JP2010107861A - Geography-model order reception system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a geography-model order reception system, in which a client can optionally specify an area as a geography model production object, and the three-dimensional geography model by NC-machining can be made at low cost while reducing time and labor. <P>SOLUTION: The order reception system includes: a provider server connected to the client terminal via internet; and an NC-machining device for NC-machining the geography model. The provider server includes: a map image display means for displaying a map image in the client terminal, using a map image database; a latitude/longitude information acquisition means for acquiring the latitude/longitude information about the specified area based on the input from the client terminal; a scale/model dimension acquisition means for acquiring the scale/model dimension information about the geography model; and a three-dimensional coordinate calculating means for calculating three-dimensional coordinate data where altitude values are applied to the latitude/longitude points of the specified area based on the numerical map database and the latitude/longitude information. The NC-machining device performs NC-machining of the three-dimensional geography model based on the three-dimensional coordinate data and the scale/model dimension information. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a terrain model order receiving system, and more particularly to a terrain model order receiving system in which a manufacturer of a terrain model acquires information about a terrain model desired by a consumer via the Internet.

  Three-dimensional terrain models are used for school geography teaching materials, landscape guidance at sightseeing spots and scenic spots, exhibits showing administrative areas such as local governments, materials for studying civil engineering works such as dam construction, natural disasters such as landslides and floods It is used for various purposes such as study materials. Conventionally, such a terrain model is obtained by a method of stacking sheets cut along contour lines (see, for example, Patent Document 1), a prototype by manually processing a prototype based on map information, and a vacuum forming method. It was mainly produced by the method of duplicating using. In recent years, a terrain model using an NC processing apparatus has also been prepared, and the present applicant who has a scope of NC processing is also preparing a terrain model at the request of a public office or a local government.

Japanese Patent No. 2500951

  However, in the method of stacking sheets cut along contour lines, the accuracy of the topographic model is limited by the interval between the contour lines and the sheet thickness. In addition, it is difficult to produce a high-precision model by a method of manually producing the prototype. In addition, each method requires a lot of time and labor.

  On the other hand, the NC machining method can make a precise terrain model based on terrain data, but the conventional terrain model by NC machining is individually ordered from a government office or local government, etc. Many of them were expensive. In addition, the terrain model marketed for general consumers is selected by the customer from off-the-shelf models that model specific areas where demand is expected, such as Mt. Fuji and Mt. Aso, in order to reduce costs by mass production. There has never been a format that allows general consumers to arbitrarily specify the area to be used as a terrain model.

  Therefore, in the present invention, in view of the above situation, a user can arbitrarily specify a region for which a terrain model is to be created, and a three-dimensional terrain model by NC processing can be reduced by reducing time and labor. The objective is to provide a system for ordering terrain models that can be manufactured at low cost.

  In order to solve the above-mentioned problem, the land model receiving system according to the present invention is “a business server comprising a consumer terminal and one or more server devices connected to the consumer terminal via the Internet so as to be communicable. And an NC processing device that NC-processes the terrain model received by the operator server based on an input from the consumer terminal. The operator server is described by a map image database and latitude / longitude / elevation values. One or more storage devices that store the numerical map database, a map image display means for displaying a map image on the consumer terminal using the map image database in response to a request from the consumer terminal, the demand Latitude / longitude information acquisition means for acquiring latitude / longitude information of a designated area designated as an area desired by a consumer as a terrain model based on an input from a customer terminal Based on the input from the consumer terminal, scale / model dimension acquisition means for acquiring the scale and model dimension information of the terrain model, based on the numerical map database and the latitude / longitude information, specified by the latitude / longitude in the designated area 3D coordinate calculation means for calculating 3D coordinate data in which an altitude value is given to a point to be processed, and the NC processing device is based on the 3D coordinate data, the scale, and the model dimension information. NC processing of the terrain model. "

  "Numeric map database" can use a database that collects data described by latitude, longitude, altitude value of the center point of the mesh for each mesh divided into the same shape and size in the latitude and longitude directions, For example, a database of 250 m mesh and 50 m mesh numerical maps published by the Geographical Survey Institute can be used.

  The “map image database” is a database that collects digitized map information for generating three-dimensional or two-dimensional map images. As data, terrain described by latitude, longitude, and elevation values is used. In addition to data to represent, data in which information on roads, railways, buildings, rivers, land use, etc. is digitized can be used. It is also possible to use data in which satellite photographs and aerial photographs are digitized and given accurate geographical coordinates. In addition, the map image display means may display an image to be displayed on the consumer terminal with a multi-layer structure, and in response to a request from the consumer terminal, the boundary line or place name of the prefecture may be displayed superimposed on the map image. good.

  The “designated area” is an area designated as the target area of the terrain model desired by the consumer. For example, a frame is generated on the map image displayed on the consumer terminal, and the position and size of the frame are displayed. The designated area can be designated by. Alternatively, the designated area can be designated by numerically inputting latitude and longitude from the consumer terminal. The “latitude / longitude information” is information for specifying a designated area by latitude and longitude, and can be constituted by, for example, latitudes at the north end and south end of the designated area, and longitudes at the east end and west end. Alternatively, it can be constituted by the latitude and longitude of a point on the contour line of the designated area.

  If one of the scale and the size of the terrain model is input from the consumer terminal, the other can be calculated from the relationship with the actual distance of the contour line of the designated area that can be calculated based on the latitude and longitude information. The terrain model dimensions can also be selected from multiple default dimensions. In that case, when specifying the specified area, the shape of the specified area and the aspect ratio correspond to the dimensions of the terrain model. And may be regulated.

  With the above configuration, according to the present invention, a consumer can arbitrarily specify a region to be a target for producing a three-dimensional terrain model by NC processing.

  In the present invention, the business server automatically receives an order from a consumer via the Internet, and processes information necessary for NC processing. Therefore, in the past, if you specified an arbitrary range and ordered a terrain model, the terrain model, which had to be expensive as a single product, was made cheaper by ordinary consumers because of labor savings. can do. In addition, since an unspecified number of customers can order a terrain model via the Internet, it is possible to promote diversification of the customer base and expansion of the market scale.

  The terrain model order receiving system according to the present invention includes, in addition to the above-described configuration, “the operator server specifies a point on a two-dimensional coordinate by a predetermined map projection method by specifying a point specified by latitude / longitude in the designated area. Further, the three-dimensional coordinate calculation means calculates three-dimensional coordinate data in which an altitude value is given to the converted point on the two-dimensional coordinate.

  Since the earth is a sphere, if you create an terrain model by assigning elevation values to points specified by latitude and longitude in the specified area, the terrain model with an uneven surface on a part of the surface of the sphere It becomes. However, the terrain model actually desired by the customer is generally a terrain model in which a change in elevation values is further three-dimensionally represented on a two-dimensional map that is usually used.

  In the present invention having the above-described configuration, the designated area is developed two-dimensionally by a predetermined map projection method, and then a three-dimensional coordinate data having an altitude value is calculated to produce a topographic model. Thereby, the terrain model of the aspect which a consumer generally desires with the unevenness | corrugation of a height direction being given to the two-dimensional map can be provided.

  The terrain model order receiving system according to the present invention is as follows: "The designated area is an area surrounded by two latitude lines and two meridians, and the expansion means is specified by latitude and longitude within an area wider than the designated area. The point is converted into a point on a two-dimensional coordinate by the predetermined map projection method, and the three-dimensional coordinate calculation means is surrounded by a minimum rectangle including the designated area on the converted two-dimensional coordinate 3D coordinate data in which an elevation value is assigned to a point within the range is calculated ”. “Latitude line” is a set of points having the same latitude, and “meridian” is a set of points having the same longitude.

  If the area surrounded by the meridian and the latitude line is a designated area, the outer shape of the designated area after two-dimensional expansion differs depending on the type of map projection, and is not necessarily a rectangle. For example, the outer shape when expanded by the Mercator projection is a rectangle, but the outer shape when expanded by the Universal Transverse Mercator projection is a fan-shaped curve with both latitude and meridians. The fan shape. Here, if the terrain model is a small scale, in other words, if the specified area is small, the specified area after expansion appears almost rectangular regardless of the type of map projection, but if the scale is large, the outline will be rectangular. It becomes noticeable that they have different shapes. However, many consumers want a topographical model that is a clean rectangle when looking down from above (in plan view).

  In the present invention having the above-described configuration, a rectangular range on two-dimensional coordinates can be set as a region for NC processing, and in this case, a topographic model having a rectangular bottom surface is produced. Accordingly, it is possible to provide a terrain model that gives a well-prepared impression and a sense of stability and has a form desired by many consumers. In addition, since the area to be processed as the smallest rectangular area that includes the expanded specified area can be determined after the area wider than the specified area is expanded two-dimensionally, the specified area is lost to form a rectangle. In addition, it is possible to produce a terrain model in which there is no portion that is not processed because there is no three-dimensional coordinate data near the outer edge of the terrain model.

  An order receiving system for a topographic model according to the present invention is as follows: “The expansion means selects, as the predetermined map projection method, a map projection selected from a plurality of types of map projection methods based on the scale or the latitude and longitude information. Use the law ".

  The map projection method, which is a method of expanding the spherical surface of the earth into a plane, always involves distortion in the direction, area, distance, shape, and the like. For example, in the Mercator projection, the higher the latitude, the larger the actual terrain. In addition, the Mercator projection is a projection in which the projected cylinder is in contact with the earth's surface at the equator. On the other hand, the Universal Transverse Mercator projection can project a mid-latitude region relatively accurately, but the distortion increases as the distance from the central meridian increases. Therefore, it is not suitable for producing a large-scale topographic model. In addition, the conic projection is suitable for a large scale because the area and angle are relatively accurate and can project about two-thirds of the entire earth.

  Since the present invention with the above configuration is a configuration for selecting a map projection method based on scale or latitude / longitude information, a map projection method suitable for the scale / latitude / longitude of the designated area is selected and expanded in two dimensions. It is possible to reduce the terrain distortion that always occurs when doing. As a result, a more accurate terrain model reflecting the actual terrain can be produced.

  The topographic model order receiving system according to the present invention includes, in addition to the above-described configuration, “the operator server displays a three-dimensional image on the consumer terminal as a finished image of the topographic model based on the three-dimensional coordinate data. An image display means ”may be included.

  In the present invention having the above-described configuration, the finished image of the terrain model can be confirmed on the screen in advance, and the consumer can order the terrain model after evaluating whether or not the desired requirement is satisfied. For this reason, it is possible to reduce the risk of impairing the consumer's expectation and the risk that the completed terrain model will be unsuitable for use. In addition, the image image is created using the same 3D coordinate data as the 3D coordinate data actually used for NC processing of the terrain model. It is high and it is highly meaningful to evaluate by image.

  As described above, as an effect of the present invention, a user can arbitrarily specify a region for which a terrain model is to be produced, and a three-dimensional terrain model by NC processing can be reduced in cost and cost by reducing time and labor. It is possible to provide a system for ordering terrain models that can be manufactured by

  Hereinafter, an order receiving system for a terrain model, which is the best embodiment of the present invention, will be described with reference to FIGS. Here, FIG. 1 is a block diagram of the terrain model order receiving system of the present embodiment, FIG. 2 is a block diagram showing a functional configuration of the provider server of FIG. 1, and FIG. 3 is a provider server of FIG. FIG. 4 to FIG. 7 are explanatory diagrams illustrating display screens in the consumer terminal of FIG. 1.

  As shown in FIG. 1, an order receiving system 1 (hereinafter simply referred to as “order receiving system 1”) for a terrain model according to the present embodiment is connected so as to be communicable with a consumer terminal 3 and a consumer terminal 3 via the Internet. Operator server 2 provided with the two server devices 2a and 2b, NC processing management device 6 that communicates with the operator server 2 via the Internet, and NC processing connected to the NC processing management device 6 via the LAN 5 Device 7.

  More specifically, the business operator server 2 has a function as a web server that publishes a web page related to a terrain model on the Internet, in addition to a function of operating the order receiving system 1, and a mail server ( The configuration is such that e-mail can be transmitted / received to / from the consumer terminal 3 via (not shown). Here, each of the server devices 2a and 2b has, as a hardware configuration, a main storage device, an auxiliary storage device, a central processing device that performs processing according to a program stored in the main storage device, and a modem that transmits and receives data via the Internet. It is comprised by the general purpose computer which mainly comprises communication apparatuses, such as. The server devices 2a and 2b include auxiliary storage devices 40a and 40b, respectively. The auxiliary storage devices 40a and 40b correspond to the storage device of the present invention.

  The NC processing management device 6 includes, as a hardware configuration, a main storage device, an auxiliary storage device, a central processing device that performs processing according to a program stored in the main storage device, a communication device such as a modem that transmits and receives data via the Internet, And a general-purpose computer mainly including a LAN adapter.

  On the other hand, the consumer terminal 3 is composed of a general-purpose computer mainly including a main storage device, a central processing unit, and a communication device that transmits and receives data and mail via the Internet, and includes a keyboard and a pointing device. An input device such as a device and an output device such as a display and a printer are connected.

  Hereinafter, the functional configuration of the operator server 2 will be described with reference to FIG. Here, the operator server 2 receives, as a main functional configuration, a program for causing the computer of the server device 2a to function as the map image control means 10 for controlling display of a three-dimensional map image and the like, and an order for a terrain model. And a program for causing the computer of the server apparatus 2b to function as the order processing control means 20 that performs the processing. The provider server 2 includes a three-dimensional map image database 41 stored in the auxiliary storage device 40a, and a numerical map database 42 described by latitude / longitude / elevation values stored in the auxiliary storage device 40b. Corresponding to the type of map projection method, the conversion formula database 43 storing the conversion formula for converting latitude and longitude into two-dimensional coordinates (x, y), and the size and scale of the terrain model, A price table 44 that predetermines the terrain model production fee is provided.

  Then, the map image control means 10 uses the map image database 41 in response to a request from the communication control means 11 for controlling transmission / reception of data via the Internet by the communication device and the consumer terminal 3, and A map image display means 12 for displaying a map image on the consumer terminal 3 and a latitude / longitude information sending means 13 for sending latitude / longitude information of the designated area based on an input from the consumer terminal 3 are provided.

  The order processing control means 20 also includes a communication control means 21 for controlling transmission / reception of data via the Internet by a communication device, a latitude / longitude information acquisition means 22 for acquiring latitude / longitude information of a designated area, and a consumer's request. Scale size / model size acquisition means 24 for acquiring the size of the topographic model as the length of one side of the bottom surface of the model, acquiring the scale of the topographic model and model size information based on the latitude and longitude information, and the map projection method based on the scale A map projection method determining means 25 for determining the type of the image, a conversion means 43 for referring to the conversion formula database 43 according to the type of the map projection method, and a developing means 26 for expanding the designated region two-dimensionally based on the latitude and longitude information. 3D coordinate data of points in the machining area using the machining area determining means 27 for determining the machining area for performing NC machining based on the designated area and the numerical map database 42 3D coordinate calculation means 28 for calculating, and image image display means 29 for displaying the completed image of the topographic model as a three-dimensional image on the consumer terminal 3 using the calculated 3D coordinate data. .

  Further, the order processing control means 20 refers to the price table 44, the estimated price calculation means 31 for calculating the estimated price of the terrain model, the order information acquisition means 32 for acquiring the order information input from the consumer terminal 3, Order information is issued, order information and three-dimensional coordinate data of the processing area, etc. are managed for information necessary for NC processing, and the information is sent to the NC processing device. And a mail transmission means 34 for transmitting the mail.

  Next, the flow of processing in the business server 2 will be mainly described with reference to FIGS. Note that the order receiving system 1 is a system that can be constructed with an unspecified number of consumer terminals 3 as a configuration, but in the following, for convenience of explanation, processing in the provider server 2 in relation to a single consumer terminal 3 The flow of is illustrated.

  First, when the consumer accesses the website managed by the business server 2 with the consumer terminal 3 connected to the Internet, an explanation screen regarding the terrain model and the order of the terrain model performed via the Internet is displayed (step). S1). On this screen, ordering of the terrain model is performed by the steps of specifying the area where the terrain model is to be created, checking the completed image of the terrain model with a three-dimensional image, and inputting information about the consumer. Is explained.

  When the consumer operates the icon “STEP1 area designation” displayed on the screen of the consumer terminal (Yes in step S2), the three-dimensional generated using the map image database 41 stored in the storage means 40a. Map image data is sent to the consumer terminal 3, and the three-dimensional map image 61 illustrated in FIG. 4 is displayed on the display screen 50 of the consumer terminal 3 (step S3). The display screen 50 also displays an icon 51 that is operated when the map image is rotated, an icon 52 that is operated when the map image is enlarged or reduced, and an icon 53 that is operated when the map image is moved.

  FIG. 5 illustrates a display screen 50 in which a consumer operates the icon 52 to display an enlarged map image 61 including a range desired as a terrain model. As described above, when the map image 61 is enlarged, it may look like a two-dimensional image at first glance, but it is a three-dimensional image.

  In addition, a “designated frame” icon 54 is displayed on the display screen 40. When the consumer operates this, a designated frame 62 is generated on the map image 61 as shown in FIG. In this designation frame 62, the two frame lines extending in the vertical direction in the figure are the meridians of the same longitude, and the two horizontal lines extending in the horizontal direction in the figure are the latitude lines of the same latitude. The consumer operates the pointing device of the consumer terminal 3 to change the position and size of the designated frame 62, thereby designating a desired range of the terrain model as the designated area. Here, the designated area is specified by latitude and longitude information described by latitude N at the north end, latitude S at the south end, longitude E at the east end, and latitude S at the west end. The latitude / longitude information is sent out by the latitude / longitude information sending means 13 and obtained by the latitude / longitude information obtaining means 22, and this transmission / reception is automatically performed between the server device 2a and the server device 2b via the Internet. However, the latitude / longitude information may be acquired once on the consumer terminal 3 side and sent to the latitude / longitude information acquisition means 22.

  When the latitude / longitude information is acquired by the latitude / longitude information acquisition means 22 (Yes in step S4), a dimension input form for inputting the dimensions of the terrain model desired by the consumer is displayed on the display screen 50 (step S5). ). This dimension input form can be provided with a default size selection unit that can be selected from a plurality of predetermined sizes, and a free size input unit that can freely set the length. In the present embodiment, a topographic model having a rectangular bottom surface is prepared, and the length of the long side of the bottom surface is input from the consumer terminal 3. Note that the top surface of the terrain model may be square, but for convenience of explanation, the term “long side” will be used also in that case.

  When the length of the long side of the bottom surface of the terrain model is input to the dimension input form (Yes in step S6), the relationship with the actual distance of the parallel or meridian that is the contour of the designated area that can be calculated based on the latitude and longitude information From this, the length of the other side of the bottom surface of the topographic model is calculated, and the scale of the topographic model is calculated (step S7). The calculated scale is displayed on the scale display section of the dimension input screen. In addition, it is good also as a structure by which the length of a long side is displayed on a free size input part conversely by inputting the reduced scale which a consumer desires to a scale display part.

  On the display screen 50, an icon “STEP2 Finish Confirmation” is displayed together with the dimension input form. When the user operates this (Yes in Step S8), the scale is fixed and both sides of the bottom surface of the topographic model are displayed. The model dimension information described by the lengths of both sides is acquired (step S9). Until this icon is operated (No in step S8), the consumer can check the scale by changing the length of the long side and examine the dimensions of the terrain model.

  Next, the type of map projection method is determined based on the calculated scale (step S10). For example, when the scale is smaller than a predetermined value, in other words, when the designated area is a small range, the universal horizontal Mercator projection (UTM projection) is selected as the map projection method, and when the scale is larger than the predetermined value, the cone is selected. A projection can be selected. Then, according to the determined type of map projection, the point specified by the latitude / longitude in the designated area using the conversion formula read from the conversion formula database 43 (hereinafter referred to as “latitude / longitude point”). Are converted into points on the two-dimensional coordinates developed two-dimensionally by a predetermined map projection method (step S11). That is, the latitude and longitude points in the designated area are associated with the coordinates (x, y) on the two-dimensional map developed by the map projection method.

  Here, although the designated frame 62 looks like a rectangle in FIG. 6, the designated area is a range obtained by cutting the earth as a sphere with meridians and parallels, and therefore when the designated area is expanded based on the map projection method. For example, when developed by the UTM method, the outer shape is not a rectangle but a fan shape in which each side draws a curve. Therefore, in the present embodiment, the following processing is performed in order to produce a terrain model having a rectangular bottom surface. That is, a latitude / longitude point within a latitude / longitude range wider than the specified area by a predetermined amount is converted to a point on the two-dimensional coordinates by the determined map projection method, and the specified area expanded in two dimensions from the converted area A region having a minimum rectangle including the contour is extracted and determined as a processing region (step S12). It should be noted that how much a two-dimensional area is expanded beyond the designated area can be set according to the scale.

Next, the three-dimensional coordinates of the points in the processing area are determined using the numerical map database 43. Specifically, based on the altitude value, the scale, and the height enhancement magnification read from the numerical map database, the two-dimensional coordinates (x _n , y _n ) corresponding to the latitude and longitude points for each processing pitch in the NC processing apparatus. A z _n value in the height direction is assigned (step S13). This makes it possible to obtain three-dimensional coordinates for points of the working area _{(x n, y n, z} n) of the three-dimensional coordinate data described in.

  Here, the height enhancement magnification is a magnification that is enlarged in the height direction in order to produce a terrain model in which the height is emphasized from the actual terrain. In the present embodiment, the height enhancement magnification is set in advance, but the height enhancement magnification may be changed according to the scale. Alternatively, the height enhancement magnification may be input from the consumer terminal 3. In addition, because the thickness of the plate material for processing the topographic model is limited, when the elevation difference in the processing area is large, the default value of the height enhancement factor or the height enhancement factor desired by the customer was used. Then, the thickness of the plate material may be insufficient. In this case, the height enhancement magnification is changed based on the elevation difference and the thickness of the plate material, and the three-dimensional coordinates are calculated.

  Since the three-dimensional coordinate data in the processing area is obtained by the above processing, NC processing can be performed using this data. In this embodiment, the finished image of the topographic model is displayed on the consumer terminal 3 in a tertiary manner. Originally displayed, the customer confirms this and decides the order. Therefore, based on the three-dimensional coordinate data, three-dimensional image data that three-dimensionally represents the topography of the processing region is created, and an image image 65 is displayed on the display screen 50 of the consumer terminal 3 as illustrated in FIG. It is displayed (step S14). In creating the three-dimensional image data, the operation speed for displaying the image image 65 is reduced by using data obtained by appropriately thinning out the data without using all the three-dimensional coordinate data, so-called “heavy”. Can be prevented.

  Further, on the display screen 50, an icon 56 for rotating the image, an icon 57 for enlarging or reducing, and an icon 58 for moving are displayed, and latitude / longitude information is displayed on the latitude / longitude display unit 66, and model dimension information is model dimensions. It is displayed on the display unit 67. Further, the estimated price of the terrain model is calculated and displayed on the price display section 68 of the display screen 50 (step S15). Here, the cost for producing the terrain model varies depending on the size, scale, and the like of the raw material plate. Therefore, the estimated price is calculated by referring to the price table 44 in which a price and a calculation formula for the price are previously determined and stored in association with parameters such as dimensions and scales of the terrain model.

  Based on the image 65 displayed on the display screen 50, the consumer confirms the finished image of the terrain model to be produced, and evaluates whether the terrain model matches his intention or application. In addition, by outputting the image 65 displayed on the display screen 50 from the printer of the consumer terminal 3, it can be compared with the produced terrain model when it is obtained.

  On the display screen 50 on which the image image 65 is displayed, an icon 59 “STEP3 To order information input” is displayed. The icon 59 is operated by a consumer who confirms the image image 65 and the estimated price and determines the order. If so (Yes in step S16), an order information input form for inputting order information including the name, address, mail address, order quantity, etc. of the consumer is displayed on the consumer terminal 3 (step S17). ).

  On the screen of the consumer terminal 3, an icon “to order” is displayed together with the order information input form, and if this icon is operated after the consumer has entered the order information input form (Yes in step S 18). ), Order information is acquired with the input content. An order number is issued and displayed on the consumer terminal 3 (step S19). Further, an email describing the order information, the order number, and the payment method for the price is transmitted from the business server 2 to the consumer terminal 3 (step S20).

  Further, the business server 2 transmits various information such as an order number, order information, estimated price, three-dimensional coordinate data of the processing area, scale, and model dimension information to the NC processing management device 6 via the Internet (step). S21), the processing for ordering the terrain model from one consumer terminal 3 is terminated.

  On the other hand, the NC processing management device 6 creates NC data for NC processing based on the three-dimensional coordinate data, scale, and model dimension information of the processing area received from the operator server 2. The created NC data is sent from the NC processing management device 6 to the NC processing device 7 via the LAN 5, and the NC processing device 7 processes the terrain model based on the NC data.

  In addition, the NC machining management device 6 is configured such as “NC data creation in progress”, “NC data creation complete, waiting for machining”, “NC machining in progress”, “NC machining completed”, etc. Process progress information is updated and managed together with order numbers, order information, and the like.

  As described above, according to the order receiving system 11 of the present embodiment, the consumer can arbitrarily specify the area to be the target of the topographic model. In addition, since the business server 2 automatically receives orders from consumers via the Internet, it is possible to reduce the production cost of the terrain model by saving labor.

  In addition, in this embodiment, three-dimensional coordinate data and NC data are automatically created, and the terrain model is automatically processed by the NC processing device 7. In other words, the entire process from ordering a terrain model to making a terrain model is automated. As a result, further labor saving can be achieved, and the terrain model can be produced in a short time, and the terrain model can be made at a low price that is easily purchased by general consumers.

  Further, in the present embodiment, the finished image of the terrain model is confirmed on the screen in advance, and it is possible to place an order for the terrain model after evaluating whether or not the desired requirement is satisfied. It is possible to reduce the risk of impairing the feeling and the possibility that the completed terrain model will be unsuitable for use. In addition, the image image is created using the same 3D coordinate data as the 3D coordinate data used when the terrain model is actually NC processed, so the image image and the actual terrain model are the same. It is highly feasible, and it is highly meaningful to make evaluations using image images.

  Further, in this embodiment, when designating a designated area, a three-dimensional map image is used so that the earth, which is a sphere, is overlooked, so that an area desired by a consumer can be easily selected on a global scale. can do. On the other hand, the terrain model that is actually produced is produced by developing a designated area, which is originally three-dimensional, into two dimensions by map projection. Thereby, the terrain model of the aspect which a consumer generally desires with the unevenness | corrugation of a height direction being given to the two-dimensional map can be provided.

  Furthermore, in this embodiment, since the type of map projection method for expanding the designated region in two dimensions is determined according to the scale or latitude / longitude information, it is avoided when expanding the earth as a sphere into a plane. The terrain model that reflects the actual terrain can be created by suppressing the distortion of the terrain that cannot be performed.

  Moreover, since the processing area is rectangular, a well-shaped terrain model having a rectangular bottom surface can be provided to the consumer. In addition, since the processing area is determined as the smallest rectangular area that includes the expanded designated area after the area wider than the designated area is expanded two-dimensionally, the designated area is not lost, and A terrain model having a rectangular shape in plan view can be produced without generating an unprocessed portion near the outer edge of the terrain model.

  The present invention has been described with reference to the preferred embodiments. However, the present invention is not limited to the above-described embodiments, and various improvements can be made without departing from the scope of the present invention as described below. And design changes are possible.

  For example, by providing a database in which major place names and building names are stored in correspondence with latitude and longitude, the range to be displayed on the display image when specifying the designated area is searched based on the place name or building name. It can be a system that can.

  Further, in the step where the order information is input from the consumer terminal, it may be possible to order processing of additional elements in addition to the terrain. For example, it is configured with a database that stores the latitude / longitude data of administrative boundaries, coast lines, lake shore lines, main roads, and railways, and an input form that allows users to input whether or not these elements need to be processed by check marks. Display on the terminal. Then, based on the selection, NC data is created using the latitude / longitude data of these elements, thereby creating a terrain model in which a groove is processed at a predetermined depth along, for example, the administrative boundary or the coastline. be able to. Thereby, it can be set as the order receiving system which can respond | correspond more finely to a consumer's request.

  In the above embodiment, since the NC processing management device 6 always knows the progress of NC processing together with the order number, by making an inquiry from the customer terminal 3 to the business server 2 using the order number, A configuration in which the business server 2 further makes an inquiry to the NC processing management device 6 using the order number, and notifies the customer terminal 3 of the progress of the production of the terrain model from the NC processing management device 6 via the server device 2; can do.

1 is a configuration diagram of an order receiving system for a topographic model that is an embodiment of the present invention. FIG. It is a block diagram which shows the functional structure of the provider server of FIG. It is a flowchart which shows the flow of a process in the provider server of FIG. It is explanatory drawing explaining the display screen in the consumer terminal of FIG. It is explanatory drawing explaining the display screen in the consumer terminal of FIG. It is explanatory drawing explaining the display screen in the consumer terminal of FIG. It is explanatory drawing explaining the display screen in the consumer terminal of FIG.

Explanation of symbols

1 Ordering system (topography model ordering system)
2 business server 2a, 2b server device (business server)
3 Customer terminal 6 NC processing management device 7 NC processing device 12 Map image display means 22 Latitude / longitude information acquisition means 24 Scale / model size acquisition means 26 Expansion means 28 Three-dimensional coordinate calculation means 29 Image image display means 40a, 40b Auxiliary storage Device (storage device)
41 Map image database 42 Numerical map database

Claims (5)

A consumer terminal,
An operator server comprising one or more server devices communicably connected to the consumer terminal via the Internet;
An NC processing device for NC processing the terrain model received by the operator server by input from the consumer terminal;
The provider server is
One or more storage devices storing a map image database and a numerical map database described by latitude, longitude and elevation values;
In response to a request from the consumer terminal, a map image display means for displaying a map image on the consumer terminal using the map image database;
Latitude / longitude information acquisition means for acquiring latitude / longitude information of a designated area designated as an area desired by a consumer as a terrain model based on an input from the consumer terminal;
Based on the input from the consumer terminal, the scale / model dimension acquisition means for acquiring the scale and model dimension information of the terrain model,
Based on the numerical map database and the latitude / longitude information, comprising three-dimensional coordinate calculation means for calculating three-dimensional coordinate data in which an altitude value is given to a point specified by latitude / longitude in the designated area,
The NC processing apparatus performs NC processing of a three-dimensional terrain model based on the three-dimensional coordinate data, the scale, and the model dimension information. The provider server further includes expansion means for converting a point specified by the latitude and longitude in the designated area into a point on a two-dimensional coordinate by a predetermined map projection method,
2. The topographic model order receiving system according to claim 1, wherein the three-dimensional coordinate calculation means calculates three-dimensional coordinate data in which an altitude value is given to the converted point on the two-dimensional coordinate. The designated area is an area surrounded by two parallels and two meridians,
The expansion means converts a point specified by latitude / longitude within an area wider than the designated area into a point on a two-dimensional coordinate by the predetermined map projection method,
The three-dimensional coordinate calculation means calculates three-dimensional coordinate data in which an elevation value is assigned to a point within a range surrounded by a minimum rectangle including the designated area on the converted two-dimensional coordinate. An order receiving system for a topographic model according to claim 2. 3. The map development method according to claim 2, wherein the expansion unit uses a map projection method selected from a plurality of types of map projection methods based on the scale or the latitude / longitude information as the predetermined map projection method. The system for ordering terrain models according to claim 3. The said provider server is further provided with the image image display means to display a three-dimensional image on the said consumer terminal as a finished image of a topographic model based on the said three-dimensional coordinate data. Item 5. The land model order receiving system according to any one of Items 4 to 5.