CN115658045A - System and method for rapidly building geographic information data application - Google Patents

Abstract

The invention provides a system and a method for rapidly building geographic information data application, wherein the system comprises the following steps: a component acquisition module for acquiring a geographic component representing each geographic cell; the possibility analysis module is used for analyzing the combination possibility of the geographic components to obtain a combination possible set; the application building module is used for acquiring a building request and analyzing the request so as to call the first component to build to obtain a first geographic application; the result matching module is used for carrying out result matching on each possible combination set based on the analysis result and reserving the corresponding geographic component; the component matching module is used for matching all reserved geographic components with all first components one by one; and the optimization module is used for performing first optimization on the first geographic application when all reserved geographic components are more than the first components contained in the first geographic application, otherwise, performing second optimization to realize optimization on the built application, improve the adaptation degree of the application and the request and indirectly improve the building efficiency.

Description

System and method for rapidly building geographic information data application

Technical Field

The invention relates to the technical field, in particular to a system and a method for quickly building geographic information data application.

Background

Geographic information data is the basis of many relevant works such as city planning, environmental protection, land survey, road construction, and the like, generally when carrying out application and building, match based on the subassembly that exists in request and the database, according to the construction rule that system stipulated in advance, realize the application and build, but in the process of building, can not carry out result matching verification to the subassembly of building, lead to using to build and can have unreasonable condition, and then influence and build efficiency.

Therefore, the invention provides a system and a method for rapidly building geographic information data application.

Disclosure of Invention

The invention provides a system and a method for quickly building geographic information data application, which are used for matching a built possible combination set with a result of analysis of a request, so as to carry out matching verification on geographic application directly built according to the request, and realize optimization of built application based on matching verification results under different conditions, thereby improving the adaptability of the application and the request and indirectly improving the building efficiency.

The invention provides a system for rapidly building geographic information data application, which comprises:

the device comprises a component acquisition module, a component selection module and a component selection module, wherein the component acquisition module is used for acquiring first geographic information of a preset area and preprocessing the first geographic information according to the unit attribute of each geographic unit in the preset area to obtain a geographic component representing each geographic unit;

the possibility analysis module is used for analyzing the combination possibility of the geographic components to obtain a combination possible set;

the application building module is used for obtaining a building request, analyzing the request, calling a first component from all the geographic components, and building to obtain a first geographic application;

the result matching module is used for matching the result of each possible combination set based on the analysis result, and when the matching results of the corresponding sets are successful, the corresponding geographic components are reserved;

the component matching module is used for considering the first geographic application as a built geographic application when all reserved geographic components are matched with all first components one by one;

the first optimization module is used for extracting redundant components when all reserved geographic components are more than first components contained in the first geographic application, performing first optimization on the first geographic application and regarding the first geographic application as a built geographic application;

and the second optimization module is used for extracting the second components from all the first components and constructing an initial array of each second component when all the reserved geographic components are less than the first components contained in the first geographic application, and performing second optimization on the first geographic application to be regarded as the built geographic application.

Preferably, the component acquiring module includes:

the point component acquisition unit is used for acquiring a point layer structure of each coordinate position in the regional geographical map according to the first geographical information of the preset region, and setting a geographical attribute to each layer structure in the point layer structure to obtain a point component; the standard structure corresponding to each coordinate position is the same, and the geographic information of each coordinate position in the vertical direction is different;

the attribute acquisition unit is used for geographically dividing the preset area according to the area division diagram of the preset area and setting unit attributes to each geographic unit based on an area-geographic mapping table;

and the geographic component acquisition unit is used for distributing and acquiring all the point components contained in each geographic unit according to the position-relation database, and performing component processing on the point components contained in the same geographic unit by combining the unit attributes to acquire the geographic components representing the corresponding geographic units.

Preferably, the likelihood analysis module includes:

the label establishing unit is used for calling history establishing requirements, extracting a history component set corresponding to each history establishing requirement, determining the requirement weight of each history component in each history component set, and establishing a representative label, wherein the representative label comprises: history components, history building requirements and requirement weights;

and the set building unit is used for extracting the historical components based on all the representative tags and building a combined possible set of the corresponding geographic components.

Preferably, the second optimization module includes:

an object acquisition unit configured to acquire a representative object set of each second component;

the array construction unit is used for constructing an initial array corresponding to the second component based on the object attribute of each representative object in the corresponding representative object set;

a fusion judging unit for judging whether all the initial arrays have fusion possibility;

wherein r1 represents the similarity value of all initial arrays; n1 represents the total number of initial arrays present;

representing the component weight corresponding to the i1 st initial array;

representing an array representative value for the i1+1 st initial array;

representing an array representative value for the i1 st initial array;

when the similarity value is greater than or equal to a preset value and each array representative value is greater than the corresponding array preset value, judging that all initial arrays have fusion possibility, and regarding the first geographic application as a built geographic application;

otherwise, judging that all the initial arrays do not have the fusion possibility, and according to the judgment result

Screening all the second components for a third component that affects the likelihood of fusion, wherein,

represents a constant;

representing an array preset value corresponding to the ith 1 st initial array;

carrying out number random screening on the third component according to a random function, and removing the number of the random screening on the third component;

wherein rand represents a random function; r2 represents the number of random screenings; n3 represents satisfaction of the selection

The number of the third components of (a);

、

represents a constant, and

is less than

；

A number determining function representing a required screening component based on the similarity value r 1; []Represents a rounding symbol; wherein the content of the first and second substances,

and

；

and performing second optimization on the first geographic application according to the removed residual assemblies, and regarding the first geographic application as the built geographic application.

Preferably, the application building module includes:

the identification obtaining unit is used for obtaining the request structure of the construction request and obtaining the structure identification of each mapping substructure in the request structure according to a preset structure mapping table;

the component calling unit is used for acquiring a component identifier which has a matching relation with the structure identifier according to the identifier-corresponding relation and calling a first component from all the geographic components based on the component identifier;

and the assembly building unit is used for building all the called first assemblies based on an assembly building mechanism to obtain the first geographic application.

Preferably, the component matching module includes:

the matching unit is used for respectively matching all reserved geographic components with the called first component;

the judging unit is used for judging whether the matching result is one-to-one complete matching;

if yes, all reserved geographic components are judged to be matched with all first components one by one.

Preferably, the first optimization module includes:

the script dividing unit is used for extracting a first script of each redundant component and dividing a scene script and an application script in the first script;

the instance testing unit is used for carrying out first testing on the scene scripts in the same first script according to the first testing instance and carrying out second testing on the application scripts in the same first script according to the second testing instance;

the component qualification judging unit is used for acquiring a first test parameter and a second test parameter, transmitting the first test parameter and the second test parameter to the target building function and judging whether the script qualification standards are met;

if yes, judging that the corresponding redundant components are qualified;

if not, judging that the corresponding redundant assembly is unqualified;

the component adjusting unit is used for adjusting the unqualified components to obtain qualified components;

and the application optimization unit is used for carrying out first optimization on the first geographic application based on all qualified assemblies and regarding the first geographic application as the built geographic application.

Preferably, the component adjustment unit includes:

the parameter extraction block is used for extracting unqualified parameters based on the target building function, determining the parameter type of the unqualified parameters and acquiring a script to be optimized matched with the unqualified parameters from a parameter-script database;

an occupation case determination block for determining the scene occupation case of the parameter type based on the first test parameter and the application occupation case based on the second test parameter to extract unqualified scripts;

the script adding block is used for optimizing the unqualified script based on the script to be optimized, and if the optimization result is full optimization, adding the script to be optimized to the corresponding redundant component and regarding the script to be optimized as a qualified component;

the position locking block is used for locking the position which cannot be optimized in the unqualified script if the optimization result is not fully optimized;

the script locking block is used for synchronously locking the first sub-script at the same position of the script to be optimized when only one position fails to be optimized exists;

the integrity judgment block is used for judging the integrity of the first sub-script, if the first sub-script is complete, a second sub-script matched with the first sub-script is called from a script optimization database, and the script at the position which cannot be optimized is replaced according to the second sub-script;

if the position is incomplete, performing first expansion on the position which cannot be optimized, performing second expansion on the first sub-script according to the left-side script identification and the right-side script identification after the first expansion, and replacing the script at the first expansion position according to the second expansion script;

the array building block is used for respectively obtaining the position attribute and the script attribute of each position which cannot be optimized when a plurality of positions which cannot be optimized exist, and building an array, wherein the array comprises a plurality of arrays, and each array comprises the position attribute and the script attribute corresponding to the position which cannot be optimized;

the similar labeling block is used for carrying out first similar labeling on position attributes and second similar labeling on script attributes on the array;

the difficulty determining block is used for extracting the first arrays of the same labeling result and determining the adjustment difficulty of the same labeling result according to the array weight of each first array;

the synchronous replacement block is used for synchronously replacing the same labeling result with the adjustment difficulty smaller than the preset difficulty according to the obtained matched script to be replaced;

the state setting block is used for inserting a new position into the left side of the position which cannot be optimized in the same labeling result and the adjustment difficulty of which is greater than or equal to the preset difficulty, adding a script to be executed in the new position, setting the script to be in a state to be executed, and meanwhile, setting the script of the position which cannot be optimized on the right side of the new position to be in a sleep state;

and the adjusting block is used for adjusting the unqualified assembly based on all synchronous replacement results and the new position setting result to obtain the qualified assembly.

The invention provides a method for quickly building geographic information data application, which comprises the following steps:

step 1: acquiring first geographic information of a preset area, and preprocessing the first geographic information according to the unit attribute of each geographic unit in the preset area to obtain a geographic component representing each geographic unit;

step 2: analyzing the combination possibility of the geographic components to obtain a combination possibility set;

and step 3: acquiring a building request, analyzing the request, calling a first component from all geographic components, and building to obtain a first geographic application;

and 4, step 4: performing result matching on each possible combination set based on the analysis result, and reserving the corresponding geographic component when the matching results of the corresponding sets are successful;

and 5: when all reserved geographic components are matched with all first components one by one, the first geographic application is regarded as a built geographic application;

step 6: when all reserved geographic components are more than first components contained in the first geographic application, extracting redundant components, performing first optimization on the first geographic application, and regarding the first geographic application as a built geographic application;

and 7: and when all the reserved geographic components are less than the first components contained in the first geographic application, extracting the second components from all the first components, constructing an initial array of each second component, performing second optimization on the first geographic application, and regarding the first geographic application as a built geographic application.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a structural diagram of a system for rapidly building geographic information data applications according to an embodiment of the present invention;

fig. 2 is a flowchart of a method for quickly building a geographic information data application in the embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

The invention provides a system for rapidly building geographic information data application, as shown in figure 1, comprising:

the device comprises a component acquisition module, a component selection module and a component selection module, wherein the component acquisition module is used for acquiring first geographic information of a preset area and preprocessing the first geographic information according to the unit attribute of each geographic unit in the preset area to obtain a geographic component representing each geographic unit;

the possibility analysis module is used for analyzing the combination possibility of the geographic components to obtain a combination possible set;

the application building module is used for obtaining a building request, analyzing the request, calling a first component from all the geographic components, and building to obtain a first geographic application;

the result matching module is used for matching the result of each possible combination set based on the analysis result, and when the matching results of the corresponding sets are successful, the corresponding geographic components are reserved;

the component matching module is used for considering the first geographic application as the built geographic application when all the reserved geographic components are matched with all the first components one by one;

the first optimization module is used for extracting redundant components, performing first optimization on the first geographic application and regarding the first geographic application as a built geographic application when all reserved geographic components are more than the first components contained in the first geographic application;

and the second optimization module is used for extracting the second components from all the first components and constructing an initial array of each second component when all the reserved geographic components are less than the first components contained in the first geographic application, and performing second optimization on the first geographic application to be regarded as the built geographic application.

In this embodiment, the preset region may refer to a region such as a country, a province, a city, a town, a village, and the like.

In this embodiment, the first geographical information refers to a location information map of each area, including: aerial images, satellite images, panoramic images, lidar data, vector maps, three-dimensional models, and the like.

In this embodiment, since the point location information corresponding to different location points is different, and the information includes different geographies, rivers, buildings, and the like, the point division is performed according to the situation corresponding to the point information, so as to obtain corresponding units, that is, unit attributes of the units can be obtained, and the unit attributes are related to geographic information, so as to obtain objects included in each geographic unit, so as to obtain geographic components, and the geographic components are constructed by different page design elements, for example, the unit 1 includes buildings 1 and 2 and a road 1, then it is necessary to obtain appearance forms of the buildings 1 and 2 and layout situations between the buildings and the road based on the first geographic information, and the buildings and the road can be regarded as separate design elements, mainly to obtain the geographic components for convenience, because the geographic components are constructed based on different movable design elements, and the geographic information of different geographic units is changed, so that the geographic components are set to be movable elements.

In this embodiment, for example, there are geographic components 1,2, 3, and 4, the geographic components needed in history request 1 are 1,2, the geographic components needed in history request 2 are 1, 3, 4, and the geographic components needed in history request 3 are 2, 3, then the combined possible set of geographic components 1 is request 1,2, the combined possible set of geographic components 2 is request 1, 3, the combined possible set of geographic components 3 is request 2, 3, and the combined possible set of geographic components 4 is request 2;

in this embodiment, the combination likelihood analysis is to retrieve the set that each component may exist from the historical request and the database of historical component combinations that match the historical request.

In this embodiment, the request analysis is obtained by analyzing a model trained in advance, and the model is obtained by training a sample based on different requests and analysis components matched with the requests, so that the existing construction requests can be analyzed, and the first component can be directly obtained by calling from all geographic components.

In the embodiment, the building of the first geographic application is obtained by building the called first component based on a preset application building mechanism, mainly aims to realize visual display of the application by placing the component at a position, rendering a scene and the like, and is realized by fusing a GIS (geographic information system) technology and an OSG (open service gateway) technology in the rendering process.

In this embodiment, the parsing result includes various identifiers, and the corresponding geographic component is retained by matching the identifier with the identifier of each component in the combined possible set, and if it is said that each parsing identifier has a completely consistent component matching identifier, the response is regarded as successful.

In this embodiment, the geographic components that are retained are: assemblies 1,2, 3, the first assembly being: the components 1,2, 3 are considered to be one-to-one matched at this time.

If the first component is: component 1,2, the redundant component being now component 3 of the reserved geographical components;

if the first component is: component 1,2, 3, 4, in this case component 4 is the second component.

In this embodiment, the first geographic application is built based on the called first component, and therefore, the first optimization refers to that when the redundant component is extracted, that is, it indicates that a building imperfection condition may exist in the first geographic application, and therefore, the redundant component is analyzed to perfect the first geographic application, which may be a perfect in a specific geographic function, for example, a road sign and the like are added.

Meanwhile, when the second component is extracted, namely the situation that the building is possibly influenced in the first geographic application is shown, therefore, the second optimization refers to analyzing the second component to improve the first geographic application, for example, the existing road sign deviates to the northeast direction, at the moment, the direction of the road sign needs to be turned, namely, the wrong direction may exist originally, and the built geographic application is obtained after the adjustment.

The beneficial effects of the above technical scheme are: and matching the constructed possible combination set with the analysis result of the request to perform matching verification on the geographic application directly constructed according to the request, and optimizing the constructed application based on the matching verification results under different conditions, so that the adaptation degree of the application and the request is improved, and the construction efficiency is indirectly improved.

The invention provides a system for rapidly building geographic information data application, wherein the assembly acquisition module comprises:

the point component acquisition unit is used for acquiring a point layer structure of each coordinate position in the regional geographical map according to the first geographical information of the preset region, and setting a geographical attribute to each layer structure in the point layer structure to obtain a point component; the standard structure corresponding to each coordinate position is the same, and the geographic information of each coordinate position in the vertical direction is different;

the attribute acquisition unit is used for geographically dividing the preset area according to the area division diagram of the preset area and setting unit attributes to each geographic unit based on an area-geographic mapping table;

and the geographic component acquisition unit is used for distributing and acquiring all the point components contained in each geographic unit according to the position-relation database, and performing component processing on the point components contained in the same geographic unit by combining the unit attributes to acquire the geographic components representing the corresponding geographic units.

In this embodiment, since the setting of each location point in the up-down direction is different, including the type of the ground corresponding to the location point, the land, the asphalt road, or the lime road, the rubber road, and the like, and further including the facilities on the ground corresponding to the location point, such as the building facilities, the fitness facilities, and the like, the real space situation of the location point is mainly displayed more intuitively, that is, the point layer structure (the ground structure, the facility structure, and the like) of the location point is obtained, and the geographic attribute is set for each layer result (the ground structure is provided with the ground type attribute, the structure is provided with the set type attribute, and the attribute is also related to the appearance, the size, the color, and the like), so as to obtain the point component, and the point component mainly represents a visual display content based on the ground and the related facility components above the ground, and can also be understood as a design element of the location point.

In this embodiment, the area division map is, for example, each road, roadside flower pool zone, building, and the like in the preset area are geographically divided, the divided geographical areas can be regarded as geographical units, each unit attribute is obtained based on an area-geographical mapping table, and the area-geographical mapping table includes different divided areas and attributes corresponding to each divided area, so that the unit attribute of the geographical unit can be obtained, and the unit attribute is related to geographical coordinates and the like of the unit.

In this embodiment, the location-relationship database includes geographic locations of different cells and point components matched with the geographic locations, and therefore, the point components included in the geographic coordinates can be determined according to the geographic coordinates corresponding to the cell attributes, and the matched point components are subjected to component processing to obtain the geographic components of the geographic cells.

In this embodiment, the geographic unit includes the point components 1,2, and 3, and then the point components 1,2, and 3 are spliced according to the geographic coordinates to obtain the geographic component.

The beneficial effects of the above technical scheme are: and acquiring the cushion structure of each coordinate position according to the first geographic information to further construct the point component, and performing component processing on the point component by performing region division on a preset region to obtain the geographic component, so as to provide a component foundation for a subsequent construction request.

The invention provides a system for rapidly building geographic information data application, wherein a possibility analysis module comprises:

the label establishing unit is used for calling history establishing requirements, extracting a history component set corresponding to each history establishing requirement, determining the requirement weight of each history component in each history component set, and establishing a representative label, wherein the representative label comprises: history components, history building requirements and requirement weights;

and the set building unit is used for extracting the historical components based on all the representative tags and building a combined possible set of the corresponding geographic components.

In this embodiment, the history building requirements are based on all the requirements that have been built successfully before the current time, and therefore, a history component set can be obtained.

In the embodiment, each history building requirement has a primary requirement and a secondary requirement of the component, so that effective determination can be performed according to the requirement weight of the component, and the more the component is required, the greater the corresponding requirement weight is, so that a label is set for each history component in the corresponding history component set according to the weight and the requirement type.

In the embodiment, the extraction of the historical component refers to the constructed condition of the component under different requirements, and provides a basis for subsequently meeting construction requests at the current moment.

The beneficial effects of the above technical scheme are: the component set is constructed by acquiring historical construction requirements, and a combined possible set is constructed by setting different representative tags and extracting the same historical components, so that an effective verification basis is provided for subsequent result matching.

The invention provides a system for rapidly building geographic information data application, wherein the second optimization module comprises:

an object acquisition unit configured to acquire a representative object set of each second component;

the array construction unit is used for constructing an initial array corresponding to the second component based on the object attribute of each representative object in the corresponding representative object set;

a fusion judging unit for judging whether all the initial arrays have fusion possibility;

wherein r1 represents the similarity value of all initial arrays; n1 represents the total number of initial arrays present;

representing the component weight corresponding to the i1 st initial array;

representing the array representative value of the i1+1 st initial array;

representing an array representative value for the i1 st initial array;

when the similarity value is greater than or equal to a preset value and each array representative value is greater than the corresponding array preset value, judging that all initial arrays have fusion possibility, and regarding the first geographic application as a built geographic application;

otherwise, judging that all the initial arrays do not have the fusion possibility, and according to the judgment

Screening all the second components for a third component that affects the likelihood of fusion, wherein,

represents a constant;

representing an array preset value corresponding to the ith 1 st initial array;

carrying out number random screening on the third component according to a random function, and removing the number of the random screening on the third component;

wherein rand represents a random function; r2 represents the number of random screenings; n3 represents satisfaction of the selection

The number of the third components of (a);

、

represents a constant, and

is less than

；

A number determining function representing a required screening component based on the similarity value r 1; []Represents a rounding symbol; wherein the content of the first and second substances,

and

；

and performing second optimization on the first geographic application according to the removed residual assemblies, and regarding the first geographic application as a built geographic application.

In this embodiment, the representative object may be understood as: the relative arrangement of the components, etc., such as color, shape, function, property, etc., and the elements contained in each corresponding set of second components are the same.

In this example, the initial array: { element 1, element 2, element 3, element 4 }, where values corresponding to different elements are preset, and elements consistent with corresponding components are called from an element database to construct an initial array, and each element has its corresponding element value, so that an array representative value corresponding to the initial array can be calculated, and the array representative value is obtained by multiplying the element value of each element by the weight value of the corresponding element and then accumulating all the values, and the element value is a normalized value between 0 and 1, mainly for convenience of calculation, and the weight values are also preset, and elements corresponding to different arrays are the same, and the weight value corresponding to each element may be different, but the cumulative sum of the weight values corresponding to all elements in the same array is 1.

In this embodiment, the component weight is preset and obtained by analyzing the component in the corresponding possible combination set, that is, accumulating all the demand weights in the corresponding possible combination set, and then calculating an average value, and taking the average value as the component weight.

In this embodiment, the preset value is generally 0.5.

In the embodiment shown in the above-mentioned figure,

。

in this embodiment, the array preset values are preset, and the array preset values corresponding to different initial arrays are different, and the value range is 0.4 to 0.6.

In the embodiment shown in the above-mentioned figure,

the value is less than 0.

In this embodiment, the second assembly includes: 1. 2 and 3, at this time, the third component obtained by meeting the conditions is: components 1,2, then, at this time, the corresponding value of n3 is 2, at this time,

the value of (a) is 2 or 1.

In this embodiment, if the number of the remaining components after the culling is 0, the previous first geographic application is kept unchanged, and if the number of the remaining components after the culling is not 0, the first geographic application is optimized according to the remaining components.

In the embodiment shown in the above-mentioned figure,

has a value range of [0, n 3]]。

In this embodiment of the present invention,

has a value range of [0,1]，

Has a value range of [1,2]。

The beneficial effects of the above technical scheme are: whether fusion possibility exists is determined by obtaining the initial arrays of each second assembly and calculating the similarity value between the arrays, so that irrelevant assemblies are eliminated through the judgment standard, optimization of first geographic application is achieved, the rationality of optimization is guaranteed, the accuracy of the geographic application is guaranteed, and the building efficiency is indirectly improved.

The invention provides a system for rapidly building geographic information data application, wherein an application building module comprises:

the identification obtaining unit is used for obtaining the request structure of the construction request and obtaining the structure identification of each mapping substructure in the request structure according to a preset structure mapping table;

the component calling unit is used for acquiring a component identifier which has a matching relation with the structure identifier according to the identifier-corresponding relation and calling a first component from all the geographic components based on the component identifier;

and the assembly building unit is used for building all the called first assemblies based on an assembly building mechanism to obtain the first geographic application.

In this embodiment, the building request is, for example, to obtain geographic applications of the area 1 and the area 2, and then the request includes information related to the area 1 and information related to the area 2, and the request structure includes [ area 1 structure ] [ area 2 structure ], so that the identifier of [ area 1 structure ] and the identifier of [ area 2 structure ] can be obtained by mapping.

In this embodiment, the preset structure mapping table includes different request structures and identifiers matching with the structures, and thus the structure identifiers can be directly obtained.

In this embodiment, the identifier-mapping relationship includes the structure identifier and the component identifier matching the structure identifier, and the first component can be effectively obtained.

In this embodiment, the component building mechanism is preset, and different components are set at the position of placement.

The beneficial effects of the above technical scheme are: the component identification is obtained by obtaining the structure of the request according to the mapping table and the relation, and the component is built through a mechanism, so that an effective basis is provided for application building, and the quick building is facilitated.

The invention provides a system for rapidly building geographic information data application, wherein the assembly matching module comprises:

the matching unit is used for respectively matching all reserved geographic components with the called first components;

the judging unit is used for judging whether the matching result is one-to-one complete matching;

if yes, all reserved geographic components are judged to be matched with all first components one by one.

In this embodiment, a component match refers to whether there is a complete match with the first component for each of all geographic components, and if so, the component is considered to be a complete match.

The beneficial effects of the above technical scheme are: through the geographic component that will remain and the subassembly of transferring match, be convenient for judge whether complete match, make things convenient for subsequent optimization, indirectly improve and build efficiency.

The invention provides a system for rapidly building geographic information data application, wherein a first optimization module comprises:

the script dividing unit is used for extracting a first script of each redundant component and dividing a scene script and an application script in the first script;

the instance testing unit is used for carrying out first testing on the scene scripts in the same first script according to the first testing instance and carrying out second testing on the application scripts in the same first script according to the second testing instance;

the component qualification judging unit is used for acquiring a first test parameter and a second test parameter, transmitting the first test parameter and the second test parameter to the target building function and judging whether the script qualification standards are met;

if yes, judging that the corresponding redundant components are qualified;

if not, judging that the corresponding redundant assembly is unqualified;

the component adjusting unit is used for adjusting the unqualified components to obtain qualified components;

and the application optimization unit is used for carrying out first optimization on the first geographic application based on all qualified assemblies and regarding the first geographic application as the built geographic application.

In this embodiment, the script refers to the component program code of the corresponding component, and each component has its existing geographic scene and component application, so the scene script and the application script are obtained by dividing the scene and the application.

In this embodiment, the first test case and the second test case are both obtained in advance, the test cases are mainly used for testing corresponding program codes, the first test case is a scenario test case, the second test case is an application test case, the first test case is used for testing whether the first script is qualified, and the test of the corresponding script is realized based on the cases based on code test software.

In this embodiment, the first test parameters H1 and H2 and the second test parameters H01 and H02, and the target component function are preset, for example, Y1= H (H1, H2.,. H01, H02.,..,. H.), during the process of determining whether the test parameters are qualified, the test parameters are compared with a preset standard parameter range, if all the test parameters are in the comparison range, the corresponding redundant component is determined to be qualified, and if not, the corresponding redundant component is determined to be unqualified.

In this embodiment, the first test parameter is obtained based on the first test result, the second test parameter is obtained based on the second test result, and the test parameters are related to the normal type, the abnormal position, the abnormal condition, and the like of the script.

The beneficial effects of the above technical scheme are: the method comprises the steps of dividing a scene and an application of a script, and testing a test case to determine whether the script meets a standard or not based on a target building function so as to determine whether corresponding redundant components are qualified or not and provide a reference basis for quickly building the application.

The invention provides a system for rapidly building geographic information data application, wherein a component adjusting unit comprises:

the parameter extraction block is used for extracting unqualified parameters based on the target building function, determining the parameter type of the unqualified parameters and acquiring a script to be optimized matched with the unqualified parameters from a parameter-script database;

an occupation case determination block for determining the scene occupation case of the parameter type based on the first test parameter and the application occupation case based on the second test parameter to extract unqualified scripts;

the script adding block is used for optimizing the unqualified script based on the script to be optimized, and if the optimization result is full optimization, adding the script to be optimized to the corresponding redundant component and regarding the script to be optimized as a qualified component;

the position locking block is used for locking the position which cannot be optimized in the unqualified script if the optimization result is not full optimization;

the script locking block is used for synchronously locking the first sub-script at the same position of the script to be optimized when only one position fails to be optimized exists;

the integrity judgment block is used for judging the integrity of the first sub-script, if the first sub-script is complete, a second sub-script matched with the first sub-script is called from a script optimization database, and the script at the position which cannot be optimized is replaced according to the second sub-script;

if the position is not complete, performing first expansion on the position which cannot be optimized, performing second expansion on the first sub-script according to the left-side script identification and the right-side script identification after the first expansion, and replacing the script of the first expansion position according to the second expansion script;

the array building block is used for respectively obtaining the position attribute and the script attribute of each position which cannot be optimized when a plurality of positions which cannot be optimized exist, and building an array, wherein the array comprises a plurality of arrays, and each array comprises the position attribute and the script attribute corresponding to the position which cannot be optimized;

the similar labeling block is used for carrying out first similar labeling on position attributes and second similar labeling on script attributes on the array;

the difficulty determining block is used for extracting the first arrays of the same labeling result and determining the adjustment difficulty of the same labeling result according to the array weight of each first array;

the synchronous replacement block is used for synchronously replacing the same labeling result with the adjustment difficulty smaller than the preset difficulty according to the obtained matched script to be replaced;

the state setting block is used for inserting a new position into the left side of the position which cannot be optimized in the same labeling result and the adjustment difficulty of which is greater than or equal to the preset difficulty, adding a script to be executed in the new position, setting the script to be in a state to be executed, and meanwhile, setting the script of the position which cannot be optimized on the right side of the new position to be in a sleep state;

and the adjusting block is used for adjusting the unqualified assembly based on all synchronous replacement results and the new position setting result to obtain the qualified assembly.

In this embodiment, the unqualified parameter refers to a parameter that is not within the corresponding standard range, and further determines the parameter type (for example, an abnormal type, a parameter type, and the like), and the parameter-script database includes different parameters and an optimization script matched with the parameters, so that the to-be-optimized script with the unqualified parameter can be obtained.

In this embodiment, for example, the parameter type is related to both the scenario-related parameter and the application-related parameter, then the scenario occupation situation needs to be obtained by determining the relationship between the unqualified parameter and the first test parameter, and the application occupation situation needs to be obtained by determining the relationship between the unqualified parameter and the second test parameter, and then the script corresponding to the test parameter with the related relationship is used as the unqualified script, for example, the parameter type is related to the first test parameter 1 and related to the second test parameter 2, where the first test parameter 1 corresponds to the script 01, the second test parameter corresponds to the script 02, and then the existing unqualified scripts are the scripts 01 and 02.

In the embodiment, the script to be optimized optimizes and optimizes the unqualified script to determine whether the script to be optimized can be used as a basis for optimizing the unqualified script, and the script to be optimized is capable of being used in the case of full optimization, otherwise, the script capable of being optimized is screened from the script to be optimized by combining with the problems of the unqualified script, so that optimization is realized.

In this embodiment, the unqualified script: 000010000, wherein the position where 1 exists is the position which cannot be optimized, at this time, a position which cannot be optimized exists, and the first sub-script in the script to be optimized, which is consistent with the position where 1 in the unqualified script appears, is locked, and is also a program code.

In this embodiment, the integrity judgment refers to whether the first sub-script can be used as a single jacquard entity, and if so, the first sub-script is considered to be complete, otherwise, the first sub-script is considered to be incomplete.

In this embodiment, the second sub-script is similar to the first sub-script but better than the first sub-script, which is mainly used for facilitating reasonable replacement of a script at a position which cannot be optimized and ensuring the reliability of the script, and the script optimization database includes the script to be optimized and the script which can be replaced by matching the script to be optimized, so that the second sub-script matched with the first sub-script can be obtained.

In this embodiment, the first extension refers to performing left-right extension on the basis of the original 1 to obtain 0010, and then the left-side script identifier is related to the script corresponding to the left 00 position of 1, and the right-side script identifier is related to the script corresponding to the right 0 position of 1, so that the position extension of the first sub-script in the script to be optimized is realized, that is, the second extension is performed to obtain the second extension script, and further, the script at the first extension position on the unqualified script is completely replaced.

In this embodiment, when the unqualified script is 0001000100100, where all the positions where 1 appears are the positions that cannot be optimized, and there are multiple positions, the position attribute (based on the current position in the unqualified script), the script attribute (based on the code type and the meaning represented by the code), and the array { [ array 1] [ array 2]. That [ array n ] } of each position that cannot be optimized are obtained.

In this embodiment, the array { [ array 1] [ array 2]. [ array n ] } is labeled with:

array { array 1: [ color 1 color 01] array 2: [ color 2 color 01]. Array n-1 [ color 1 color 01] array n: [ color 2 color 03] }

Where colors 1,2, etc. are labels for the location attributes, colors 01, 03, etc. are labels for the script attributes, and the same label color is used when similar.

In this embodiment, the first array may be: array 1: [ color 1 color 01], array n-1: [ color 1 color 01]

The first array may be: array 2: [ color 2 color 01]

The first array may be: an array n: [ color 2 color 03]

The above-mentioned results are obtained by differentiating according to colors, and all can be regarded as the first array of the same labeling result.

In this embodiment, the array weight is a maximum weight value in all the first arrays corresponding to the same labeling result, and the maximum weight value is regarded as the corresponding array weight, so as to obtain an adjustment difficulty of the current same labeling result according to the array weight and the historical adjustment difficulty of the corresponding color, where the greater the array weight is, the greater the corresponding historical adjustment difficulty is, and the greater the corresponding current adjustment difficulty is. If the weight of the array is more than 0.5, the current adjustment difficulty is more than the historical adjustment difficulty, and if the weight of the array is not less than 0.5, the current adjustment difficulty is equal to the historical adjustment difficulty.

In this embodiment, the preset difficulty is preset, and the value is generally 0.6.

In this embodiment, the synchronous replacement refers to simultaneous replacement of codes of positions with the same labeling result, where the adjustment difficulty is smaller than the preset difficulty, and the script to be replaced refers to a parameter obtained by the preset optimization database, mainly related to the position attribute and the script attribute, and needed to be optimized for the unqualified parameter, so that the script to be replaced can be obtained, and effective replacement of the unqualified script is achieved.

In this embodiment, the position corresponding to the unqualified script: 00100100, wherein the two 1 appearing positions are the script positions to be replaced, if the first 1 appearing position is the position which cannot be optimized and is adjusted by the adjusting difficulty, the new position is inserted into the first 1 appearing left position, the script which needs to be adjusted to the first 1 appearing position is added, namely the script to be executed is to be obtained, the script is obtained from the preset optimization database, the script is adjusted mainly in different modes, the inserted script is adopted, the state is set, and the unqualified script is conveniently and reasonably adjusted.

In this embodiment, the synchronous replacement result refers to a replacement result with a difficulty smaller than a position corresponding to the preset difficulty, and the new position setting result refers to a result of performing script insertion and script state setting on a position corresponding to the preset difficulty with a difficulty greater than or equal to the preset difficulty.

The beneficial effects of the above technical scheme are: the method comprises the steps of optimizing unqualified scripts through an acquired script to be optimized, and realizing complete adjustment of the unqualified scripts through an optimization result, wherein the script to be optimized is added when full optimization is performed to obtain a qualified assembly, adjusting the unqualified scripts separately in different modes through locking of the position which is not optimized and determining the number of the positions when the position is not optimized, when one position which is not optimized exists, script adjustment is realized by script replacement, and when a plurality of positions which are not optimized exist, an array is constructed, the result is analyzed with the mark, and the difficulty is compared, so that accurate classification adjustment is realized, reliability adjustment of the unqualified scripts is realized, and the application building efficiency is indirectly improved.

The invention provides a method for rapidly building geographic information data application, as shown in fig. 2, comprising the following steps:

step 1: acquiring first geographic information of a preset area, and preprocessing the first geographic information according to the unit attribute of each geographic unit in the preset area to obtain a geographic component representing each geographic unit;

step 2: analyzing the combination possibility of the geographic components to obtain a combination possibility set;

and step 3: acquiring a building request, analyzing the request, calling a first component from all geographic components, and building to obtain a first geographic application;

and 4, step 4: performing result matching on each possible combination set based on the analysis result, and reserving the corresponding geographic component when the matching result of the corresponding set is successfully responded;

and 5: when all reserved geographic components are matched with all first components one by one, the first geographic application is regarded as a built geographic application;

step 6: when all reserved geographic components are more than first components contained in the first geographic application, extracting redundant components, performing first optimization on the first geographic application, and regarding the first geographic application as a built geographic application;

and 7: and when all the reserved geographic components are less than the first components contained in the first geographic application, extracting the second components from all the first components, constructing an initial array of each second component, performing second optimization on the first geographic application, and regarding the first geographic application as a built geographic application.

The beneficial effects of the above technical scheme are: and matching the constructed possible combination set with the analysis result of the request to perform matching verification on the geographic application directly constructed according to the request, and optimizing the constructed application based on the matching verification results under different conditions, so that the adaptation degree of the application and the request is improved, and the construction efficiency is indirectly improved.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (9)

1. A system for rapidly building geographic information data application is characterized by comprising:

the device comprises a component acquisition module, a component selection module and a component selection module, wherein the component acquisition module is used for acquiring first geographic information of a preset area and preprocessing the first geographic information according to the unit attribute of each geographic unit in the preset area to obtain a geographic component representing each geographic unit;

the possibility analysis module is used for analyzing the combination possibility of the geographic components to obtain a combination possible set;

the application building module is used for obtaining a building request, analyzing the request, calling a first component from all the geographic components, and building to obtain a first geographic application;

the result matching module is used for matching the result of each possible combination set based on the analysis result, and when the matching results of the corresponding sets are successful, the corresponding geographic components are reserved;

the component matching module is used for considering the first geographic application as the built geographic application when all the reserved geographic components are matched with all the first components one by one;

the first optimization module is used for extracting redundant components, performing first optimization on the first geographic application and regarding the first geographic application as a built geographic application when all reserved geographic components are more than the first components contained in the first geographic application;

and the second optimization module is used for extracting the second components from all the first components and constructing an initial array of each second component when all the reserved geographic components are less than the first components contained in the first geographic application, and performing second optimization on the first geographic application to be regarded as the built geographic application.

2. The system for rapidly building geographic information data application according to claim 1, wherein the component acquisition module comprises:

the point component acquisition unit is used for acquiring a point layer structure of each coordinate position in the regional geographical map according to the first geographical information of the preset region, and setting a geographical attribute to each layer structure in the point layer structure to obtain a point component; the standard structure corresponding to each coordinate position is the same, and the geographic information of each coordinate position in the vertical direction is different;

the attribute acquisition unit is used for geographically dividing the preset area according to the area division diagram of the preset area and setting unit attributes to each geographic unit based on an area-geographic mapping table;

and the geographic component acquisition unit is used for distributing and acquiring all the point components contained in each geographic unit according to the position-relation database, and performing component processing on the point components contained in the same geographic unit by combining the unit attributes to acquire the geographic components representing the corresponding geographic units.

3. The system for rapidly building a geographic information data application according to claim 1, wherein the possibility analysis module comprises:

the label establishing unit is used for calling history establishing requirements, extracting a history component set corresponding to each history establishing requirement, determining the requirement weight of each history component in each history component set, and establishing a representative label, wherein the representative label comprises: history components, history building requirements and requirement weights;

and the set building unit is used for extracting the historical components based on all the representative tags and building a combined possible set of the corresponding geographic components.

4. The system for rapidly building a geographic information data application according to claim 1, wherein the second optimization module comprises:

an object acquisition unit configured to acquire a representative object set of each second component;

the array construction unit is used for constructing an initial array corresponding to the second component based on the object attribute of each representative object in the corresponding representative object set;

a fusion judging unit for judging whether all the initial arrays have fusion possibility;

where r1 represents the similarity value of all the initial arrays; n1 represents the total number of initial arrays present;

representing the component weight corresponding to the i1 st initial array;

representing the array representative value of the i1+1 st initial array;

representing an array representative value for the i1 st initial array;

when the similarity value is greater than or equal to a preset value and each array representative value is greater than the corresponding array preset value, judging that all initial arrays have fusion possibility, and regarding the first geographic application as a built geographic application;

otherwise, judging that all the initial arrays do not have the fusion possibility, and according to the judgment result

Screening all the second components for a third component that affects the likelihood of fusion, wherein,

represents a constant;

representing an array preset value corresponding to the ith 1 st initial array;

carrying out number random screening on the third component according to a random function, and removing the number of the random screening on the third component;

wherein rand represents a random function; r2 represents the number of random screenings; n3 represents satisfaction of the selection

The number of the third components of (a);

、

represents a constant, and

is less than

；

A number determining function representing a required screening component based on the similarity value r 1; []Represents a rounding symbol; wherein, the first and the second end of the pipe are connected with each other,

and

；

and performing second optimization on the first geographic application according to the removed residual assemblies, and regarding the first geographic application as the built geographic application.

5. The system for rapidly building a geographic information data application according to claim 1, wherein the application building module comprises:

the identification obtaining unit is used for obtaining the request structure of the construction request and obtaining the structure identification of each mapping substructure in the request structure according to a preset structure mapping table;

the component calling unit is used for acquiring a component identifier which has a matching relation with the structure identifier according to the identifier-corresponding relation and calling a first component from all the geographic components based on the component identifier;

and the assembly building unit is used for building all the called first assemblies based on an assembly building mechanism to obtain the first geographic application.

6. The system for rapidly building a geographic information data application according to claim 1, wherein the component matching module comprises:

the matching unit is used for respectively matching all reserved geographic components with the called first component;

the judging unit is used for judging whether the matching result is one-to-one complete matching;

if yes, all reserved geographic components are judged to be matched with all first components one by one.

7. The system for rapidly building a geographic information data application according to claim 1, wherein the first optimization module comprises:

the script dividing unit is used for extracting a first script of each redundant component and dividing a scene script and an application script in the first script;

the instance testing unit is used for carrying out first testing on the scene scripts in the same first script according to the first testing instance and carrying out second testing on the application scripts in the same first script according to the second testing instance;

the component qualification judging unit is used for acquiring a first test parameter and a second test parameter, transmitting the first test parameter and the second test parameter to the target building function and judging whether the script qualification standards are met;

if yes, judging that the corresponding redundant components are qualified;

if not, judging that the corresponding redundant assembly is unqualified;

the component adjusting unit is used for adjusting the unqualified components to obtain qualified components;

and the application optimization unit is used for carrying out first optimization on the first geographic application based on all qualified assemblies and regarding the first geographic application as the built geographic application.

8. The system for rapidly building a geographic information data application according to claim 7, wherein the component adjusting unit comprises:

the parameter extraction block is used for extracting unqualified parameters based on the target building function, determining the parameter type of the unqualified parameters and acquiring a script to be optimized matched with the unqualified parameters from a parameter-script database;

the occupation situation determining block is used for determining the scene occupation situation of the parameter type based on the first test parameter and the application occupation situation based on the second test parameter to extract unqualified scripts;

the script adding block is used for optimizing the unqualified script based on the script to be optimized, and if the optimization result is full optimization, adding the script to be optimized to the corresponding redundant component and regarding the script to be optimized as a qualified component;

the position locking block is used for locking the position which cannot be optimized in the unqualified script if the optimization result is not full optimization;

the script locking block is used for synchronously locking the first sub-script at the same position of the script to be optimized when only one position fails to be optimized exists;

the integrity judgment block is used for judging the integrity of the first sub-script, if the first sub-script is complete, a second sub-script matched with the first sub-script is called from a script optimization database, and the script at the position which cannot be optimized is replaced according to the second sub-script;

if the position is not complete, performing first expansion on the position which cannot be optimized, performing second expansion on the first sub-script according to the left-side script identification and the right-side script identification after the first expansion, and replacing the script of the first expansion position according to the second expansion script;

the array building block is used for respectively obtaining the position attribute and the script attribute of each position which cannot be optimized when a plurality of positions which cannot be optimized exist, and building an array, wherein the array comprises a plurality of arrays, and each array comprises the position attribute and the script attribute corresponding to the position which cannot be optimized;

the similar marking block is used for carrying out first similar marking on the position attribute and second similar marking on the script attribute on the array;

the difficulty determining block is used for extracting the first arrays of the same labeling result and determining the adjustment difficulty of the same labeling result according to the array weight of each first array;

the synchronous replacement block is used for synchronously replacing the same labeling result with the adjustment difficulty smaller than the preset difficulty according to the obtained matched script to be replaced;

the state setting block is used for inserting a new position into the left side of the position which cannot be optimized in the same labeling result and the adjustment difficulty of which is greater than or equal to the preset difficulty, adding a script to be executed in the new position, setting the script to be in a state to be executed, and meanwhile, setting the script of the position which cannot be optimized on the right side of the new position to be in a sleep state;

and the adjusting block is used for adjusting the unqualified assembly based on all synchronous replacement results and the new position setting result to obtain the qualified assembly.

9. A method for rapidly building geographic information data application is characterized by comprising the following steps:

step 1: acquiring first geographic information of a preset area, and preprocessing the first geographic information according to the unit attribute of each geographic unit in the preset area to obtain a geographic component representing each geographic unit;

step 2: analyzing the combination possibility of the geographic components to obtain a combination possible set;

and step 3: acquiring a building request, analyzing the request, calling a first component from all geographic components, and building to obtain a first geographic application;

and 4, step 4: performing result matching on each possible combination set based on the analysis result, and reserving the corresponding geographic component when the matching result of the corresponding set is successfully responded;

and 5: when all reserved geographic components are matched with all first components one by one, the first geographic application is regarded as a built geographic application;

step 6: when all reserved geographic components are more than first components contained in the first geographic application, extracting redundant components, performing first optimization on the first geographic application, and regarding the first geographic application as a built geographic application;

and 7: and when all the reserved geographic components are less than the first components contained in the first geographic application, extracting the second components from all the first components, constructing an initial array of each second component, performing second optimization on the first geographic application, and regarding the first geographic application as a built geographic application.

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