) 16, a predicted rainfall DB 17, and calculated rainfall information DBs 18 and 19 are formed.
The computer body 10 performs various calculation processes using the rainfall information received from the telemeter and the predicted rainfall information received from the information provider server 22, and finally displays a debris flow determination diagram as shown in FIG. It is displayed on the screen of the device 14. This display is updated, for example, every 10 minutes.
[0025]
On the debris flow determination diagram, a snake curve SL and a debris flow occurrence danger reference line CL are displayed as shown in FIG. In this example, the time information TD indicating the time corresponding to each point on the snake curve (the time of the latest rainfall information used for calculating the point) is displayed at predetermined time intervals (one hour interval in FIG. 9). Is done. Each time information TD is arranged at a position apart from each point on the snake curve. In addition, an instruction line TL that connects each point on the snake curve and the corresponding time information TD is displayed.
[0026]
In FIG. 9, the snake curve SL is represented by a solid line and a dotted line. The part indicated by the solid line is the actual information reflecting only the actual rainfall information before the present, and the part indicated by the dotted line is the predicted information calculated including the predicted rainfall ahead of the present.
Various kinds of rainfall information can be applied to the numerical value of the horizontal axis and the numerical value of the vertical axis of the graph when the snake curve SL is displayed, but in this example, “effective rainfall” is applied to the horizontal axis, and the vertical axis is used. "1 hour rainfall intensity" is applied to.
[0027]
In addition, refer to the document "General debris flow countermeasures (II): Guidelines for setting the amount of rainfall for issuing warnings and evacuation instructions for landslide disasters, supervising the Sabo Department of the River Bureau, Ministry of Construction, Planning Department of the Sabo PR Center" To calculate the snake curve SL.
According to the literature, a group of rainfalls in which there is no rainfall (including a rainfall of 0 mm) for more than 24 hours before and after is referred to as a series of rainfalls, and the rainfall is referred to as a continuous rainfall. Also, the rainfall up to one week (168 hours) before that is counted from the start time of the series of rainfall is referred to as “previous rainfall”, and the amount of rainfall is referred to as “previous rainfall”.
[0028]
“Effective rainfall” is an integrated rainfall taking into account the influence of “previous rainfall”. Further, “1 hour rainfall intensity” is a rainfall converted per hour. In this example, since the actual rainfall is observed every 10 minutes, the “one hour rainfall intensity” can be obtained by multiplying the obtained actual rainfall by six.
As shown in FIG. 6, the actual rainfall DB 16 of FIG. 3 holds the date, time, previous term effective rainfall, 10-minute rainfall, 1-hour rainfall intensity, integrated rainfall, and effective rainfall information at each point in time, and new data is stored. When input, the information at each time point is sequentially added.
[0029]
The effective rainfall in the previous period in FIG. 6 indicates the influence of “previous rainfall” and is calculated from the past actual rainfall. The 10-minute rainfall in FIG. 6 is the latest actual 10-minute rainfall input from the telemeter. The date and time in FIG. 6 are information on the date and time when the rainfall for 10 minutes was input.
The one-hour rainfall intensity in FIG. 6 is a value obtained by doubling the amount of rainfall for 10 minutes at that time. The integrated rainfall in FIG. 6 is a value obtained by integrating the actual rainfall after the “previous rainfall”. The effective rainfall in FIG. 6 is a value obtained by adding the accumulated rainfall at that time to the effective rainfall in the previous period in FIG.
[0030]
As shown in FIG. 8, the information on the date, the predicted time, the effective rainfall in the previous term, the hourly rainfall intensity, the integrated rainfall, and the effective rainfall at each time point in the future is stored in the predicted rainfall DB 17 in FIG. Then, the information at each time point is sequentially added.
In this example, the one-hour predicted rainfall at each time point of one hour, two hours, three hours,... From the present time can be acquired from the server 22 of the information provider. The one-hour predicted rainfall in FIG. 8 is the predicted rainfall at each time point acquired from the server 22. The date and predicted time in FIG. 8 are date and time information associated with each hourly predicted rainfall.
[0031]
The effective rainfall in the previous period in FIG. 8 indicates the influence of “previous rainfall”, and is obtained by calculation from the past actual rainfall. The integrated rainfall in FIG. 8 is a value obtained by integrating the actual rainfall after the “previous rainfall” and the predicted rainfall up to that time. The effective rainfall in FIG. 8 is a value obtained by adding the integrated rainfall at that time to the effective rainfall in the previous period in FIG.
The solid line portion of the snake curve SL in FIG. 9 can be drawn based on the effective rainfall at each time point and the one-hour rainfall intensity in the actual rainfall DB16, and based on the effective rainfall amount at each time point and the one-hour predicted rainfall in the predicted rainfall DB17. Thus, the dotted line portion of the snake curve SL can be drawn.
[0032]
Actually, information on the coordinates of each point before the current point of the snake curve SL calculated based on the contents of the actual rainfall DB 16 is stored in the calculated rainfall information DB 18 and calculated based on the contents of the predicted rainfall DB 17. Since the information on the coordinates of each point n hours after the present of the snake curve SL is stored in the calculated rainfall information DB 19, the snake curve SL of FIG. 9 is drawn based on the contents of the calculated rainfall information DBs 18 and 19. .
[0033]
As shown in FIG. 7, the calculated rainfall information DB 18 holds the time tm, the coordinates (Px, Py) on the snake curve, and the display coordinates (X, Y) of the time every 10 minutes, as shown in FIG. The same applies to the calculated rainfall information DB 19.
Next, the actual operation of the device shown in FIG. 3 will be described. The program executed by the computer main body 10 realizes the operations shown in FIGS. Each step in FIGS. 4 and 5 will be described below.
[0034]
In the first step S40, an initial screen is displayed. That is, the scale of each axis of the debris flow determination diagram shown in FIG. 9, the debris flow generation danger reference line CL, the character string of "effective rainfall (mm)", the character string of "one hour rainfall intensity (mm)", and the like are displayed.
In this example, the actual rainfall input timing is periodically set once every 10 minutes, and each time the process proceeds from step S40 to S42 through S41. In step S42, information (observation data and observation time) of the latest actual rainfall for 10 minutes (10 minutes ago to the present) is input from the telemeter.
[0035]
In step S43, the actual rainfall information (observation data and observation time) acquired from the telemeter in step S42 is stored in the actual rainfall DB 16. In one process of step S43, the information of “date”, “time”, and “10-minute rainfall” regarding one time in FIG. 6 is written to the actual rainfall DB 16.
It should be noted that the effective rainfall in the previous year in the actual rainfall DB 16 is calculated in advance based on the actual data of “precipitation rainfall”.
[0036]
In step S44, the one-hour rainfall intensity of the actual rainfall is calculated. In this example, since the actual rainfall obtained from the telemeter is “10-minute rainfall”, the result obtained by multiplying the value by 6 is defined as the 1-hour rainfall intensity. The hourly rainfall intensity is written in the actual rainfall DB 16.
In step S45, the current effective rainfall is calculated. First, the accumulated rainfall up to the present time is obtained, and the result obtained by adding the effective rainfall in the previous term to the obtained rainfall is defined as the effective rainfall. The accumulated rainfall up to the present time is obtained by adding the actual rainfall (10-minute rainfall) input in step S42 to the accumulated rainfall at the time 10 minutes before in the actual rainfall DB 16.
[0037]
In the case of the actual rainfall DB 16 shown in FIG. 6 as an example, if the current time is “20:50”, the accumulated rainfall (2) at the time “20:40” is the 10-minute rainfall at the time “20:50”. The result of adding (1) is defined as the integrated rainfall (3) at the time “20:50”. The result obtained by adding the effective rainfall (14) in the previous period to the accumulated rainfall (3) at the time “20:50” is defined as the effective rainfall (17) at the time “20:50”.
[0038]
In step S46, the coordinates of the current point on the snake curve are calculated based on the values of the effective rainfall and the one-hour rainfall intensity at the current time on the actual rainfall DB 16. In step S47, the current time tm is input. Then, the coordinates (Px, Py) of the point obtained in step S46 and the current time tm in step S47 are stored in the calculated rainfall information DB 18.
[0039]
On the other hand, in this example, the predicted rainfall input timing is periodically set once a hour, and each time the process proceeds from step S40 to S50 through S41 and S49. In step S50, the latest information of the predicted rainfall (rainfall per hour) at each time point of one hour, two hours, three hours,... Is input from the server 22 of the information provider.
[0040]
In step S51, the information on the predicted rainfall at each point in time n hours after input in step S50 is stored in the predicted rainfall DB 17 together with the information on the predicted time (including the date). That is, the date, the predicted time, and the one-hour predicted rainfall are written in the predicted rainfall DB 17. In step S53, the effective rainfall at each point in time after n hours is calculated using the predicted rainfall. First, the accumulated rainfall up to each time point is obtained, and the result obtained by adding the effective rainfall in the previous term thereto is defined as the effective rainfall.
[0041]
For example, the accumulated rainfall one hour later can be obtained as a result of adding the one-hour predicted rainfall one hour later to the accumulated rainfall up to the present (the value on the actual rainfall DB 16). Further, the effective rainfall after one hour can be obtained as a result of adding the previous term effective rainfall to the integrated rainfall after one hour. The result of each calculation is stored in the predicted rainfall DB 17.
In step S54, the coordinates of points on the snake curve are calculated based on the values of the effective rainfall and the one-hour forecast rainfall at each time point n hours later on the predicted rainfall DB17. In step S55, the current time tm is input. Then, the coordinates (Px, Py) of each point obtained in step S54 and information on the corresponding predicted time (tm + 1, tm + 2, tm + 3,...) Are stored in the calculated rainfall information DB 19 in step S56.
[0042]
When the data of the calculated rainfall information DB 18 or 19 is updated by the input of the actual rainfall information from the telemeter or the input of the predicted rainfall information from the server 22 of the information provider, the flow proceeds through steps S40, S41, S49, and S60. The process proceeds to step S61 of No. 5.
[0043]
In step S61, the display of the snake curve, time, and the like drawn before that is erased in preparation for redrawing.
In step S62, display processing is performed for each of the current and past points of the snake curve. Step S62 is repeatedly executed until the processing is completed for all the current and past displayable points. When this process ends, the process advances to the step S64 through the step S63.
[0044]
In step S64, display processing is performed for each point n hours after the snake curve. Step S64 is repeatedly executed until the processing is completed for all the displayable points after n hours.
Details of the display processing in steps S62 and S64 are as shown in FIGS. Each step in FIGS. 1 and 2 will be described below.
[0045]
In step S10, the calculated rainfall information (Px, Py, tm) for one point of the snake curve is input from the calculated rainfall information DB 18 or 19. That is, in the case of the display process in step S62 of FIG. 5, the calculated rainfall information DB 18 is a processing target, and in the case of the display process of step S64 in FIG. 5, the calculated rainfall information DB19 is a processing target.
[0046]
In this example, the points on the snake curve and the time information TD thereof are drawn sequentially in the order of time. For the points already drawn, the information of the display coordinates (X, Y) of the time information TD of each point is temporarily stored in the internal memory of the computer main body 10. In addition, the number Dcnt of display points that have been drawn is also stored in the internal memory.
In step S11, the display coordinates of the time information TD of all the drawn points are obtained as (Xn, Yn).
[0047]
In step S12, the value of the center coordinates (xc, yc) of the area displaying the debris flow determination diagram of FIG. 9 is obtained. Note that the coordinates of a specific reference position may be used instead of the center coordinates (xc, yc).
In step S13, Py and yc are compared for one point on the snake curve input in step S10. If (Py> yc), the process proceeds to step S14, and "1" is set to the direction flag Fdir. If (Py ≦ yc), the flow advances to step S15 to set “−1” to the direction flag Fdir.
[0048]
In step S16, the display coordinates of the time (the coordinates of the reference position where the time information TD is drawn: X, Y) are determined by the following equation.
X = Px + Xmov
Y = Py + Ymax · (−Fdir)
Xmov, Ymax: constant
That is, the distance from the coordinates (Px, Py) of one point on the snake curve is determined by the constants Xmov, Ymax (see FIG. 10). Further, the position changes according to the direction flag Fdir.
[0049]
That is, when the coordinates (Px, Py) of one point on the snake curve are below the coordinates (xc, yc) of the center point, the position of the display coordinates at the time is based on the coordinates (Px, Py). Are also arranged on the upper side, and when the coordinates (Px, Py) of one point on the snake curve are above the coordinates (xc, yc) of the center point, the position of the display coordinates at the time is the coordinates (Px, Py). Py).
[0050]
In step S20 of FIG. 2, the number of drawn display points Dcnt is acquired.
The processing of steps S21 to S26 is repeatedly executed as a loop. When this loop is first executed, the counter i is preset to 1 in step S21, and after the second time, the counter i is incremented (+1) in step S21. The loop is repeated while (i <Dcnt).
[0051]
In this loop, the presence / absence of overlap between the time display coordinates (X, Y) determined in step S16 and all the drawn time information TD is identified. In step S22, a comparison of (X + W + Di <Xn) or a comparison of (X <Xn + W + Di) is performed to check whether there is any overlap in the horizontal axis direction. In step S23, a comparison of (Y + H + Di <Yn) or a comparison of (Y <Yn + H + Di) is performed to check whether there is any overlap in the vertical axis direction.
[0052]
Xn: X of the drawn time information TD corresponding to the value of i
Yn: Y of the drawn time information TD corresponding to the value of i
W: horizontal width of time information TD (constant)
H: Vertical height of time information TD (constant)
Di: display interval (constant)
If there is no overlap, “true” is set in step S24, and if there is overlap in at least one of the vertical and horizontal directions, “false” is set in step S25.
[0053]
In step S27, it is determined whether or not an overlap has been detected as a result of executing the loop of steps S21 to S26. If "false" is set for at least one piece of the drawn time information TD, there is an overlap, and the process proceeds from step S27 to S28.
In order to avoid overlap, in step S28, Y of the coordinates (X, Y) determined in step S16 is corrected by the following equation.
[0054]
Y = Y + (H + Di) · (Fdir)
By the process of step S28, for example, the coordinates (X, Y) are automatically corrected before drawing as shown in FIG. After this correction, the process returns to step S21 to check for the presence or absence of overlap. If the overlap cannot be avoided by one correction, step S28 is repeatedly executed until the overlap is eliminated.
[0055]
However, if the correction only in the vertical axis direction is repeated, the point on the snake curve and the time information TD approach so that the snake curve and the time become difficult to see. Therefore, in step S29, a comparison of (Y−Py <Ymin) is performed using the constant Ymin, and when the point on the snake curve approaches the time information TD, the process proceeds to step S30.
In step S30, Y is returned to the value before correction by the value of Yo (see step S16) holding the value of Y before correction, and X is further corrected to move the position of the time information TD in the horizontal direction. .
[0056]
If there is no overlap from the beginning, or if there is no overlap due to the correction in steps S28 and S30, the process proceeds from step S27 to S31.
In step S31, the coordinates (X, Y) or corrected coordinates (X, Y) determined in step S16 and the time tm are stored as display information. At the time when step S31 is completed, data of tm, Px, Py, X, and Y are held in the columns of each time of the calculated rainfall information DB 18 or 19 as shown in FIG.
[0057]
In step S32, the coordinates (Px, Py) of two adjacent points arranged in chronological order are acquired from the calculated rainfall information DB 18 or 19, and a line segment connecting those points is drawn. By repeatedly executing step S32, a snake curve SL connecting the points is drawn as shown in FIG.
In step S33, the coordinates (Px, Py) of the point associated with one time tm and the coordinates (X, Y) indicating the time are acquired from the calculated rainfall information DB 18 or 19, and they are connected. Two line segments are drawn as the instruction line TL.
[0058]
In step S34, one time tm and information of the coordinates (X, Y) associated therewith are acquired from the calculated rainfall information DB 18 or 19, and the time tm is set at a position based on the coordinates (X, Y). Is drawn as shown in FIG.
(Second embodiment)
Another embodiment of the debris flow determination diagram display device of the present invention will be described with reference to FIGS. This embodiment corresponds to claims 5 and 6.
[0059]
FIG. 12 is a block diagram showing the configuration of the device of this embodiment. FIG. 13 is a schematic diagram illustrating a configuration example of the actual disaster DB. FIG. 14 is a flowchart showing the operation of the apparatus of this embodiment. FIG. 15 is a front view showing a display example of the debris flow determination diagram of this embodiment. This embodiment is a modification of the first embodiment.
12 and 14, elements and steps corresponding to those of the first embodiment are denoted by the same reference numerals and numbers. For the same parts as those in the first embodiment, the following description is omitted.
[0060]
In this embodiment, the disaster result data holding means of claim 5 corresponds to the result disaster DB 31, and the disaster result display means of claim 5 corresponds to step S71.
Referring to FIG. 12, this device includes a computer main body 10B, a communication interface 11, a clock circuit 13, a display device 14, and a storage device 15B. Further, an actual rainfall DB 16, a calculated rainfall information DB 18, and an actual disaster DB 31 are formed on the storage device 15B.
[0061]
The actual disaster DB 31 holds actual information on disasters that occurred in the past. Specifically, as shown in FIG. 13, data of date, hourly rainfall intensity, effective rainfall, type, display coordinates (horizontal axis), and display coordinates (vertical axis) are stored in the actual disaster DB 31 as actual disaster information. Is held.
In this example, four types of result information of debris flow (occurrence), frequent occurrence of collapse, small occurrence of collapse, and non-occurring rainfall are held in the actual disaster DB 31. The type of the result information is stored in the result disaster DB 31 as type information as shown in FIG.
[0062]
The past disaster information stored in the actual disaster DB 31 is displayed on the screen of the display device 14 so as to overlap with the debris flow determination diagram as shown in FIG. The display position of each result information on the result disaster DB 31 is calculated in advance based on the hourly rainfall intensity and the effective rainfall and the arrangement of the scale on the debris flow determination diagram, and the display coordinates (horizontal axis) and the display coordinates (vertical axis). Is stored in the actual disaster DB 31.
[0063]
The device shown in FIG. 12 performs the operation shown in FIG. 14 under the control of the computer main body 10B. Steps S40 to S48 and S60 to S63 in FIG. 14 are the same as those in the first embodiment.
In step S71 of FIG. 14, information of each disaster is displayed on the screen of the display device 14 based on each result information held in the result disaster DB 31. That is, as shown in FIG. 15, a specific mark corresponding to the type of disaster is displayed at the position of coordinates corresponding to the one-hour rainfall intensity and effective rainfall of each disaster. In addition, for a disaster of “debris flow occurrence”, a character string of the date when the disaster occurred is displayed near the mark, and an arrow indicating line connecting the character string and the corresponding mark is further displayed.
[0064]
【The invention's effect】
According to the first aspect, the forecaster can read the time-series change of the past rainfall information from the order of the displayed times. The forecaster can also predict future changes to some extent based on the time-series change pattern of past rainfall information, the amount of movement of display points per unit time, and the like.
[0065]
According to the second aspect, the time can be displayed at a position away from the snake curve. Further, the correspondence between the position of each display point and the time can be easily read from the connection state of the displayed line segments.
According to the third aspect, it is possible to prevent times of a plurality of adjacent display points from overlapping each other.
[0066]
According to the fourth aspect, since the snake curve at a point earlier than the present time is displayed, the forecaster can foresee the debris flow with a sufficient time margin before the risk of occurrence of the debris flow increases. . Therefore, it is possible to effectively prevent occurrence of a disaster due to a delay in notification or evacuation.
According to claim 5, since the information of the disaster that actually occurred in the past is displayed on the debris flow determination diagram, the forecaster can compare the past disaster with the current debris flow determination diagram to determine the risk of debris flow occurrence. You can foresee it before it gets high.
[0067]
According to the sixth aspect, since the results of a plurality of types of past disasters are displayed for each type, the forecaster can more accurately recognize the possibility of occurrence of the disaster.
[Brief description of the drawings]
FIG. 1 is a flowchart illustrating details of a display process (1) according to a first embodiment.
FIG. 2 is a flowchart illustrating details of a display process (2) according to the first embodiment.
FIG. 3 is a block diagram illustrating a configuration of a device according to the first embodiment.
FIG. 4 is a flowchart showing an operation (1) of the apparatus according to the first embodiment.
FIG. 5 is a flowchart showing an operation (2) of the device according to the first embodiment.
FIG. 6 is a schematic diagram illustrating an example of the configuration of an actual rainfall DB.
FIG. 7 is a schematic diagram showing a configuration example of a calculated rainfall information DB (1).
FIG. 8 is a schematic diagram illustrating a configuration example of a predicted rainfall DB.
FIG. 9 is a front view illustrating a display example of a debris flow determination diagram according to the first embodiment.
FIG. 10 is a front view showing an example of determining display coordinates of time.
FIG. 11 is a front view showing an example of changing the time display coordinates.
FIG. 12 is a block diagram illustrating a configuration of a device according to a second embodiment.
FIG. 13 is a schematic diagram illustrating a configuration example of a record disaster DB.
FIG. 14 is a flowchart illustrating an operation of the device according to the second embodiment.
FIG. 15 is a front view illustrating a display example of a debris flow determination diagram according to the second embodiment.
[Explanation of symbols]
10. Computer body
11 Communication interface
12 Network interface
13 Clock circuit
14 Display device
15 Storage device
16 Actual rainfall DB
17 Predicted rainfall DB
18,19 Calculated rainfall information DB
21 Network
22 Information provider server
31 Actual Disaster DB

Claims (6)

A debris flow determination diagram display that displays a debris flow determination diagram representing a correspondence relationship between first rainfall information according to past rainfall during the first period and second rainfall information according to past rainfall during the second period. A device,
Time acquisition means for acquiring information on the calculation time of the first rainfall information and the second rainfall information;
A time storage unit that stores the first rainfall information and the second rainfall information and the information of the time at which the information was obtained in association with each of a plurality of different time points;
Near the position of each display point on the debris flow determination diagram determined from the first rainfall information and the second rainfall information at each time point, information on the time associated with the first rainfall information and the second rainfall information And a time display means for acquiring and displaying the information from the time storage means. The debris flow determination diagram display device according to claim 1,
Coordinate comparing means for determining a relative position between the coordinates of the display point and the coordinates for displaying the time in accordance with the comparison result between the position of each display point on the debris flow determination diagram and a predetermined reference position on the display area. ,
An apparatus for displaying a debris flow determination diagram, further comprising an instruction line display unit for displaying a line segment connecting the position of each display point on the debris flow determination diagram and the display position of time. Debris flow determination diagram display apparatus odor Te claim 1,
A plurality of display points are sequentially displayed on the debris flow judgment diagram, and the time display area of each display point displayed in the past and the time display area of the next display point are checked for overlap and the overlap is detected. A debris flow judging diagram display device further comprising a display position changing means for automatically moving the time display position of the next display point to be displayed in the event of a change. The debris flow determination diagram display device according to claim 1,
Predicted rainfall input means for inputting information of predicted rainfall related to rainfall after the current time,
A debris flow determination diagram display, comprising: a debris flow determination diagram that displays a debris flow determination diagram including information on predicted rainfall after the current time based on the information on the predicted rainfall input by the predicted rainfall input device. apparatus. The debris flow determination diagram display device according to claim 1,
Disaster result data holding means for holding at least result data of rainfall information relating to a disaster that occurred in the past,
A debris flow determination chart display device, further comprising: disaster result display means for superimposing and displaying information of the result data input from the disaster result data holding means on the debris flow determination chart. In Debris determination view display device according to claim 5, wherein the disaster actual data holding means stage holds the actual data indicating the type of each disaster that occurred in the past, the disasters actual result display unit inputted from the disaster actual data holding means A debris flow judgment diagram display device, wherein the display is changed according to the type of disaster in the result data.

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