JP5538449B2 - Ground strength judgment device and ground strength judgment method - Google Patents

Description

  The present invention relates to a ground strength determination device and a ground strength determination method.

Conventionally, an apparatus that displays ground strength at a predetermined coordinate position on a map is known (see, for example, Patent Document 1).
The ground data system described in Patent Document 1 performs ground inspection by a ground survey device in a building site of a construction site, and outputs ground data obtained by the ground survey device to a server via the Internet. Then, when a search request for ground data at a predetermined point is made from the personal computer, the server outputs a map in which icons corresponding to the strength of the ground are superimposed on the personal computer.

JP 2000-47574 A

By the way, the ground data system as described in Patent Document 1 displays ground data measured by a ground survey device on a map at a construction site or the like. Therefore, it is not possible to display the ground strength for a point where the ground data is not measured by the ground survey device. In addition to the problem that the measurement of ground data by a ground survey device is expensive and requires a large-scale measurement device, it is not possible to measure the ground strength at points where buildings already exist. There is a problem.
On the other hand, when it is desired to know the ground strength for an arbitrary point, it may be possible to use a map showing the ground strength issued by a public institution. However, this map is a map in which the rough ground strength for each region is estimated from the range affected by the measured values based on the measured values obtained by the ground survey device, etc., and it is difficult to obtain the ground strength at an arbitrary point. There is a problem.

  An object of this invention is to provide the ground strength determination apparatus and ground strength determination method which can determine the ground strength in an arbitrary point easily.

The ground strength determination device of the present invention includes a point acquisition unit that acquires a position and an altitude of a ground strength measurement target point, an old map storage unit that stores an old map in which a past altitude at a predetermined point is recorded, and the measurement Past altitude acquisition means for acquiring a past altitude that is the altitude of the old map corresponding to the target point, and ground determination means for determining the ground strength of the measurement point based on the altitude of the measurement target point and the past altitude And the ground determination means uses an altitude change amount that is a difference between the altitude of the measurement target point and the past altitude as an index, and when the altitude of the measurement target point is higher than the past altitude, It is determined that the ground strength is weak according to the altitude change amount, and when the altitude at the measurement target point is lower than the past altitude, it is determined that the ground strength is strong according to the altitude change amount.

  In the present invention, the ground strength at any measurement target point can be easily determined.

The block diagram which shows schematic structure of the ground strength determination system which is the ground strength determination apparatus which concerns on 1st embodiment of this invention. The flowchart which shows the ground determination process by the ground strength determination system of 1st embodiment. The figure which shows the example of distribution of the altitude change amount centering on a measurement object point. Explanatory drawing for demonstrating valley determination by a valley determination means. Explanatory drawing for demonstrating valley shape determination by a valley determination means. Explanatory drawing for demonstrating the difference in the ground strength by an altitude change amount. The figure which shows the example of a display of the ground strength determination result in 2nd embodiment. The figure which shows the example of a display in the case of designating a measuring object point from a map.

[First embodiment]
Hereinafter, a first embodiment according to the present invention will be described with reference to the drawings.
[Schematic configuration of ground strength judgment system]
FIG. 1 is a block diagram showing a schematic configuration of a ground strength determination system which is a ground strength determination device according to a first embodiment of the present invention.
As shown in FIG. 1, the ground strength determination system 1 includes a terminal device 10 and a server device 20 that are connected to each other via a network 2 (Internet).
The ground strength determination system 1 of the present embodiment is a device that measures the ground strength of soil at the current position measured by the terminal device 10. Therefore, it is preferable that the terminal device 10 includes a position measurement unit that can acquire a current position that is a measurement target point. As such a terminal device 10, it is preferable to use portable terminal devices, such as a mobile phone and a smart phone, for example. In the present embodiment, a mobile terminal device is illustrated as the terminal device 10, but the present invention is not limited to this. That is, for example, an arbitrary measurement target point may be input by a fixed-side terminal device such as a personal computer, and the ground strength with respect to the input position of the measurement target point may be determined.

  The network 2 is the Internet based on a general-purpose protocol such as TCP / IP, but is not limited to this. For example, any configuration that transmits and receives data can be used, such as a local area network (LAN) and a communication network in which a plurality of base stations capable of transmitting and receiving information via a wireless medium constitute a network.

[Configuration of terminal device]
As shown in FIG. 1, the terminal device 10 includes, as a hardware configuration, a terminal storage unit 11 configured by a memory or the like, a display unit 12, an operation unit 13 configured by a touch panel, a keyboard, a mouse, and the like, Based on satellite signals from position measurement satellites such as GPS satellites, position measurement means 14 for measuring the current position and terminal control means 15 constituted by a CPU (Central Processing Unit) and the like are provided. In addition, the terminal device 10 includes terminal communication means (not shown) for communicating with the server device 20 via the network 2.

  The terminal storage unit 11 includes, for example, a RAM (Random Access Memory) having a temporary area in which data such as a map transmitted from the server device 20 and ground strength determination results can be temporarily stored, an OS (Operating System), Various programs, various applications, ROM (Read Only Memory) storing various data, and the like are provided.

  The position measurement means 14 receives satellite signals having time information transmitted from, for example, three position measurement satellites (for example, GPS satellites) and, based on these satellite signals, 3 of the current position serving as a measurement target point. Axis coordinates (latitude, longitude, altitude) are calculated (hereinafter, coordinate calculation of the measurement target point by the position measuring means 14 may be referred to as “positioning”).

The terminal control unit 15 functions as a point acquisition unit 151 and a display control unit 152 as shown in FIG. 1 by reading and executing various programs stored in the terminal storage unit 11.
The point acquisition unit 151 causes the position measurement unit 14 to perform current position measurement processing based on the operation of the operation unit 13 by the user, and acquires the current position and the altitude of the current position.
The display control unit 152 causes the display unit 12 to display the ground strength determination result transmitted from the server device 20.

[Configuration of server device]
As shown in FIG. 1, the server device 20 includes a server storage unit 21 configured by a memory or the like and a server control unit 22 configured by a CPU or the like as a hardware configuration. Further, the server device 20 includes server communication means (not shown) for communicating with the terminal device 10 via the network 2.

The server storage unit 21 includes a RAM having a temporary area that can temporarily store various data, an OS, various programs, various applications, a ROM that stores various data, a hard disk that stores various data and various programs, and the like. including.
The server storage unit 21 includes a current map storage unit 211 that stores a current map (current map), an old map storage unit 212 (an old map storage unit) that stores an old map that is a past map, and an altitude. A data storage unit 213 (elevation data storage unit) and a land improvement data storage unit 214 (land improvement data storage unit) are provided. The server storage unit 21 also functions as a reference data storage unit, and stores strength determination reference data used in ground determination processing described later.

The current map stored in the current map storage unit 211 is a current map. In the present embodiment, the elevation for each point is associated and stored as the current map. That is, in the current map storage unit 211, mesh data in which the altitude of each point on the map is recorded based on the contour line is recorded and associated with the current map. As mesh data indicating such altitude, for example, mesh data used in the Geographical Survey Institute, etc. can be used. The mesh data is created with a mesh having a main part on the map at intervals of 5 m and other areas at intervals of 10 m. ing.
When a map associated with elevation is recorded as described above, for example, the current map is updated at regular intervals (for example, every year), and the current map before the update is stored in the old map storage unit 212. Can do.

  The old map recorded in the old map storage unit 212 is a past map, and a plurality of old maps having different created times are stored. Similar to the current map, the old map is associated with mesh data indicating the altitude, and further records geographical information such as past land use status and water area characteristics.

In addition, as an old map, for example, if it is a map in Japan, it is preferable to record a map after the 1870s in which altitude surveying techniques are generally popular. Here, in an old map with an old age, it may be possible that there is a point where the accuracy of surveying the altitude is low or not surveyed, and therefore, as described above, a plurality of old maps with different age are recorded.
Note that the current map stored in the current map storage unit 211 is updated to the latest current map at regular intervals (for example, every year), and the current map before being updated is newly used as the old map storage unit. 212 may be stored.

  The altitude data accumulating unit 213 constitutes altitude data accumulating means of the present invention, and is transmitted from the terminal devices 10 of all users using the ground strength determination system 1, that is, the positioning results by the position measuring means 14, that is, the positioning is performed. Data in which the location and the altitude at that location are associated with each other are stored.

In the land improvement data storage unit 214, an area (artificial improvement area) where artificial land improvement (land improvement work) has been carried out in the past, a land improvement method in the artificial improvement area, and a time when the land improvement work was executed Land improvement data associated with these and the like are stored.
In addition, as described above, when the current map is updated at regular intervals, and the current map before the update is stored in the old map storage unit 212 as an old map, the land improvement work performed within the regular period The land improvement data regarding the land improvement data storage unit 214 may be accumulated and stored.

  The server control unit 22 reads and executes various programs stored in the server storage unit 21, and as shown in FIG. 1, the past elevation acquisition unit 221, the elevation change calculation unit 222, and the past water field determination unit 223. , Function as a change area specifying unit 224, a valley determining unit 225, and a ground determining unit 226.

  The past altitude acquisition means 221 is based on the positioning result (positional coordinates and altitude of the measurement target point) transmitted from the terminal device 10, and the oldest age at which the altitude of the measurement target point is recorded (the oldest measurement time). ) Read the old map. And the past altitude acquisition means 221 acquires the altitude (past altitude) of the measurement target point based on the read old map.

  The elevation change amount calculation means 222 calculates an elevation change amount that is a difference value between the elevation of the positioning result and the past elevation acquired by the past elevation acquisition means 221.

  The past water field determination unit 223 acquires the land use form of the measurement target point, the characteristics of the water area, and the like based on the old map acquired by the past altitude acquisition unit 221, and whether or not the measurement target point is a water field. Determine. Here, the water fields include, for example, naturally formed water areas such as lakes, ponds, and rivers, and artificially formed water areas such as paddy fields and reservoirs.

The change area specifying unit 224 obtains an altitude change area that changes in the same direction as the altitude change direction calculated by the altitude change amount calculating unit 222 from the current altitude accumulated in the altitude data accumulation unit 213. For example, when the current altitude of the measurement target point is higher than the past altitude, an area that is similarly higher than the past altitude is obtained as the altitude change area.
The valley determination unit 225 acquires the elevation distribution of the elevation change area based on the old map acquired by the past elevation acquisition unit 221, and determines whether the measurement target point is a valley.
The ground determination means 226 is based on the elevation change calculated by the elevation change calculation means 222, the determination result by the past water field determination means 223 and the valley determination means 225, the elevation change area obtained by the change area specifying means 224, and the like. Then, the ground strength at the measurement target point is determined.
Note that specific processing performed by the server control unit 22 will be described later.

[Ground judgment processing by ground judgment system]
Next, ground strength determination processing using the ground strength determination system 1 as described above will be described based on the drawings.
FIG. 2 is a flowchart showing the ground strength determination process by the ground strength determination system 1.
[Ground determination point acquisition processing]
As shown in FIG. 2, when an application for determining the ground strength at the measurement target point is executed in the terminal device 10, the terminal control unit 15 of the terminal device 10 controls the position measurement unit 14 to The position coordinates and altitude of the position are measured (S101).
Next, the terminal control means 15 transmits the positioning result of S101 to the server apparatus 20 using a terminal communication means (not shown) (S102).

[Ground determination index acquisition processing]
When the server control unit 22 of the server device 20 receives the positioning result transmitted from the terminal device 10 using a server communication unit (not shown) (S201), the past altitude acquisition unit 221 uses the old altitude corresponding to the measurement target point. The map is read from the old map storage unit 212 (S202).
Specifically, the past altitude acquisition means 221 reads out the oldest age old map among the old maps in which the altitude for the positioning target point is stored, and calculates the altitude (past altitude) of the measurement target point in the read old map. Obtain (S202).
Thereafter, the altitude change calculation means 222 calculates an altitude change that is the difference between the past altitude acquired in S202 and the current altitude of the measurement target point received in S201 (S203). Further, the altitude change amount calculating unit 222 stores the calculated altitude change amount in, for example, a temporary storage area of the server storage unit 21.
Thereafter, the past water field determination means 223 determines whether or not the measurement target point is a water field from the geographical state of the measurement target point recorded in the old map read out in S202, and stores the determination result in, for example, a server storage The data is stored in the temporary storage area of the means 21 (S204).

Further, the change area specifying unit 224 extracts a point within a predetermined distance range centered on the measurement target point from the points stored in the altitude data storage unit 213 as a comparison point, and calculates the altitude and the old value at the comparison point. The altitude change amount with the past altitude of the map is calculated, and the altitude change area is specified (S205).
FIG. 3A is a diagram showing an example of distribution of elevation change centered on the measurement target point P, and FIG. 3B is an example of a cross section in one direction (BB ′) passing through the measurement target point P. FIG. In FIG. 3, a point P indicates a measurement target point, and the other points indicate extracted comparison points. Also, at each point, “+” is displayed when the altitude change is positive (current altitude is higher), and “−” is displayed when the altitude change is negative (current altitude is lower). When the altitude change amount is “0”, the white circle is displayed.
The change area specifying unit 224 extracts a comparison point changing in the same direction as the measurement target point from the calculated elevation change amount of the comparison point (“+” in the case of FIG. 3), and calculates the maximum of the extracted comparison point. An area connecting the outer peripheral points is set as an elevation change area A.
Then, the change area specifying unit 224 calculates the area (elevation change area) of the set elevation change area A, and stores the elevation change area in the temporary storage area of the server storage unit 21, for example.

Furthermore, the valley determination means 225 determines whether or not the measurement target point has been a valley (part of a valley) in the past from the geographical state in the elevation change region centered on the measurement target point recorded in the old map read out in S202. Is determined (S206).
FIG. 4 is a schematic diagram for explaining valley determination by the valley determination means 225.
As shown in FIG. 4, the valley determination means 225 includes a point where the elevation is high at two points (for example, point Q in FIG. 4) sandwiching the measurement target point P in the elevation change area A of the old map, and When the past inclination shown in an old map is more than the predetermined angle (alpha), it determines with it being a trough. On the other hand, when there is no point where the elevation is high only at one of the two points across the measurement target point P, when there is no point higher than the measurement target point P, and when the elevation is high across the measurement target point P If there are two points, but the past inclination is less than the predetermined angle, it is determined that it is not a valley.
The valley determination by the valley determination means 225 is not limited to the above. For example, the valley determination unit 225 has an area where the altitude is higher than a predetermined value in the altitude change area A across the lowest altitude area where the altitude is lowest based on the mesh data of the past altitude corresponding to the old map. Whether or not a valley bottom exists in the altitude change region A may be determined.
And the change area specific | specification means 224 memorize | stores the flag information which shows whether a measuring object point is a trough in the temporary storage area of the server memory | storage means 21, for example.

If it is determined in S206 that it is a valley, it is further determined whether or not the elevation change amount calculated in S203 is “+” (S207). If it is determined in S207 that the altitude change amount is “+” (the current altitude is higher than the past altitude), the valley determination means 225 calculates an intensity estimation value for the altitude change area (S208). .
Specifically, the valley determination unit 225 calculates the average value of the altitude change (average altitude change) based on the altitude at the current comparison point stored in the altitude data storage unit 213 and the altitude change of the past altitude in the old map. (Quantity) is calculated as an intensity estimate. That is, as shown in FIG. 5, when valleys C1 and C2 having the same depth and the same altitude change region are compared, generally a substantially V-shaped valley C1 (valley crossing) The wedge-shaped valley of the surface shape tends to have a stronger ground strength than the valley C2 having a substantially U-shaped valley slope (the valley having a trough-shaped cross section). Here, when the valley C1 and the valley C2 are compared, the average elevation change amount of the valley C1 is smaller than the average elevation change amount of the valley C2. That is, the average elevation change amount can be used as an estimated strength value and can be used as one of the indexes for determining the ground strength.
In the present embodiment, the average elevation change is exemplified as the intensity estimated value. However, for example, the volume of soil accumulated in the valley and the density of accumulated soil may be estimated to be the intensity estimated value. In general, the ratio W / D between the width dimension W in the valley cross-sectional shape and the embankment thickness (maximum elevation change amount) D in the valley bottom is large in the bowl-shaped valley C2, and is small in the wedge-shaped valley C1. Therefore, the ratio W / D may be calculated as an estimated intensity value. In addition, for example, a more detailed intensity estimation value may be calculated using an average inclination angle of a valley bottom or the like.
Then, the valley determination unit 225 stores the average elevation change amount in the elevation change region that is the calculated intensity estimation value, for example, in the temporary storage region of the server storage unit 21.

[Judgment processing of ground judgment means]
Thereafter, the ground determination means 226 includes each determination element stored in the server storage means 21, that is, the elevation change amount calculated in S203, the determination result of the water field determination in S204, the elevation change area calculated in S205, The ground strength at the measurement target point is determined based on the determination result of the valley determination in S206, the average elevation change amount estimated in S208, and the like (S209).
Specifically, the ground determination unit 226 determines the ground strength based on the strength determination reference data stored in the server storage unit 21. Table 1 below shows an example of strength determination reference data.

FIG. 6 is a schematic diagram for explaining ground strength determination based on an altitude change amount. As shown in FIG. 6A, when the current altitude is higher than the past altitude (when it is determined that the altitude change amount is “+”), due to accumulation due to natural factors or due to artificial factors Embankment etc. can be considered. The ground where the altitude changes due to such accumulation and embankment becomes loose. At this time, the greater the change in elevation, the greater the amount of sediment and embankment, and the ground strength tends to be weakened.
On the other hand, as shown in FIG. 6B, when the current altitude is lower than the past altitude (when it is determined that the altitude change amount is “−”), weathering or erosion due to natural factors, artificial Cutting due to natural factors can be considered. Land whose altitude has changed due to such weathering, erosion, and cutting tends to be solid and strong. At this time, the greater the altitude change, the harder the ground strength. Therefore, as shown in Table 1, the ground determination means 226 can determine the ground strength by using the elevation change amount as one of the ground strength determination indexes.

  In addition, when the measurement target point has been a water field in the past, it is considered that the soil at the measurement target point contains a large amount of moisture. Thus, when the water content of the soil is large, the ground becomes loose, and therefore the ground strength tends to be weaker than in the case where no water field existed in the past. Therefore, the ground determination means 226 can determine the ground strength by using the determination result of the water field determination in S204, that is, whether or not it was a water field in the past as one of the ground strength determination indexes. .

And when the current altitude is higher than the past altitude (when the altitude change is “+”), whether the measurement target point is a valley, the shape of the valley, etc. The intensity changes. For example, as shown in FIG. 4, when embankment is performed on an inclined surface that is not a valley or on flat ground, there is no ground that supports the periphery of the embankment part (by slope protection work or earth retaining work that is weaker than the original ground) The slope is artificially supported). On the other hand, when embankment is carried out in the valley, the peripheral part of the embankment is supported by the inclined surfaces (ground surfaces D1, D2 in FIG. 4) facing each other.
Therefore, the ground determination means 226 can determine the ground strength by using the presence or absence of the valley determined in S206 as one of the ground strength determination indexes.

Further, as described above, even when the ground strength changes depending on the shape of the valley and the elevation change amount at the measurement target point is the same, the V-shaped valley C1 as shown in FIG. The ground strength tends to be stronger than the U-shaped valley C2 shown in (B). Therefore, when the past topography of the measurement target point is a valley, the shape of the valley is used as one of the ground strength determination indices, and the ground strength is determined.
In this embodiment, when determining the shape of the valley, when the average elevation change amount in the valley is ½ or more of the maximum elevation change amount (for example, the elevation change amount in the valley bottom) of the valley, Although it determines with it being the valley C2, it is not limited to this. For example, based on the average elevation change amount and the elevation change area, the embanked soil amount may be estimated, and the ground strength may be determined to be weaker as the soil amount is larger.

In addition to the above, when the current elevation is higher than the past elevation (when the elevation change is “+”), the ground determination means 226 is caused by artificial land improvement. It is determined whether it is due to natural or natural accumulation, and is used as one index for determining ground strength. For this purpose, the ground determination means 226 first searches whether or not the land improvement data stored in the land improvement data storage unit 214 has data for an area including the measurement target point. And when the data with respect to the area | region including a measuring object point cannot be searched in land improvement data, the ground determination means 226 determines that it is natural deposition (there is no artificial land improvement). On the other hand, when the data for the area including the measurement target point can be searched for in the land improvement data, the ground determination means 226 determines the ground strength based on the time when the construction was performed. In the present embodiment, the ground strength is determined separately before 1975 and after 1975. However, the present invention is not limited to this, and the ground strength may be determined for each smaller year.
Furthermore, in this embodiment, although the example which determines ground strength based on the age when land improvement was implemented is shown, you may determine ground strength based on the construction method of land improvement, for example. Further, the ground strength may be determined based on both the land improvement period and the land improvement method.
Furthermore, when the altitude change is “+”, the land may be raised by an earthquake. Such embankments are different from embankment and sedimentation, and the elevation of the original ground itself changes, and the ground strength tends to be relatively strong. Therefore, when the elevation change amount is “+”, the ground determination means 226 may further determine whether or not it is due to the elevation of the land.
In this case, for example, a survey result issued by a predetermined geographic measurement organization (for example, the Geographical Survey Institute) is stored in the server storage means. Then, when the elevation change amount at the measurement target point is “+”, the ground determination means 226 determines whether there is an uplift of the land due to the earthquake at the measurement target point based on the survey result. If there is a land bump, it is determined that the ground strength is strong.

On the other hand, when the current altitude is lower than the past altitude (when the altitude change amount is “−”), the ground determination means 226 further determines the altitude change based on the altitude change area set in S205. Estimate the cause of elevation change and determine the ground strength.
For this, the ground determination means 226 is a ground subsidence because it is rare that cutting is performed over a wide range when the area of the altitude change region is equal to or larger than a predetermined area threshold (for example, 1 km ² ). It is determined that the ground strength is weak. On the other hand, when the area of the altitude change region is less than a predetermined area threshold (for example, 1 km ² ), it is determined that the cut is performed in a narrow range, weathering or erosion, and the ground strength is determined to be strong. Therefore, the ground determination means 226 can determine the ground strength by using the elevation change region determined in S205 as one of the determination indexes.
In addition, in this embodiment, although it was determined whether it was ground subsidence or cut (or weathering and erosion) based on the elevation change area, it is not limited to this. For example, as land improvement data, it is determined whether or not cut work for the measurement target point is recorded, and when artificial improvement work is being carried out, it is determined that the ground strength is strong. Good.

Then, the ground determination means 226 acquires a determination point corresponding to the condition of the measurement target point based on the plurality of indices as described above and the strength determination reference data in Table 1. The ground determination means 226 is, for example, good when the determination point is 80 or more, slightly caution when the determination point is 60 or more and less than 80, caution when the determination point is 40 or more and less than 60, and the determination point is less than 40. In the case of (2), the ground strength determination result and the determination point are output to the terminal device 10 (S210).
And the display control means 152 of the terminal device 10 will display the received determination result on the display means 12, if the determination result is received from the server apparatus 20 (S103) (S104).

[Operational effects of this embodiment]
In the ground strength determination system 1 of the present embodiment, the point acquisition unit 151 of the terminal device 10 controls the position measurement unit 14 to measure the position information (latitude, longitude, altitude) of the current position that is the measurement target point, The positioning result is transmitted to the server device 20. Upon receiving the positioning result, the server device 20 acquires the old map from the old map storage unit 212 by the past altitude acquisition unit 221 and acquires the past altitude corresponding to the measurement target point. Then, the ground determination unit 226 determines the ground strength using the elevation change amount, which is the difference between the acquired past elevation calculated by the elevation change amount calculation unit 222 and the current elevation transmitted from the terminal device 10, as an index. To do.
For this reason, if the ground determination means 226 can acquire the altitude at the measurement target point, it can determine the ground strength by comparing with the past altitude of the old map. In addition, it is possible to measure the ground strength even when there is already a building on the land. Therefore, in this embodiment, the ground strength with respect to an arbitrary measurement target point can be easily investigated at low cost.

The terminal device 10 includes a position measuring unit 14. Then, the point acquisition unit 151 acquires the current position and altitude measured by the position measurement unit 14 as the position and altitude of the measurement target point.
For this reason, in this embodiment, the ground strength in the current position of the user of the terminal device 10 can be determined. Thereby, for example, when a user who plans to purchase land visits the site, the ground strength can be easily determined on the spot without using a large-scale device for measuring ground strength. In addition, it is possible to easily determine the ground strength at the current position in the event of a disaster such as an earthquake, and to contribute to securing a safe evacuation site.

  The ground determination unit 226 determines the ground strength corresponding to the elevation change amount calculated by the elevation change amount calculation unit 222 based on the strength determination reference data stored in the server storage unit 21. In such a configuration, if the strength determination reference data is stored in the server storage unit 21, a complicated calculation for determining the ground strength is unnecessary, and only the ground strength corresponding to the altitude change amount is read. The ground strength can be easily determined, and the processing speed can be increased.

The old map storage unit 212 stores a plurality of old maps having different measurement times (different ages created), and the past altitude acquisition means 221 includes a past altitude map in which past altitudes for the measurement target points are recorded. The past altitude is obtained from the old map with the oldest measurement time.
Thus, the reliability in ground strength determination can be improved by evaluating the ground of a measurement object point with respect to the measurement object point with respect to the oldest ground where land improvement is not performed.

The server device 20 determines whether or not the measurement target point has been a water field in the past by the past water field determination unit 223, and the ground determination unit 226 uses the determination result of the water field determination as one index to determine the ground strength. judge.
If there is a water field in the measurement target point in the past, it is likely that the water is poorly drained and the soil contains a lot of water, and the ground is loose. On the other hand, the ground determination means 226 of the present embodiment determines the ground strength using the water field determination result determined by the past water field determination means 223 as an index in addition to the altitude change amount, and thus more accurate ground. Strength determination can be performed.

The server device 20 includes an altitude data storage unit 213 that stores the positioning result transmitted from the terminal device 10, and the change area specifying unit 224 includes an object within a predetermined range centered on the measurement target point from the altitude data storage unit 213. A point is extracted, and further, a target point having the same direction of the elevation change calculated by the elevation change calculation means 222 is extracted. The change area specifying unit 224 specifies an altitude change area, which is an area where the altitude changes in the same direction, from the distribution of these target points. Then, when the elevation change amount is “−”, the ground determination means 226 considers cut, weathering, and erosion based on the area of the elevation change area, for example, if the elevation change area is less than the area threshold, If the altitude change region is equal to or greater than the area threshold, it is determined that ground subsidence has occurred and the ground is weak.
As described above, the ground determination means 226 determines the strength of the ground strength based on the area of the altitude change region even when the current altitude is lower than the past altitude, so that the accuracy is higher. The ground strength determination can be performed, and the reliability in the ground strength determination can be improved.

  Further, when the altitude change amount is “+”, the change area specifying unit 224 determines whether or not the altitude change area is a valley, and when the ground determination unit 226 is a valley, the ground strength is stronger. Is determined. As described above, when embankment or the like is simply performed on an inclined surface or flat ground, it is common to strengthen the ground by protecting the embankment periphery by slope protection or the like. In this case, the ground tends to be weaker than when the embankment is protected by the inclined surface of the valley. Therefore, by determining the ground strength using the determination result of the change area specifying unit 224 as one index as described above, the ground determining unit 226 performs the ground determination with higher accuracy from the land shape on which the embankment has been performed. be able to.

At this time, in the present embodiment, the change area specifying unit 224 further calculates an average elevation change amount in the elevation change region, and the ground determination unit 226 has an average elevation change amount of 1 of the maximum change amount in the elevation change region. The ground determination is carried out using one index as to whether it is larger than / 2.
As described above, even if the amount of elevation change at the measurement target point is the same, the V-shaped valley tends to have a stronger ground strength than the U-shaped valley. In the present embodiment, since the valley shape can be estimated and the ground strength can be determined based on the average elevation change amount, more accurate ground determination can be performed.

  Furthermore, when the elevation change amount is “+”, the ground determination means 226 searches the land improvement data stored in the land improvement data storage unit 214 for data for the measurement target point. Then, when there is no data for the measurement target point in the land improvement data, the ground determination means 226 determines that the altitude change is due to natural deposition and determines that the ground strength is weaker than that of the artificial embankment. Moreover, when there is data for the measurement target point in the land improvement data, the ground strength is determined based on the age when the land improvement work was performed. In this way, if it is an artificial elevation change, a natural elevation change, or if it is an artificial elevation change, whether the land improvement technology is due to an immature past, By determining the ground strength based on whether the technology has been developed recently, more accurate ground determination can be performed.

In the present embodiment, the ground judgment means 226 calculates the ground strength based on the strength judgment reference data including the elevation change, elevation change area, water field judgment, valley judgment, average elevation change, and land improvement construction time. Although it determines, it is not limited to this. For example, the ground determination means 226 may further use the place name at the measurement target point as one index for determining the ground strength.
In general, when a place name includes a word indicating terrain, the place name is often assigned based on the terrain. For example, if the place name includes a word that means a water field such as “river” or “pond”, an old map is created even if the measurement target point on the old map is not a water field. It is highly likely that there was a water field even before that time. Therefore, the ground determination accuracy can be further improved by performing the ground determination using words such as kanji included in the place name as another index.

In addition, other elements may be added as an index for ground determination. For example, an index based on the current map recorded in the current map storage unit 211 may be used. As an index based on the current map, for example, whether the current altitude is in the vicinity of “0” (for example, −5 m to +5 m) or a 0 m zone, whether water is within a predetermined distance range from the measurement target point. Whether or not there is a place, and if there is a water place, whether or not the altitude of the measurement target point is higher than the average water level may be added as a new index to determine the ground strength.
Even in such a case, if the determination point for each determination result is recorded in the strength determination reference data, the ground strength for the measurement target point can be easily determined.

[Second Embodiment]
Next, a second embodiment of the present invention will be described based on the drawings.
In the first embodiment, the terminal device 10 measures the current position by the position measuring unit 14 and transmits the positioning result to the server device 20 to determine the ground of the current position, and the display control unit 152 The result was received and displayed on the display means 12. On the other hand, in 2nd embodiment, the point acquisition means 151 differs in the point which determines the ground strength of the arbitrary points which the user input.
In addition, since each structure of the terminal device and server apparatus in 2nd embodiment is substantially the same as said 1st embodiment, it demonstrates below based on FIG.

FIG. 7 is a diagram illustrating an example of a determination result screen for ground strength determination displayed on the display unit 12 in the second embodiment.
As shown in FIG. 7, the display control unit 152 displays the ground strength determination result transmitted from the server device 20 in the result display column 31 at the top of the display unit 12. Further, the display control unit 152 displays a measurement target display field 32 indicating the position of the measurement target point at the lower part of the display unit 12.
When the ground determination is not performed, the result display column 31 may be blank or only the measurement target display column 32 may be displayed.

In addition to this, the display control means 152 evaluates the ground strength at the current position in the measurement object display field 32, determines the ground strength from an arbitrary point on the map, or designates an address to evaluate the ground strength. The measurement object selection unit 33 for selecting “” is displayed.
When the user inputs a selection for evaluating the ground strength at the current position, the terminal control unit 15 performs the same processing as in the first embodiment.

On the other hand, when the user inputs to determine the ground strength from an arbitrary point on the map, the display control unit 152 causes the display unit 12 to display a map as shown in FIG. This map is a map showing the current geographical state, and may be stored in the terminal storage unit 11, for example, and receives and displays the map stored in the current map storage unit 211 of the server device 20. May be.
When an arbitrary point on the map is designated by the user's input operation, the point acquiring unit 151 sets the point as a measurement target point and acquires the position (latitude, longitude) and altitude of the measurement target point from the map. To the server device 20. In addition, when the current map which has the altitude data with respect to each point is memorize | stored in the server memory | storage means 21 of the server apparatus 20, the point acquisition means 151 acquires only the position (latitude, longitude) of a measurement object point, and a server You may transmit to the apparatus 20.

When the altitude data storage unit 213 of the server device 20 records the ground strength determination results at the measurement target points in addition to the measurement target points transmitted from the plurality of terminal devices 10, the terminal control unit 15 The point where the measurement was performed in the past and the determination result stored in the altitude data storage unit 213 may be received from the server device 20. In this case, as shown in FIG. 8, an icon 34 indicating the ground strength determination result may be displayed at the received point where the measurement has been performed in the past. As a display method of the ground determination result, for example, a point where the ground determination result is “good” is “green”, a point where “slightly caution” is “yellow”, a point where “caution” is “orange”, “ The ground determination result may be identified by color display such as “red” for a point that is “attention”, or a determination point may be displayed.
In this way, displaying the ground determination result on the map eliminates the need for the user to perform ground determination processing again at the point where the ground determination has already been performed, improving convenience in the ground determination processing. Can be made.

  Returning to FIG. 7, when an input for designating the address and evaluating the ground strength is made by the user, the display control unit 152 displays, for example, an input field for inputting the address. When the user inputs an address in the input field, the point acquisition unit 151 transmits the input address to the server device 20 as the measurement target point.

[Operational effects of this embodiment]
In the ground strength determination system 1 according to the second embodiment as described above, the point acquisition unit 151 can acquire an arbitrary point designated by the user as a measurement target point in addition to the position information at the current position. Therefore, for example, the ground strength at an arbitrary point desired by the user can be easily determined without moving to the measurement target point, and the convenience in the ground strength determination system can be further improved.

[Other Embodiments]
In addition, this invention is not limited to embodiment mentioned above, In the range which can achieve the objective of this invention, the deformation | transformation shown below is also included.
For example, in the first and second embodiments described above, the measurement target point acquired by the terminal device 10 is transmitted to the server device 20, and after the ground strength is determined in the server device 20, the result is transmitted to the terminal device 10. And displayed.
On the other hand, the current map storage unit 211, the old map storage unit 212, the altitude data storage unit 213, and the land improvement data storage unit 214 are recorded in the terminal storage unit 11 of the terminal device 10, and the terminal control unit 15 By executing various programs stored in the terminal storage unit 11, the past elevation acquisition unit 221, the elevation change calculation unit 222, the past water field determination unit 223, the change area identification unit 224, the valley determination unit 225, the ground determination unit The configuration may function as H.226. That is, the terminal device alone may function as a ground strength determination device. Even in this case, the same effects as those of the first and second embodiments can be obtained, and the ground strength at an arbitrary point can be easily determined. In addition, with this configuration, the ground strength can be determined even in a terminal device that does not have communication means with the server device 20 or in an environment where the radio wave reception state is poor.
Further, the server device may function as an old map storage unit, and the terminal device may be configured to acquire an old map from the server device. Even in this case, the terminal control means 15 executes various programs stored in the terminal storage means 11, so that the past elevation acquisition means 221, the elevation change calculation means 222, the past water field determination means 223, and the change area specification means 224, valley determining means 225, and ground determining means 226. By adopting such a configuration, various determinations for determining ground strength and ground strength determination are performed by individual terminal devices, so that the load on the server device is reduced and the processing speed can be increased.

In the first embodiment, the ground determination means 226 includes the elevation change calculated in S203, the determination result of the water field determination in S204, the determination result of the valley determination in S205 to S206, and the average elevation calculated in S208. Based on the determination result of the valley shape determination based on the change amount and the like, the determination point corresponding to each determination result was read from the strength determination reference data, and the ground strength determination was performed. On the other hand, for example, an addition point is set for each index for determining various ground strengths, and a determination point is calculated by adding (or multiplying) these addition points and subtraction points from the initial point. However, the ground strength may be determined.
For example, when the initial point is “100” and the altitude change amount is 0 m or more and less than +5 m, an addition point of “−10” is added, and when the altitude change amount is −5 m or more and less than 0 m, the addition point of “+10” is added. Is added. Similarly, the determination result of the water field determination in S204, the area of the elevation change area calculated in S205, the determination result of the valley determination in S206, the average elevation change amount calculated in S208, and whether there is artificial land improvement The determination result, the time when the land improvement was performed, the land improvement method, etc. are set for each point, and the ground determination means 226 calculates the determination point based on the determination result.
Even if such a method is used, the ground strength with respect to an arbitrary point can be easily implemented without using a large-scale ground measuring device, as in the above embodiment.

  In the above embodiment, the ground determination means 226 performs the ground strength determination using the results of various determination processes performed in S204 to S208 as an index in addition to the elevation change calculated in S203. Some of the determination processes may be selectively performed, or the ground strength may be determined based only on the altitude change amount. In addition, as described above, the ground strength may be determined using another determination result such as determination of a phrase included in the place name as a new index.

  In addition, the specific structure and procedure for carrying out the present invention can be appropriately changed to other structures and the like within a range in which the object of the present invention can be achieved.

  DESCRIPTION OF SYMBOLS 1 ... Ground strength determination system (ground strength determination apparatus), 10 ... Terminal device, 12 ... Display means, 14 ... Position measuring means, 15 ... Terminal control means, 20 ... Server apparatus, 21 ... Server storage means, 22 ... Server control Means 151: Point acquisition means 152 ... Display control means 212 ... Old map storage section (old map storage means) 213 ... Elevation data storage section (elevation data storage means) 214 ... Land improvement data storage section (land improvement) Data accumulating means), 221 ... past altitude obtaining means, 222 ... altitude change amount calculating means, 223 ... past water field judging means, 224 ... change area specifying means, 225 ... valley judging means, 226 ... ground judging means.

Claims (11)

Point acquisition means for acquiring the position and altitude of the measurement target point of ground strength,
An old map storage means for storing an old map in which a past altitude at a predetermined point is recorded;
Past elevation acquisition means for acquiring a past elevation that is an elevation of the old map corresponding to the measurement target point;
A ground determination means for determining the ground strength of the measurement point based on the elevation of the measurement target point and the past elevation,
The ground determination means uses an altitude change which is a difference between the altitude of the measurement target point and the past altitude as an index, and responds to the altitude change when the altitude of the measurement target point is higher than the past altitude. ground intensity determination apparatus characterized by determining soil strength strong depending on the determined that the ground strength is weak, the altitude variation when elevation of the measurement object point is lower than the previous altitude Te. In the ground strength determination apparatus according to claim 1,
Reference data storage means for storing strength determination reference data for storing the elevation change amount and the strength level of the ground strength corresponding to the elevation change amount,
The ground strength judging device, wherein the ground strength judging means judges ground strength at the measurement target point based on the strength judgment reference data. In the ground strength determination apparatus according to claim 1 or 2,
The old map storage means stores a plurality of old maps having different measurement times of geography,
The past altitude acquisition means acquires the past altitude from an old map having the oldest measurement time among the old maps in which the past altitude corresponding to the measurement target point is recorded. apparatus. In the ground strength determination apparatus in any one of Claims 1-3,
A past water field judging means for judging whether or not the geographical state of the old map corresponding to the measurement target point is a water field;
The ground determination means, when it is determined that the geography state of the old map corresponding to the measurement target point is a water field, compared to the case where it is determined that it is not a water field, the ground strength of the measurement target point A ground strength judgment device characterized in that it is judged to be weak. In the ground strength determination apparatus in any one of Claims 1-4,
Altitude data storage means for storing the position and altitude of the predetermined point as altitude data;
Based on the altitude data, the altitude relative to the past altitude changes in the same direction as the altitude of the measurement target point, and a change region specifying means for obtaining an altitude change region including the measurement target point therein, and
The ground determination means includes
In the case elevation of the measurement object point is not lower than the past altitude, when the area of the elevation change area is not less than a predetermined area threshold, when the area of the elevation change area is smaller than the area threshold value compared to, soil strength determination apparatus characterized by determining soil strength is low. In the ground strength determination apparatus in any one of Claims 1-5,
Altitude data storage means for storing the position and altitude of the predetermined point as altitude data;
Based on the altitude data, the altitude relative to the past altitude changes in the same direction as the altitude of the measurement target point, and a change area specifying means for obtaining an altitude change area including the measurement target point inside,
In the altitude change region of the old map, when there is a point where the altitude is high across a point where the altitude is low, it is determined as a valley, and when there is no valley, a valley determining means that determines that it is not a valley,
The ground determining means determines that the elevation changing area is a valley by the valley judging means, and if the elevation of the measurement target point is higher than the past elevation, the elevation data is within the elevation changing area. A ground strength determination device, wherein a plurality of target points included are extracted and ground strength is determined based on an average value of an elevation change amount at these target points. In the ground strength determination apparatus in any one of Claims 1-6,
The land improvement data storage means for storing the land improvement data indicating the land improvement position where the artificial land improvement has been performed on the land is provided,
The ground determination means determines whether the change in the altitude is due to artificial improvement or natural change based on the land improvement data when the altitude of the measurement target point is higher than the past altitude. However, when it is determined that it is due to artificial improvement, it is determined that the ground strength is stronger than when it is determined that it is due to a natural change. In the ground strength determination apparatus according to claim 7,
The land improvement data includes information on the time when the land improvement was carried out,
When the ground determination means determines that the altitude at the measurement target point is different from the past altitude, and that the change in the altitude is due to artificial improvement, the land improvement is further performed. A ground strength determination device characterized by determining ground strength based on time. In the ground strength determination apparatus according to claim 7,
The land improvement data includes a land improvement method according to the land improvement position,
The ground determination means, when it is determined that the elevation of the measurement target point is different from the past elevation and the change in the elevation is due to artificial improvement, further, based on the land improvement method A ground strength judgment device characterized by judging ground strength. In the ground strength determination apparatus according to claim 1,
Equipped with a position measuring means for measuring the current position and current altitude,
The point acquisition means acquires the current position and current altitude measured by the position measuring means as the position and altitude of the measurement target point. A ground strength determination method for determining the ground strength of a measurement target point by a computer,
The computer has an old map storage means for storing an old map in which a past altitude at a predetermined point is recorded,
The computer
A point acquisition step for acquiring the position and altitude of the measurement target point of the ground strength,
A past elevation acquisition step of obtaining a past elevation that is an elevation of the old map corresponding to the measurement target point;
A ground determination step for determining the ground strength of the measurement point based on the elevation of the measurement target point and the past elevation; and
In the ground determination step, an elevation change amount that is a difference between the elevation of the measurement target point and the past elevation is used as an index, and the elevation change amount according to the elevation change when the elevation of the measurement target point is higher than the past elevation. ground strength determination method characterized by determining soil strength strong depending on the determined that the ground strength is weak, the altitude variation when elevation of the measurement object point is lower than the previous altitude Te.

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