JP3873053B2 - Replacement interrupt processing apparatus and program - Google Patents

Description

  The present invention relates to a land replacement interrupt processing system for supporting land replacement interrupt design in a land readjustment project.

Conventionally, in land readjustment projects, as exemplified in Patent Documents 1 and 2, a support system that incorporates geographic information system (GIS) technology and is easy to understand and use, even if it is not a specialized computer engineer. The development of is being attempted. For example, in patent document 1, the information required at the time of temporary replacement land design is used to issue documents related to land readjustment projects and create land maps.
JP 2000-132599 A JP 2002-140474 A

  Further, in Patent Document 2, from the positional overlap between the brush before the site arrangement and the city block planned after the arrangement, the block adjacent to the brush is automatically identified and assigned as a temporary destination, and this temporary replacement plan is referred to. While drawing the subsoil. That is, select a brush to be replaced for each brush unit from the map, specify the block to be replaced, store the relative position of the specified block, adjust the interruption angle of the replaced block, and change the location and interrupt of the block Automatically interrupts the block from the angle and automatically draws the object of the land integration in the form of cutting out the block (Fig. 6). However, in the method of Patent Document 2, evaluation / verification after automatic interruption is not taken into consideration, so that a good substitute interruption result cannot be obtained.

  In other words, in the land readjustment project, the work of actually interrupting the converted land corresponding to the previous land allocated to the block is evaluated for each converted land, and the evaluation of each converted land is equal to the evaluation of each corresponding previous land. Verify whether there is a relationship, if there is not an even relationship, change the replacement condition (the shape and position of the replacement), perform a replacement interrupt again according to the changed replacement condition, evaluate the interrupt replacement and verify the evaluation This is an extremely inefficient operation of repeating the interrupt-evaluation-verification process many times until a good verification result is obtained. Therefore, the advent of a simple replacement interrupt method for efficiently obtaining a good replacement interrupt result is awaited.

  In view of such circumstances, the main object of the present invention is to use the image layout arrangement matrix that reflects the positional relationship of the previous land where the land replacement interrupt is performed in the land replacement interrupt design in the land readjustment project. It is an object of the present invention to provide a replacement interrupt processing system capable of easily setting an interrupt condition while obtaining an image, obtaining a good replacement interrupt result in a short time, and efficiently performing a replacement interrupt operation.

  According to the main feature of the present invention, the block information storage means (4: post-planning database) that stores block terrain information related to the terrain of the planned block (BR), and a plurality of blocks assigned to the block (BR) Based on the previous land information storage means (4: current state database) storing the previous land topography information on the topography of the previous land (A: A1, A2,...) And the block topography information stored in the block information storage means. Based on the reference line setting means (S2) for setting the longest side of the shape of the block (BR) to the reference line (LR) of the block (BR) and the previous landform information stored in the previous place information storage means Thus, the previous position acquisition means (i, j) for acquiring the gravity center position information (i, j) of each previous place (A) using the reference line (LR) set by the reference line setting means (S2) as the reference coordinate axis (i) S3) and city block (BR) Matrix generating means (S3) for generating an image array matrix (MX) having the same number of rows (m) and columns (n) as the number (K) of the images (B: B1, B2,. According to the relative positional relationship of the gravity center position information of each previous place (A) acquired by the previous place position acquisition means (S3), a place symbol (" 1 ”,“ 2 ”,...) Are developed at the corresponding position (m, n) on the image layout matrix (MX) generated by the matrix generating means (S3). And a matrix display means (S3) for displaying the image area arrangement matrix (MX) in which the image area symbols (“1”, “2”,...) Are expanded by the image area symbol expanding means (S3); Depending on the matrix display means (S3). Matrix editing means (S4 to S9) for editing the arrangement (m, n) of the displayed area symbols (“1”, “2”,...) On the area arrangement matrix (MX), and matrix editing means ( Duplicate check for checking that the place symbol (“1”, “2”,...) Whose arrangement has been changed by S4 to S9) is not duplicated in the same row (m) or column (n). Means (S7), row position (m) or column position (n) of image symbol ("1", "2",...) After being checked by duplication checking means (S7), and previous place information The direction of the reference line (LR) in the block (BR) or the reference line (LR) in accordance with the evaluation value of each previous place corresponding to the drawing place symbol calculated from the previous place terrain information stored in the storage means In the vertical direction, the image area (B: B1, B 2), and a block information storage for storing block landform information relating to the topography of the planned block (BR). Means (4: post-planning database) and previous place information storage means for storing previous landform information on the topography of a plurality of previous places (A: A1, A2,...) Assigned to the block (BR) ( 4: a current state database), and a computer functioning as a land interruption interrupt processing device, the longest side of the shape of the block (BR) is determined based on the block terrain information stored in the block information storage means. ) Based on the reference line setting step (S2) and the reference line setting step (S2) based on the previous landform information stored in the previous ground information storage means. A previous location acquisition step (S3) for acquiring the center-of-gravity position information (i, j) of each previous location (A) with (LR) as the reference coordinate axis (i), and the image area (B : A matrix generation step (S3) for generating an image area arrangement matrix (MX) having the same number of rows (m) and columns (n) as the number (K) of B1, B2,. According to the relative positional relationship of the gravity center position information of each previous place (A) acquired in S3), a place symbol ("1", "2") indicating that the place corresponds to the previous place (A) ,... To the corresponding position (m, n) on the image layout matrix (MX) generated in the matrix generation step (S3), and the image symbol expansion. In step (S3), the place symbol ("1", "2", ) Is displayed in the matrix display step (S3) for displaying the image area arrangement matrix (MX), and the image area symbols ("1", "2" displayed in the matrix display step (S3) in accordance with the user's operation. “,...) In the matrix editing step (S4 to S9) for editing the layout (m, n) on the layout matrix (MX), and the ground symbol whose layout has been changed in the matrix editing step (S4 to S9). (“1”, “2”,...) In a duplicate check step (S7) for checking that duplicates are not arranged in the same row (m) or column (n), and a duplicate check step (S7) It is calculated from the row position (m) or column position (n) of the image area symbol (“1”, “2”,...) After being checked, and the previous land topography information stored in the previous land information storage means. Vs. Depending on the evaluation value of each corresponding previous place, the image area (B: B1) corresponding to the image area symbol in the direction of the reference line (LR) in the block (BR) or in the direction perpendicular to the reference line (LR). , B2,...) Is provided for executing a procedure including an image area interruption step (S10). The parentheses are reference symbols or terms used in the embodiments for the sake of understanding.

  In the land replacement interrupt processing device according to the present invention, the image area symbol expansion means (S3) indicates that the image area (B3, B5) corresponds to the reserved area (A3, A5) allocated to the block (BR). An image area representing that the image area symbol (“3”, “5”) is an image area (B1, B2, B4, B6,...) Corresponding to the previous area (A1, A2, A4, A6,...). An image area interrupting means (S10) is developed in an area on the image area arrangement matrix (MX) different from the area where the symbols (“1”, “2”, “4”, “6”,...) Are expanded. Can be configured to interrupt the image area (B3, B5) according to the evaluation amount of the reserved area (A3, A5). In addition, the image area symbol developing means (S3) is configured so that the image area symbols ("1", "1") are not overlapped on the same line (m) or column (n) on the image area arrangement matrix (MX). 2 ″,...) Are expanded (claim 3).

  In the substitution interrupt processing apparatus according to the present invention, the matrix editing means (S4 to S9) is configured to display the ground symbol ("1", "2" on the ground layout matrix (MX) in accordance with the ground symbol moving operation by the user. ”,...) In the row (m) or column (n) direction according to the symbol position changing means (S7) for changing the arrangement (m, n) and the segment instruction operation by the user. The partition means (S4, S9) for partitioning into a plurality of areas (G1, G2) and the areas (G1, G2) partitioned by the partition means (S4, S9) It can be configured to have a section diagram display means (S5, S9) for displaying a section map divided into the sections (g1, g2). Further, the matrix editing means (S4 to S9) can select the entire image area arrangement matrix (MX) or the row (m) or the column (n) on the image area arrangement matrix (MX) according to the spine splitting instruction operation by the user. Back splitting means (S6, S8) for splitting a predetermined section (G1; G2) partitioned in the direction into two regions (1 + 2, 8; 3, 4 + 5 + 6 + 7) in the column (n) or row (m) direction The image area interrupting means (S10) corresponds to the areas (1 + 2, 8; 3, 4 + 5 + 6 + 7) divided on the image area arrangement matrix (MX) by the back dividing means (S6, S8), There is a back split execution means for splitting the entire block (BR) or the section (g1, g2) corresponding to the predetermined section (G1, G2) into two sites (B1 + B2, B8; B3, B4 + B5 + B6 + B7) , The ground symbol in each region (1 + 2, 8; 3, 4 + 5 + 6 + 7) on the ground region arrangement matrix (MX) [For example, as shown in FIG. In each case, the sites divided by the spine execution means according to the row position (m) or column position (n) of “1”, “2” and “8” [in the same example, In the position of the reference line (LR) or the direction perpendicular to the reference line (LR) in the sites B1 + B2 and the site B8 in FIG. 2 ”and“ 8 ”] (in the case of the same example, the image areas B1, B2 and the image area B8 in FIG. 12A) are interrupted (claim 5).

  In the substitute land interruption processing system according to the present invention (claims 1 and 6), when the reference line (LR) of the planned block (BR) is set (S2), the set reference line (LR) is set as the reference coordinate axis (i). As a result, the location information (i, j) of the previous location (A: A1, A2, etc.) assigned to the block (BR) is obtained, and the previous location (A) is obtained according to the obtained location information (i, j). The image area arrangement matrix (MX) in which the image area symbols (“1”, “2”, etc.) corresponding to is expanded and displayed (S3). Since the place symbol (“1”, “2”, etc.) arranged on this place array matrix (MX) reflects the positional relationship of the previous place (A) where the place change interrupt is performed, the user can By editing the image area array matrix (MX), it is possible to easily set an interrupt condition while imagining the interrupt position of the image area (B: B1, B2, etc.) for the block (BR) (S4 to S9). . Then, according to the contents set by the edited image area arrangement matrix (MX), the image area (B) is interrupted to the block (BR), so that a good result of the image replacement interrupt can be obtained in a short time, and the efficiency of the image replacement interrupt work is improved. Can be done well.

  Further, in this replacement interrupt processing system, the image area arrangement matrix (MX) has the same number of rows (m) and columns (n) as the image areas (B: B1, B2, etc.) that interrupt the block (BR) [ When the number of rows m and columns n is the same as the number of image areas B (B1, B2, etc.) to be interrupted in the block BR, there are no unused (empty) lines or columns, and an optimally effective image area Since it is possible to interrupt, it is sufficient in principle that the number is the same as the number of drawings, but in practice it may be more than the same number), and the drawing symbols (“1”, “1”, etc.) on the drawing arrangement matrix (MX) "2" etc.) can easily change the interrupt position of the image area (B: B1, B2, etc.) for the block (BR) by changing the arrangement position (m, n) according to the user operation (S7) The location of the place symbol (“1”, “2”, etc.) can be changed by user operation. If it is changed, it is checked that the place symbol ("1", "2", etc.) is not duplicated in the same row (m) or column (n) (S7). The setting of the image area interrupt position can be ensured.

  In the land replacement interrupt processing apparatus according to the present invention, the image area symbols ("3", "5") corresponding to the reserved areas (A3, A5) assigned to the block are also developed on the image area arrangement matrix (MX). As a result, it is possible to efficiently perform a land-replacement interrupt in consideration of the interrupt of the reserved land image (B3, B5) (claim 2).

  In the substitution place interrupt processing apparatus according to the present invention, when the place symbol (“1”, “2”, etc.) is developed on the place arrangement matrix (MX), the place symbol (“1”, “2”, etc.). ) Are arranged and displayed so as not to overlap each other in the same row (m) or column (n), the user can easily and definitely edit the image layout matrix (MX). In accordance with the direction and order of the image-interrupt set by (1), the image (B) can be interrupted according to the image-symbol position (m, n).

  In the substitute land interruption processing device according to the present invention, in the case of a composite type in which the image area interruption is performed on each division area after the block (BR) is divided, when the user performs the division instruction operation prior to the image area interruption, It is possible to perform setting for dividing the image area arrangement matrix (MX) into a plurality of sections (G1, G2) in the row or column direction (S4, S9). At this time, the user can confirm the state of the division setting by the division instruction line (LG1, LG2) appended to each of the zones (G1, G2), and corresponding to these zones (G1, G2). By displaying a block diagram in which the block (BR) is divided into a plurality of divided areas (g1, g2), an outline of the block in the block can be grasped (claim 4).

  In the spare area interrupt processing device according to the present invention, when interrupting in the back split method, the entire image layout matrix (MX) or on the map layout array matrix (MX) according to the back split instruction operation by the user. A predetermined section (G1, G2) partitioned in the row (m) or column (n) direction is divided into two regions (1 + 2/8, 3/4 + 5 + 6 + 7) in the column (n) or row (m) direction. Can be set (S6, S8). At this time, the user can confirm the setting state of the spine division by the spine division lines (LC1, LC2) displayed between the two areas (1 + 2/8, 3/4 + 5 + 6 + 7), and the image layout matrix ( MX) 2 corresponding to the whole area (BR) or the section (g1, g2) corresponding to the predetermined area (G1, G2) corresponding to both areas (1 + 2/8, 3/4 + 5 + 6 + 7) set on MX) It can be divided into two sites (B1 + B2 / B8, B3 / B4 + B5 + B6 + B7).

〔System configuration〕
FIG. 1 is a block diagram showing an example of a hardware configuration of a substitute interrupt processing system according to an embodiment of the present invention. In this example, a general-purpose data processing device such as a personal computer (PC) is used as the substitute interrupt processing device. This replacement interrupt processing device includes a central processing unit (CPU) 1, a random access memory (RAM) 2, a read only memory (ROM) 3, an external storage device 4, an input operator device 5, a display device 6, an input interface 7, Elements such as an output interface 8 are provided, and these elements 1 to 8 are connected to each other via a bus 9.

  CPU1 which controls the whole apparatus performs the process for various operations of the land readjustment project including the change land interrupting process according to the control program for various land readjustment projects such as the change land interrupt processing program. The writable RAM 2 functions as a working memory for temporarily storing various information necessary for executing various control programs. In the ROM 3, various control programs and various data are stored in the CPU 1.

  The external storage device 4 can move a built-in recording medium such as a hard disk (HD) and its driving device, a flexible disk (FD), a magneto-optical (MO) disk, a compact disk (CD), a smart media (registered trademark), and the like. The control program for the replacement processing device and various data are stored. For example, even if a control program such as a replacement interrupt processing program for controlling this data processing device as a replacement interrupt processing device is not stored in the ROM 3, the control program is stored in the external storage device 4 and stored in the RAM 2. By reading, it is possible to make the CPU 1 perform the same operation as when the control program is stored in the ROM 3. Further, in the external storage device 4, a current state database that accumulates the current topography and attribute information in the area targeted for the land readjustment project and a post-planning database that accumulates the post-planning topography and attribute information after the plan are constructed. .

  The input operator device 5 includes operators such as a keyboard and a mouse. The input operator device 5 accepts the user's operation contents on these operators and introduces them into the apparatus main body. The display device 6 includes a display and an indicator such as an LCD and a CRT, and controls the display contents according to instructions from the CPU 1 to provide display assistance for the user operation of the input operator device 5 and input / output as necessary. It is possible to display a screen necessary for data and land change interrupt processing.

  An input interface 7 collectively represents an interface for inputting an external image input device 10 such as an image scanner and an external graphic input device 11 such as a drawing reader to the apparatus main body. An interface for outputting text or image data or graphic data obtained as a result of processing to the printer 12 or the plotter 13 is collectively shown.

[Flow of land readjustment project and information processing system]
FIG. 2 is a diagram for explaining the flow of the land readjustment project and an information processing system for providing support corresponding to each work. In the land readjustment project, as is well known, work proceeds according to the flow shown on the left side of FIG. Of these operations, for operations that require representation using a map, the technology of geographic information system (GIS) is applied to construct a corresponding information processing system as shown on the right side of FIG. It is possible to provide a consistent land readjustment project support tool called a “land readjustment mapping system” by linking these systems effectively.

  As shown in the left side of FIG. 2, the flow of work in the land readjustment project begins with the current surveying stage ST1, then goes through the rights investigation stage ST2 and the business plan development stage ST3, and the desired town block is confirmed in the block confirmation stage ST4. Is done. During this time, the land readjustment mapping system operates the rights check system in the right check stage ST2, and the existing (present) image area in the area subject to the land readjustment project (hereinafter referred to as “target area”). (Brush) [Hereafter, referred to as "former land". ] Is acquired from the land register, etc., and both information are linked and stored in the current status database and registered. In the block determination stage ST4, the block landform after block adjustment is determined using the block determination system, and topographic information (overall shape and block shape) and attribute information (land area value, block number, usage pattern, etc.) are planned. Store in the database.

  In the next land evaluation stage ST5, the land area obtained in the right survey stage ST2 is calibrated using the reference land estimation system in consideration of the public land and actual measurement values, and “the sum of public land + reference land area = target area” In accordance with the expression “total area of”, a “reference area” representing the correct area of each previous area is calculated. Next, in the road price calculation system, the street coefficient [systemity (also known as trunk line), width, etc.], access coefficient (distance from major facilities), residential land coefficient (environment to residential land such as water and sewage, gas) Based on the above, the value (route price) of the existing road and the post-plan road is evaluated according to a predetermined calculation formula. Subsequently, the block evaluation system evaluates the value of each post-planning block based on the positional relationship with the post-planning road according to the conditions established in the business plan development stage ST3, and calculates the total evaluation value and average unit price of each block. calculate. In addition, each brush evaluation system performs land evaluation of each previous land (current position) based on the relationship with the current road, and determines the evaluation amount. These results are stored in the current status or post-plan database.

  Subsequently, when entering the substitution design stage ST6, operations such as rough substitution, provisional substitution, and substitution interruption are performed. The rough land replacement work is a work in which the target area is divided into a plurality of areas according to the planned block group, and each previous land and reserved land in the target area are allocated to each area, and is supported by the rough land replacement system. In addition, reserved land means land after plan that the sale costs are appropriated for fund for proceeding with land readjustment project, and in this rough turnover work, it is distributed to required block as reserved land section, and each holding The evaluation amount or area (land area) of the land section is set. In general land replacement work, in principle, each previous land existing in or near each area is distributed to the planned area together with the reserved land. In this case, a plurality of small brushes (current location) related to the same owner are put together into one previous place that is a certain size so that an area that can be used in one drawing area can be secured. It is necessary to increase the value and to arrange the ratio of subsidized and reserved land and the economic value evenly in a balanced manner among the areas. In addition, by the rough land replacement work, the information on the block after the plan is associated with the information on the previous land distributed to each block.

  Subsequent to the rough turnover, provisional turnover work is performed in which each previous place and reservation place allocated to each area is assigned to any block in the area, and this work is supported by the temporary turnover system. Even in this temporary land transfer, it is necessary to make the ratio and economic value of the reserved land fair and balanced among each block. In this way, the correspondence between the previous land and the planned land allocation is gradually narrowed down from the area to the block, and after the temporary turnover, the changeover interrupt is entered and each previous land assigned to each block and The location and shape of the planned image area corresponding to the reserved area (hereinafter simply referred to as “image area”) is set in the block (this is called “interrupting”). (Replacement interrupt ”or simply“ interrupt ”). This land-replacement interrupting work is supported by the land-replacement interrupt system, and the image land (also referred to as “replacement land”) set in the block corresponding to each subdivision respects the positional relationship of the subdivisions assigned to the block as much as possible. However, the sum of the economic value combined with the reserved land is set in a well-balanced manner so as to be equal to the planned economic value of the entire block.

  In the succeeding image area determining stage ST7, the image area determining system determines the image area of each block according to the result of the area replacing interrupt obtained in the area design stage ST6. Next, the process proceeds to temporary replacement place designation step ST8, where the determined land is designated as a “temporary replacement place” corresponding to the previous place by the temporary replacement place designation system, and further, transfer compensation work is performed in the transfer compensation system in transfer compensation stage ST9. In the construction stage ST10, the construction of the target area is performed according to the block and the land determined in stages ST4 and ST7. When the construction is completed, with the assistance of the land conversion planning system, land subsidization is performed at the land substituting stage ST11, all liquidation is performed at the liquidation stage ST12, and this land readjustment project is completed.

[Replacement interrupt processing]
In the substituting interrupt processing system according to one embodiment of the present invention, in the final process of the substituting design stage ST6 described above, a substituting interrupt processing program called a “substituting interrupt system” is started to start substituting interrupt processing. Using the image area arrangement matrix that depends on the number of image areas, the position relationship between the replacement land and the reserved land that is interrupted by the block is schematically shown, and the image area of the desired shape is located at the desired position that respects the position relationship of the previous area. Can be placed in the block to effectively assist in the land-replacement interruption work. FIG. 3 and FIG. 4 are flowcharts showing the operation based on the land change interrupt processing according to one embodiment of the present invention.

  After the temporary replacement work at the replacement design stage ST6, when this replacement interrupt process is started, the current state map of the entire target area is displayed in the main display area of the display screen of the display device 6, and the block confirmation stage is displayed in the menu display area. The numbers and names of all the blocks determined in ST4 are displayed in a list format. In addition, the numbers and shapes of all the blocks are superimposed on the current state map. In the first step S1 of the operation flow of FIG. 3, when the user operates the input operator device (mouse, direction key, etc.) 5 to indicate the desired block number or shape, the CPU 1 accesses the post-planning and current status database. Then, select the designated block and the previous land allocated to the block from the entire block and previous land in the target area, and select the selected block based on the data of the selected block and the previous land. In addition to the shape, the shape figure of the previous place corresponding only to the block is displayed in the main display area, and necessary operation buttons such as a block reference line setting button and a matrix creation button are displayed in the menu display area.

  In the next step S2, in response to a user operation of the block reference line setting button, the CPU 1 automatically selects the longest side among the shapes of the selected block, and selects the line segment along the selected longest side as the block. The reference line (main line) is set and registered (the reference line LR is represented by an angle), and the longest side is displayed in a predetermined color different from the other sides. The block reference line serves as a reference coordinate axis for creating an image area arrangement matrix (MX) described later. Note that the user can manually change (adjust) the setting of the block reference line to an arbitrary block-shaped line by instructing a desired side of the block shape after operating the block reference line setting button.

  In the subsequent step S3, when the start of matrix creation is instructed by the user operation of the matrix creation button, the CPU 1 creates an image area arrangement matrix (MX) in response to this and creates the matrix in the auxiliary display area on the display screen (6). Display as a window. This image area arrangement matrix (MX) is a matrix (m, m) in which squares having the same number of cells as the number K of image areas constituting one block are arranged in a square shape along the row (m) and the column (n). n). In other words, the maximum value of m = K, the maximum value of n = K, and the image array matrix (MX) has K × K cells (in principle, 1 ≦ m, n ≦ K ). Here, the array (m) in the row direction is taken in the same horizontal axis direction (i) as the block reference line, for example, and the array (n) in the column direction is a vertical line perpendicular to the block reference line. Taken in direction (j). The image areas constituting the block can be arranged only in the grids in a certain row and column position, and two or more image areas cannot be arranged in the same row and column. When the matrix creation start is instructed, the matrix position (m, n) on the matrix corresponding to each previous location is calculated according to the positional relationship (i, j) of the previous location assigned to the block. Then, the image area symbol representing the corresponding image area is displayed at the grid of the calculated matrix position (m, n).

  Next, in step S4, an initial adjustment of the image position on the generated image array matrix (MX) is performed. That is, the user assumes an interrupt method such as an interrupt type to be set from now on, and operates the corresponding ground symbol in the matrix (MX) in advance while imaging the interrupt position of the ground with respect to the block. By manually rearranging the arrangement positions of the image area symbols, the image area interrupt position is initially adjusted. This initial adjustment is passed if it is not necessary, but in particular, when a reserved area image area is allocated to a block, an reserved area image area symbol is initially displayed on the outer side of the matrix (MX). Therefore, it is necessary to perform initial adjustment of the image area position so that each image area is arranged at a desired position. After the position adjustment operation, a duplication check is always performed, and the image position on the matrix (MX) can be adjusted at any time up to the interrupt execution step S11 (FIG. 4). Yes (see step S8).

  FIG. 5 shows an example of the placement symbol arrangement state in the placement array matrix MX at a certain point in time. The image area arrangement matrix MX has 8 × 8 cells (the number of image areas K = 8), and represents the positional relationship of the image areas in a certain planned entire block in an image, in the row direction (m). Corresponds to the direction (i) of the block reference line. Numbers “1” to “8” are drawing area symbols representing the first to eighth drawing areas to be interrupted in the block, and schematically display the positions of the drawing areas in the block. Here, the third and fifth image area symbols represented by underlined numbers “3” and “5” represent the reserved area image area. As shown in the figure, a second image area symbol “2” arranged at a certain matrix position (m, n) = (5, 2) in the matrix MX is dragged and dropped to a position (3, 1 ), The relative position of the second image area in this block can be adjusted. The positions of other image area symbols can be adjusted in the same manner.

  When the user operates the interrupt type instruction button in the menu area of the display display screen (6) after the matrix creation (S3) or the image area initial adjustment (S4), the CPU 1 displays the interrupt type instruction dialog and displays the interrupt type instruction dialog. Prompt the user for an instruction (also called interrupt type). Here, when "composite type" is designated, the process proceeds to step S5. In step S5, the interrupt type is set to “composite type”, the matrix classification method is set in accordance with the user operation, and the process further proceeds to step S6 for automatically creating a classification diagram. The interrupt types include “composite type”, “simple type”, “partition type”, etc. If “composite type” is not designated, the steps S5 and S6 are passed through, and the next interrupt method indication is further provided. Proceed to step S7 (FIG. 4).

  In step S5, each image area symbol on the image area arrangement matrix MX created through steps S3 and S4 can be grouped to set a sorting method for the block. In other words, the classification method means that when a composite type is set and different interrupt formats are to be applied to each area in the block, each area in the block is displayed on the matrix MX in accordance with the group symbol instruction operation by the user. This is a process for generating a segmentation instruction line that designates an image area to be included and indicates a direction in which each region is segmented. The set classification method is registered in accordance with the operation of the “Register” button.

  After creating / displaying the division instruction line, the process proceeds to step S5, where the total area of the grouped image areas is calculated. Based on the set division method, the block is divided into a plurality of regions (divisions) according to the division instruction line. To create a division map. Here, the total area of all the plots belonging to each division is calculated so that the evaluation value of the division is equal to the sum of the converted evaluation value of the previous land and the evaluation value of the reserved land section. According to the area, the block is graphically divided by a dividing line for the division instruction line, and a divided map of the divided block is displayed in the main display area of the display screen (6).

  When the interrupt type is not designated as “composite type” or after the operation in step S6, the process proceeds to step S7 (FIG. 4), and the interrupt method is set for each block. Interrupt methods include a “back split method” and a “straight back method”, and one of the methods is selected based on a user's instruction operation. For example, for a block that has already been set to “composite type”, an interrupt method is set for each division in the block, and in the case of “simple type”, an interrupt method is collectively set for one entire block. Set. In step S7, a method for specifically interrupting the image area is specified, such as the direction of the reference line for image area division, the image division direction, and the interrupt order. A rectangular block can be sufficiently divided into desired areas by setting a composite or simple type and split or straight type using the area arrangement matrix MX. For a block having a special shape such as a concave shape, the image area is divided by a separate manual interrupt method (called “partition type” in the “interrupt type” classification method described below).

  In the embodiment, the interrupt method is also indicated using the expression “interrupt type”. When the interrupt type is “composite type”, either the back split method or the straight back method is set for each category. Even called "composite type". Further, in the case of “simple type”, it is called “back split type” when the back split method is set, and is called “straight back type” when the straight back method is set. FIG. 6 shows an example of a screen displayed on the display 6 when such an “interrupt type” instruction is also given. In this screen, when the user operates an interrupt type instruction button (not shown) in the menu area, the block number list is displayed in the auxiliary display area. When a desired block number is checked from this list, for example, an interrupt type instruction dialog shown in the center of FIG. 5 is displayed. By pulling down this dialog, the desired interrupt type can be indicated.

  FIG. 7 shows an example of a substitute interrupt order instruction screen, which is displayed when a substitute interrupt order is specifically designated after an interrupt method is designated. In this screen, the image area arrangement matrix MX in which the replacement place interrupt order and the like are already set in a predetermined state is displayed in the matrix window of the upper auxiliary display area, and the main display area corresponds to each area symbol position of the matrix MX. Then, each image area is arranged in the block according to the initial setting value, and a reference line (four lines at the center of the main display area) is displayed to indicate the interruption angle of the replacement area.

  In this case, the direction of the turnover interrupt (also referred to as “interrupt angle”, which is the direction or angle along which the interrupt line that divides each image area runs) is displayed from the interrupt direction instruction dialog of FIG. 8 displayed superimposed on the screen of FIG. Can be directed. That is, when “Direction” is designated as “vertical” (the state shown in FIG. 8) in this dialog, the interrupt angle is set to a direction perpendicular to the reference line (not shown) and “parallel” (not shown). Is set to the same direction as the reference line (the state shown in the main display area in FIG. 7). When “position” is designated “left” (the state shown in FIG. 8), an interrupt is started from the image area corresponding to the left side of the matrix MX (projections in two groups in the matrix MX on the upper right in FIG. 7). When specified as “right”, an interrupt can be started from an image area corresponding to the right side of the matrix MX (not shown). Therefore, the guidance display as shown in FIGS. 7 and 8 allows the user to make the most appropriate interruption while confirming the direction of interruption and the shape of the interruption.

  Next, in step S8, the image position is changed using the image array matrix MX. In order to change the substitute interrupt position, this operation instructs the adjustment of the substitute interrupt position by manually rearranging the position of the place symbol in the matrix MX by imagining the substitute interrupt position according to the user operation. It is made to be able to. In the illustrated operation flow, it is performed after step S6, but it can be performed at any time point from the sorting method (S5) described above to immediately before the interrupt execution (S11) described later.

  As with the previous description using FIG. 5, the change-over interrupt position is changed by dragging and dropping an arbitrary image area symbol whose arrangement position is to be changed in the image area arrangement matrix MX. By moving to a desired position, the relative position of the corresponding image area in the block can be adjusted. When changing the image location, there is always provided a duplication check means for performing an overlap [arrangement] check and confirming that only one image location symbol is arranged in the same row and column. If there is this confirmation, the arrangement state after the movement is registered, but two or more image area symbols are arranged in the same row and column (in other words, the image area symbols are arranged). If there are no rows or columns), a warning to that effect is displayed to prompt the user to move again.

  If the back split method is set, the back split line can be changed in step S9. That is, when a back-split method interrupt is set in step S6 (both composite type and simple type), the user operates the “back split line change” button to insert a back split in the image layout array matrix MX. When a desired row boundary line is designated, the spine split instruction line created in the matrix MX is changed to a desired position where the spine split is desired, and this is registered in accordance with the operation of the “Register” button.

  Furthermore, when the composite type is set, the division diagram can be edited in step S10. That is, when a composite type is set and it is necessary to correct the section map, the user operates the “edit section map” button to instruct to change the image forming the group in the image array arrangement matrix MX. In response to this, the group configuration is changed to change the display of the division instruction line created in the matrix MX and to correct the division diagram. Then, in accordance with the operation of the “Register” button, these group configuration changes and modified division diagrams are registered.

  The above-described split line changing step S9 and segment drawing editing step S10 can be passed through if not necessary. Accordingly, after any of the operations in steps S7 to S10, the process proceeds to interrupt execution step S11, and processing for interrupting the image area in the block according to the setting contents of the image area arrangement matrix MX edited and registered through steps S4 to S10. And an interrupt diagram is created by this process.

[Function of the image layout matrix]
In the substitute land interruption processing system according to one embodiment of the present invention, the location information of the previous place assigned to the planned block is converted into a coordinate system (i, j) with the block reference line as the reference coordinate axis (i). Then, the positional relationship of these previous locations is schematically displayed as a background symbol on the background layout matrix (m, n) corresponding to this coordinate system. This image area symbol represents an image area that is interrupted by the block corresponding to the conventional area, and the position can be rearranged by a user operation, so that the user can easily grasp the objective positional relationship of the conventional area. In addition, it is possible to efficiently indicate the interrupt type that matches the image of the interrupt.

  FIG. 9 to FIG. 13 are diagrams for more specifically explaining the functions of the image area arrangement matrix. Here, an outline of the substitute land interrupt processing according to one embodiment of the present invention will be described. This location replacement interrupt processing system uses the block reference line LR set for the planned block BR as the reference coordinate axis (i), and the location information (i, j) is obtained, and according to the position information (i, j), the previous grounds A1, A2,... are placed on the image ground array matrix MX (m, m) in which the row (m) is aligned with the reference coordinate axis (i). Corresponding image area symbols “1”, “2”,... Are expanded. Then, the matrix MX is edited according to a user operation, and the image areas B1, B2,... Are interrupted in the block BR according to the setting contents of the edited matrix MX. The user imagines the interrupt positions of the image areas B1, B2,... With respect to the block BR by using the image area symbols “1”, “2”,... On the matrix MX reflecting the positional relationship between the previous areas A1, A2,. However, it is possible to efficiently perform a matrix editing operation and obtain a desired interrupt result in a short time. Note that the image area symbols “3” and “5” corresponding to the reserved areas A3 and A5 assigned to the block BR can also be developed on the matrix MX.

  FIG. 9 shows an example of the positional relationship between the planned block and the previous place and the reserved place, and the function of the image area arrangement matrix will be described in more detail below according to this example. It is assumed that the block BR shown in FIG. 9A is selected in the block selection step S1 (FIG. 3) of the operation flow. The block BR to be subject to a change-over interrupt has a rectangular shape, and the block BR includes the previous locations A1, A2, A4, A6-A8 shown in FIG. 9B and the block shown in FIG. 9C. The image areas (B1 to B8: used in FIG. 12 and subsequent figures) are allocated to the reserved area sections A3 and A5. Therefore, in this example, the number K of image areas constituting one block is K = 8, and an image area arrangement matrix MX (see FIG. 10) having the number of rows and columns equal to the image area number K = 8 is prepared. .

  Further, the block BR in FIG. 9A and the conventional ground group in FIG. 9B are not necessarily in the positional relationship as shown in the figure, but the directions (directions) are the same, and P1, P2, P4, P6 to P8 represent the center of gravity of each of the previous locations A1, A2, A4, A6 to A8. In addition, in the reserved area sections A3 and A5, the two reserved areas are allocated in the block BR, and the conversion corresponding to the block evaluation value (average unit price of the block BR x land area) set in the rough conversion work The area value (land area) is very schematically shown.

  In the block reference line setting step S2, the long side of the block BR is set as the block reference line LR. In the matrix creation step S3, when the start of matrix creation is instructed, the direction of the block reference line LR is first changed to the horizontal (i) direction. And the centers of gravity P1, P2, P4, P6 of the previous locations A1, A2, A4, A6 to A8 in an arbitrary coordinate system (i, j) with the direction orthogonal to the block reference line LR as the vertical axis (j). The position (i, j) of P8 is obtained.

  Next, the relative positional relationship of the previous location is acquired from these barycentric positions, and the matrix position (m, n) on the image layout array matrix MX corresponding to this positional relationship according to only the magnitude relationship of the respective axis coordinate values i, j. In addition, the matrix position (m, n) is also determined on the matrix MX (for example, the outer row and column portion) for the image area positions of the reserved area sections A3 and A5 (1 ≦ m, n ≦ 8). Note that the matrix position of the image area is only one in the same row and column while maintaining the relative positional relationship of the centroids.

  Then, each matrix position (m, n) is set as the initial set position of the image areas (B1 to B8) corresponding to the respective previous sites A1, A2, A4, A6, A7, A8 and the reserved land sections A3, A5. As shown in FIG. 10, a map symbol (“land number” or “land number” representing each map) is set in a grid of initially set map positions on a matrix MX having K × K = 8 × 8 grids. “1” to “8” are also developed and displayed in a matrix window in the auxiliary display area of the display screen.

  In short, as shown in FIG. 9 (b), the longitudinal direction lines T1, T2 passing through the centers of gravity P1, P2, P4, P6, P7, P8 of the conventional sites A1, A2, A4, A6, A7, A8. , T4, T6, T7, and T8, the horizontal axis direction coordinates (i) are i1, i2, i4, i6, i7, and i8, respectively, and the horizontal axis direction lines L1, L2, L4, L6, L7, L8 passing through the same center of gravity. If the coordinates (j) in the vertical axis direction are j1, j2, j4, j6, j7, and j8, the respective centroid positions are (i, j) = (i1, j1), (i2, j2), (i4, j4), (i6, j6), (i7, j7), (i8, j8). Therefore, as shown in FIG. 10, the vertical axis and horizontal axis direction lines (T, L) are arranged in the order of the vertical axis and horizontal axis direction coordinate values in the column (n) and row ( m) (for example, in order from the origin side (upper left side in the figure = inner side)) in order.

  Next, discrete matrix positions (m, n) = (1, 1), (2, 4), (6, 6) where the rows and columns corresponding to the vertical and horizontal axis lines passing through the centroids intersect. ), (5, 5), (4, 3), (3, 2) are assigned to the image areas corresponding to the respective previous sites. Further, with regard to the image locations of the reserved land sections A3 and A5, the matrix position (m, n) = (7, 7), (for example, the row and column portion on the outside (lower right side in the figure)) on the matrix MX. Assign to (8,8). Then, an image area symbol is pasted at each matrix position (m, n). In the illustrated example, for easy understanding, the reference symbols “A1” to “A8” of the previous land and the reserved land section and the reference symbols (B1 to B8 of FIG. 12 and subsequent drawings) of the maps after the replacement land allocation. The subscripts “1” to “8” are used for the place symbol displayed in the matrix window MX, but any identifiable symbol or mark is used. be able to.

As for the matrix display of the image area corresponding to the reserved area, at the beginning of the matrix generation, as described above, for example, outside the previous area corresponding display area (1 ≦ m, n ≦ 6) on the image area arrangement matrix MX (7 ≤ m, n ≤ 8) Diagonal grid (m, n) = (7,7), (8,8), reservation corresponding to reservation areas A3, A5 [Fig. 9 (c)] The area symbols “3” and “5” representing the land areas (B3, B5) are automatically displayed. When no reserved area is assigned to the block, the image area arrangement matrix MX naturally includes only an image area corresponding to the previous area. For example, when the reserved land sections A3 and A5 are not allocated to the block BR, the block BR is configured by 6 rows and 6 columns (6 × 6 cells) corresponding to the previous land.

  In this way, the image area symbols “1” to “8” are expanded and displayed in the image area arrangement matrix MX, thereby corresponding to each of the previous and reserved land areas A1 to A8 in the block BR in the replacement area interrupt. The positional relationship of the image areas (B1 to B8) to be performed can be schematically represented. The image area symbols “1” to “8” can be operated by the user, and can be set at desired positions on the matrix MX by the position adjustment method described in step S4 (FIG. 5).

  In steps S5 and S6, the method for dividing the city block BR can be set by the method shown in FIG. 11, and the division diagram can be displayed. For example, when the image area arrangement matrix MX in the image area arrangement state as shown in FIG. 11A is obtained by the prior position adjustment in step S4, the user image area symbols “1” and “2” are obtained in step S5. “,” “8” is associated with the first group G1, and the instruction for associating the image symbols “3” to “7” with the second group G2 is performed, each image including all image symbols belonging to the groups G1, G2 Corresponding to the rectangular area, first and second segment instruction lines LG1 and LG2 are generated and displayed at the end (for example, the left end) of each rectangular area. The direction (n) of both lines LG1, LG2 designates the direction of the dividing line Lg (same as the j direction) in the block BR, and the display positions of the lines LG1, LG2 [the first to third rows (or columns) and the first 4 to 8 rows (or columns)] represent grouping ranges, and designate that the city block BR should be divided into the divisions g1 and g2 corresponding to the respective ranges. In the display example of FIG. 11A, the classification instruction lines LG1 and LG2 are provided with a plurality of protrusions on one side, as in the case of setting the interrupt method described later. Has no special meaning.

  Therefore, in the section map automatic creation step S6, the total area of the image areas represented by the image area symbols included in each grouping range is calculated, and the block BR is stored in the image area arrangement matrix MX as shown in FIG. According to the direction (n) of the first and second section indication lines LG1, LG2, the first and second section areas g1, g2 each having an area corresponding to the total area by the section line Lg along the longitudinal axis (j). Is divided graphically.

In creating the division map, the position of the division line Lg is determined based on the evaluation values of the previous land and the reserved land sections A1 to A8. For example, Sg1 and Sg2 represent the total area of the first and second divisions g1 and g2 corresponding to the first and second groups G1 and G2, and v represents the average unit price (evaluation amount per unit area) of the block BR. If the converted evaluation values of the conventional land or reserved land sections A1 to A8 are U1 to U8 [conventional land converted evaluation value = conventional land evaluation value x "1-α" (α: reduction rate)], the area S1, S2 is calculated by the following equations (1) and (2):
Sg1 = (U1 + U2 + U8) / v (1)
Sg2 = (U3 + U4 + U5 + U6 + U7) / v (2)

  In the interrupt method setting step S7, for example, when it is desired to set the “back split method” for both the first and second sections g1 and g2 of the block BR where “composite type” is set as shown in FIG. & Back split method), by designating the “back split method” to both groups G1 and G2 of the image layout matrix MX, the back split method is specified for both the sections g1 and g2, and further users According to the operation, a desired image area interrupt based on the back split method can be set.

  In this case, when a desired border area portion to be split is designated for each of the groups G1 and G2 divided in the column (n) direction on the border array matrix MX, for example, on the left side of FIG. As shown, spine reference lines LC1 and LC2 indicating spine split positions along the row (m) direction are set at each boundary portion, and predetermined highlighting [for example, a blue color line. (However, double-directional arrows in the figure)] are made. As a result, the groups G1 and G2 are set to be divided into the first and second sections [8 / (1 + 2), 3 / (4 + 5 + 6 + 7)] according to the back split instruction lines LC1 and LC2, respectively.

  Further, an interrupt order of the image areas is further set in each divided area in accordance with a user operation. For example, when the direction is set to “vertical” and the position is set to “left”, the column (n) direction j [perpendicular to the block reference line LR from the left-side image area for each area on the image area arrangement matrix MX. If “parallel” is set, the image area is set to be interrupted by an image area boundary line along the row (n) direction i] parallel to the reference line LR. Accordingly, in the main display area of the display screen 6, as shown on the right side of FIG. 12A, interrupt reference lines L11 to L22 parallel to the block reference line LR correspond to the blocks along with the block BR. As shown on the left side of FIG. 12 (a), the division instruction lines LG1 and LG2 are displayed on the auxiliary display area matrix matrix MX in the rectangular areas of the first and second groups G1 and G2. It is displayed with the protrusion on the left end and the right side.

  Accordingly, as shown on the right side of FIG. 12 (a), spine splitting and splitting can be performed on the block BR in response to various settings relating to the spine split zone in each group and the image area splitting in each zone. it can. That is, when an interrupt is executed with the above settings, as shown in the lower right of FIG. 12 (a), the first division g1 of the city block BR is in accordance with the back reference line Lc1 corresponding to the back instruction line LC1. The first and second sites (B8, B1 + B2) corresponding to the first and second zones are split apart, and each site is drawn in the direction j perpendicular to the interrupt reference lines L11 and L12 from the leftmost drawing site B8. Interrupts at the boundary line and sequentially interrupts the image areas B1 and B2. Similarly, with respect to the second division land g2, the first and second sites (B3, B4 to B7) are split in accordance with the back split reference line Lc2, and each site (B3, B4 to B7) is further separated from the drawing site B3. Interruption is performed at the image boundary line in the direction j perpendicular to the interrupt reference lines L21 and L22, and the image regions B7, B6, B5 and B4 are sequentially interrupted.

  FIG. 13 shows the plots in which the classification method of FIG. 11 is set for the plots BR planned as shown in FIG. 9, and the interrupt method and interrupt order are edited as shown in FIG. An arrangement example of image areas when an image area interrupt is executed in accordance with the setting contents of the arrangement matrix MX is shown. When the image area interrupt is executed, interrupt reference lines L11 to L22 are additionally displayed in the main display area of the display screen 6 in the interrupt diagram representing the interrupt processing results of the areas B1 to B8 to the block BR. (See FIG. 7). For this reason, FIG. 13 shows these interrupt reference lines L11 to L22, and also shows a block reference line LR for comparison with FIG.

  On the other hand, when the “back splitting method” is set for each block BR (back split type), although not shown, the processing applied to each group or division in the above example is executed for the entire block.

  In addition, when the “straight profile method” is set for each block BR (straight profile type), the image area position of the image element arrangement matrix MX is set to a predetermined arrangement state, and the interrupt order (direction and position) is indicated. To do. For example, when the image area position is set and the interrupt direction is designated as “vertical” and the position is designated “left”, as shown in FIG. 12B, one interrupt reference line parallel to the block reference line LR is obtained. L is displayed for the entire city block BR, and one segment instruction line LG is displayed at the left end of the entire matrix MX with the protrusion directed to the right. When a straight-back interrupt is executed with this setting, as shown in the lower right of FIG. 12B, the block BR is interrupted from the leftmost drawing area B1 at the drawing border line in the direction j perpendicular to the interruption reference line L, The image areas B1, B2,..., B3 are sequentially interrupted.

  Furthermore, for example, when it is desired to set the “back split method” and the “straight back method” for the first and second divisions g1 and g2 of the block BR where “composite type” is set (composite type & back split / normal), respectively. Although not shown in the figure, the “back split method” and the “straight back method” are designated for the groups G1 and G2 of the image layout matrix MX, respectively, and the corresponding interrupt order is designated. Each of the divisions g1 and g2 is designated with an interrupt method and an interruption order, and the processing for each group or division explained in FIG. Then, the process for the entire block BR described with reference to FIG. 12B is executed for the groups G2 to g2 for which the “straight profile method” is designated.

  Next, supplementing the change of the back dividing line (S9), for example, in the drawing array matrix MX on the left side of FIG. 12 (a), indicating the boundary line between the fifth and sixth rows, the back dividing instruction in the second group G2 The line LC2 is moved from the boundary between the 4th and 5th rows to the boundary between the 5th and 6th rows, and the spine position is changed to the first area composed of the image areas “3” and “4” and the image areas “5” to “7”. Can be changed between the second zone consisting of "". In this case, when an interrupt is executed, the second section g2 of the block BR shown on the right side of FIG. 12 (a) is divided into the first and second sections B3 and B4 on the top and bottom of the figure with the back dividing line Lc2. Divided into one site and a second site consisting of the image sites B5 to B7.

  Further, with regard to the editing of the division diagram (S10), for example, in the image layout matrix MX of FIG. 11A, the image symbols “8”, “1”, “2”, “3” as the first group G1. When the image area symbols “4” to “7” are instructed as the second group G2, the configuration of the first and second groups G1 and G2 is changed as instructed, and the first division instruction line LG1 is changed. The line is extended to the lower end of the fourth line, the second segment instruction line LG2 is moved to the left end of the fifth line, and is reduced from the upper end of the fifth line to the lower end of the eighth line. In this case, in the division diagram shown on the right side of FIG. 11B, the portion of the image area B3 corresponding to the image area “3” of the matrix MX is incorporated from the second area g2 into the first area g1. The position of the dividing line Lg is corrected so as to have moved greatly to the right side in the figure.

[Interrupt execution and evaluation]
When the interrupt process of step S11 is executed according to the setting contents of the edited image area arrangement matrix, the image area B1 to B8 is displayed in the block BR as an interrupt process result on the display screen 6 as illustrated in FIG. Is displayed in the main display area (see FIG. 13), and the area values of the interrupted image areas B1 to B12 are displayed in the second auxiliary display area. Next, the image areas B1 to B8 are evaluated for economic value according to the arrangement conditions (positional relation and direction with respect to the road, frontage / depth ratio, etc.) and area values obtained by the interrupt processing. Interrupt evaluation values V1 to V8 are calculated for each B8, and are compared with the planned evaluation values U1 to U8 of the respective plots planned in the block BR.

  In the first process, an interruption is performed so as to apportion the block BR to the partition values g1 and g2 by the plan evaluation values U1 to U8 of the respective subordinate land and the reserved land sections A1 to A8 (the plan evaluation values U1 to U8 are averaged). Since the converted area divided by v directly becomes the processing result area value), the interrupt evaluation values V1 to V8 do not coincide with the planned evaluation values U1 to U8. Therefore, for each of the image areas B1 to B8, according to the comparison result between the interrupt evaluation values V1 to V8 and the plan evaluation values U1 to U8 by the previous process, the evaluation value for apportionment is changed and interrupt processing is performed. Re-evaluate.

  If this is repeated several times, the interrupt evaluation values V1 to V8 converge to the planned evaluation values U1 to U8 within a range of errors that can be ignored. Thereby, the sum total of the interrupt evaluation values V1 to V8 becomes equal to the evaluation amount of the entire block BR (the total sum of the planned evaluation values U1 to U8), and the block BR can be finished in a short time.

[Various Embodiments]
The preferred embodiment of the present invention has been described in detail with reference to the drawings. However, this embodiment is merely an example, and various modifications can be made without departing from the spirit of the present invention. For example, in the embodiment, the number of rows and columns of the image area arrangement matrix is the same as the number of image areas interrupted in the planned city block, but may be equal to or more than the number of image areas interrupted in the city block.

It is a block diagram showing the hardware constitutions of the substitute interruption processing system by one Example of this invention. It is a figure for demonstrating the relationship of the information processing system corresponding to the flow of land readjustment project. It is a part of figure showing the operation | movement flow of the substitute interruption process by one Example of this invention. It is the other part of the figure showing the operation | movement flow of the substitute interruption process by one Example of this invention. It is a figure for demonstrating the instruction | indication aspect about adjustment of the substitute interruption position using the matrix by one Example of this invention. It is a figure showing the example of the interruption format instruction | indication screen for instruct | indicating the format of the substituting interruption by one Example of this invention. It is a figure showing the example of the substitute interrupt order instruction | indication screen for instruct | indicating the order of the substitute interrupt by one Example of this invention. It is a figure showing the example of the interruption direction instruction | indication dialog for instruct | indicating the direction of the substitute interruption by one Example of this invention. It is a figure showing the example of the positional relationship of a block and a conventional place, and a reservation place. It is a figure showing the example of an initial matrix generation by one Example of this invention. It is a figure showing the example of a setting of the classification method using the matrix by one Example of this invention. It is a figure showing the example of various settings using the matrix by one Example of this invention. It is a figure showing the example of arrangement | positioning of the image area obtained by the substitution interruption by one Example of this invention.

Explanation of symbols

LR A block reference line passing through the main line of the block BR to be interrupted,
A1, A2, A4, A6, A7, A8 [Previous section (brush)],
A3, A5 reservation area,
P1, P2, P4, P6, P7, P8
L1 to L8 i-axis direction horizontal lines passing through the centroids P1 to P8 and parallel to the reference line LR,
T1-T8 A vertical line in the j-axis direction that passes through the centroids P1-P8 and is orthogonal to the reference line LR,
MX Image layout matrix (matrix window),
"1" to "8" Drawing place symbol (land number),
G1, G2 group (area),
LG1, LG2; LG section indication line,
g1, g2 division land,
Lg dividing line,
B1, B2, B4, B6, B7, B8
B3, B5 reserved area,
LC1, LC2 Back split indicator line,
Lc1, Lc2 spine line,
L11 to L22; L interrupt reference line.

Claims (6)

Block information storage means for storing block terrain information relating to the planned terrain of the block,
A previous location information storage means for storing previous location terrain information relating to the terrain of a plurality of previous locations assigned to the block;
Reference line setting means for setting the longest side of the shape of the block as the reference line of the block based on the block terrain information stored in the block information storage means;
Based on the previous land terrain information stored in the previous land information storage means, the previous ground position acquisition means for acquiring the gravity center position information of each previous ground with the reference line set by the reference line setting means as the reference coordinate axis; ,
Matrix generating means for generating an image area arrangement matrix having the same number of rows and columns as the number of image areas constituting the block;
In accordance with the relative positional relationship of the center-of-gravity position information of each previous location acquired by the previous location position acquisition unit, the matrix generation unit that generates the image location symbol indicating the background corresponding to the previous location is generated by the matrix generation unit. Image area symbol expansion means for expanding at corresponding positions on the image area array matrix;
Matrix display means for displaying an image area arrangement matrix in which the image area symbols are expanded by the image area symbol expansion means;
Matrix editing means for editing the arrangement of the place symbol displayed by the matrix display means on the drawing area arrangement matrix in response to a user operation;
A duplication check means for checking that the place symbol whose arrangement has been changed by the matrix editing means is not duplicated in the same row or column;
Each previous ground corresponding to the above-mentioned ground symbol calculated from the row position or column position of the ground symbol after being checked by the duplication checking means, and the previous land topographic information stored in the previous ground information storage means In accordance with the evaluation amount, image area interrupting means for interrupting the image area corresponding to the image area symbol in the direction of the reference line in the block or in the direction perpendicular to the reference line is provided. Replacement interrupt processing device. The image area symbol developing means expands an image area symbol indicating that the image area corresponds to the reserved area assigned to the block, and an image area symbol indicating that the image area corresponds to the previous area. Expanded to a region on the image layout matrix different from the region
The land replacement interrupt processing apparatus according to claim 1, wherein the image area interrupting unit further interrupts the image area according to the evaluation amount of the reserved area.   3. The place replacement interrupt according to claim 1, wherein the place symbol expanding means expands a place symbol so as not to overlap in the same row or column on the place array matrix. Processing equipment. The matrix editing means includes
Symbol position changing means for changing the placement of the image area symbols on the image area arrangement matrix in accordance with an operation of moving the image area symbols by the user;
Sorting means for sorting the image area arrangement matrix into a plurality of areas in a row or column direction according to a sorting instruction operation by a user;
4. A division diagram display means for displaying a division diagram obtained by dividing the block into a plurality of division areas corresponding to the areas divided by the division means. A substitute interrupt processing device described in 1. The matrix editing means is configured to select the entire area array matrix or a predetermined area divided in the row or column direction on the area array matrix in the column or row direction in accordance with a spine division instruction operation by a user. Has a back splitting means for splitting the back into two areas,
The image area interrupting means is
Corresponding to the area divided on the drawing area arrangement matrix by the back dividing section means, the entire block or the dividing area corresponding to the predetermined area is divided into two sites,
The position in the direction of the reference line or the direction perpendicular to the reference line in each site divided by the spine execution means according to the row position or the column position of the image area symbol in each area on the image area arrangement matrix The replacement place interrupt processing apparatus according to any one of claims 1 to 4, wherein an image area corresponding to the image area symbol is interrupted. Block information storage means for storing block terrain information relating to the planned terrain of the block, and previous place information storage means for storing previous landform information relating to a plurality of previous landforms assigned to the block In a computer that functions as a substitute interrupt processing device,
A reference line setting step for setting the longest side of the shape of the block as the reference line of the block based on the block terrain information stored in the block information storage means;
Based on the previous ground terrain information stored in the previous ground information storage means, the previous ground position acquisition step for acquiring the gravity center position information of each previous ground with the reference line set in the reference line setting step as a reference coordinate axis; ,
A matrix generation step of generating an image area arrangement matrix having the same number of rows and columns as the number of image areas constituting the block;
In accordance with the relative positional relationship of the gravity center position information of each previous location acquired in the previous location position acquisition step, an image location symbol representing the image location corresponding to the previous location is generated in the matrix generation step. An image area symbol expansion step to expand at a corresponding position on the image area array matrix;
A matrix display step for displaying an image area arrangement matrix in which the image area symbols are expanded in the image area symbol expansion step;
A matrix editing step for editing the arrangement of the image area symbols displayed in the matrix display step on the image area arrangement matrix in accordance with a user operation;
A duplication check step for checking that the place symbol whose arrangement has been changed in the matrix editing step is not arranged in duplicate in the same row or column;
Each previous ground corresponding to the above-mentioned ground symbol calculated from the row position or column position of the ground symbol after being checked in the duplication checking step and the previous ground land information stored in the previous ground information storage means In accordance with the evaluation amount, a procedure including an image area interruption step for interrupting an image area corresponding to the image area symbol in the direction of the reference line in the block or the direction perpendicular to the reference line is executed. Replacement interrupt processing program.

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