CN112667762A - Method for quickly constructing GIS (geographic information System) through zero programming - Google Patents

Abstract

The invention relates to the technical field of system platform construction, and discloses a method for quickly constructing a GIS system by zero programming, which comprises the following steps: s1, initializing a functional component warehouse; s2, associating a GIS database; s3, calling a functional component: the functional components have visual deployment and distribution functions, and a functional area is formed by dragging the functional components; s4, building a functional area; s5, recognizing user emotion: judging whether the user has a nervous or angry emotion; s6, recognizing user voice data: collecting and analyzing the voice data information content, extracting keywords and transmitting the keywords to a functional component warehouse, and matching the keywords with the names of the functional components in the functional component warehouse; and S7, user feedback. The invention simplifies the construction of the GIS system by the user, and reduces the difficulty of constructing the GIS system and the use threshold of the user. The invention aims at the problems that the existing method for constructing the GIS system needs a user to be familiar with the operation for constructing the GIS system during construction, and the threshold of the user for constructing the GIS system is higher.

Description

Method for quickly constructing GIS (geographic information System) through zero programming

Technical Field

The invention relates to the technical field of system platform construction, in particular to a method for quickly constructing a GIS system by zero programming.

Background

A GIS system, i.e., a geographic information system, is an integration that organizes computer hardware, software, geographic data, and system administrators into a form that efficiently acquires, stores, updates, operates, analyzes, and displays geographic information of any form.

The traditional GIS development modes mainly comprise two modes: the development of the memory structured program and the development of the object-oriented componentization are that most systems use the object-oriented component technology at present, and the traditional object-oriented componentization development technology has high difficulty and high requirements on computer programmers. Aiming at the problem that the traditional GIS development mode is difficult to develop, the prior art provides a method for constructing a GIS system by zero programming.

The zero programming is that an enterprise does not need to find a programmer to write codes, development amount is simplified, and a large data visualization screen can be realized only by a drag-and-drop mode, so that the programmer is freed from heavy coding work, and therefore only the requirements of customers are concerned, and the customers are better served. The construction efficiency of the GIS system is improved, and the cost and risk of constructing the GIS system are reduced.

The user oriented to the mode of constructing the GIS system by zero programming is a developer of the zero programming development foundation, and the existing method for constructing the GIS system by zero programming is established on the basis of the powerful functional components of the bottom functional library of the system and comprises the following steps: the programmer develops the component functions to form a functional component warehouse, a GIS data warehouse and a visual operation interface, and a user drags and drops the functional components in the visual operation interface based on the functional component warehouse, the GIS data warehouse and the visual operation interface, so that the user interface can be quickly established. For a user, drag and drop are carried out on the functional components in the visual operation interface on the user interface, and the GIS system can be quickly built.

The technical problems of the existing zero programming GIS development mode construction are as follows:

a user (namely, a zero programming developer) needs to be familiar with a visual operation interface in advance, and can build a GIS system efficiently and quickly by being familiar with a functional component warehouse, a GIS data warehouse and the like, otherwise, the building efficiency is low, and the user has high operation proficiency requirement and a use threshold.

Disclosure of Invention

The invention provides a method for quickly constructing a GIS system in a zero programming way, aiming at the problems that a user is required to be familiar with the operation for constructing the GIS system and the threshold of the user for constructing the GIS system is high in the construction of the existing method for constructing the GIS system.

In order to solve the technical problem, the present application provides the following technical solutions:

a method for zero programming rapid construction of a GIS system comprises the following steps:

s1, initializing a functional component warehouse: loading the functional components to form a functional component warehouse;

s2, associating with a GIS database: the functional component is associated with the GIS database, and can call data in the GIS database according to the corresponding function;

the method is characterized by further comprising the following steps:

s3, calling a functional component: calling the required functional components in the functional component warehouse;

s4, building a functional area: the functional components have visual deployment and distribution functions, and a functional area can be formed by dragging the functional components;

s5, recognizing user emotion: acquiring facial image data of a user while calling a functional component, analyzing micro-expression characteristics in a facial image according to the facial image data, identifying the meaning of the micro-expression characteristics, judging whether the user has a nervous or angry emotion, and acquiring voice data of the user after judging that the user has a nervous or angry emotion;

s6, recognizing user voice data: after voice data of a user is collected, analyzing the information content of the voice data according to the collected voice data, extracting a keyword, transmitting the keyword to a functional component warehouse, matching the keyword with the name of a functional component in the functional component warehouse, and recommending the successfully matched functional component to the user in an instruction mode;

s7, user feedback: and judging whether the user adopts the recommended instruction or not according to whether the recommended functional component enters the functional area or not, collecting feedback of the user to the recommended instruction after the user adopts the recommended instruction to form a feedback record, and realizing self-learning according to the feedback record.

Has the advantages that: the method comprises the steps of selecting required functional components by calling the functional components in a functional component warehouse, and dragging the required functional components to form a functional area formed by integrating the functional components, wherein in the process of calling the functional components, depending on the familiarity of a user with the functional component warehouse, the method carries out facial emotion recognition of the user when calling the functional components, when the user is not familiar with an operation interface and cannot accurately find the required functional components, the user generally has variation of micro expressions, and irritability and anger emotions, after judging that the user has the irritability and anger emotions, voice collection is started and the voice recognition of the user is carried out, the difficulty of constructing a GIS system is reduced better, the collected voice content of the user is analyzed, keywords are extracted, and the keywords are matched with the names of the functional components prestored in the functional component warehouse, and searching the functional component corresponding to the keyword in a functional component warehouse, recommending the functional component to the user, collecting user feedback on the effectiveness of a recommendation instruction to form a feedback record, and realizing self-learning according to the feedback record, so that the user can construct a GIS system more simply and intelligently, and the difficulty of constructing the GIS system and the use threshold of the user are reduced.

According to the method and the device, the facial emotion recognition and the voice recognition of the user are added, the voice collection is started according to the facial emotion when the user builds the GIS system, the collected voice data is recognized, the recommendation of the functional component is carried out according to the recognition, the difficulty of building the GIS system is better reduced, the efficiency of building the GIS system when the user is not familiar with the operation interface and cannot accurately find the required functional component is effectively improved, the user can build the GIS system more simply and intelligently, and the difficulty of building the GIS system and the use threshold of the user are reduced.

Further, the S4 further includes S401, building a custom function area: the method comprises the steps of collecting functional components with high use frequency of a user in daily use in advance, and configuring the functional components into a user-defined functional area.

Has the advantages that: the method comprises the steps that a set of common functional components of a user is formed in advance, a user-defined functional area is formed, the use habits and application scenes of different users are different, the common functional components are also different, the efficiency of constructing the GIS system by the same user can be reduced by the traditional functional component set mode, the time of searching the functional components by the user in the construction is reduced through the construction of the specific user-defined functional area, and the construction efficiency is further improved.

Further, the S4 further includes 402, a frequency detecting step: and monitoring the frequency of the user for inputting and deleting the instruction while building the functional area, and recommending the user-defined functional area for the user when the frequency of the user for repeatedly inputting and deleting the instruction reaches a preset value.

Has the advantages that: the user individuals have differences and different operation proficiency, and partially skilled users have common functional components, but have enough proficiency and do not need to recommend the user-defined functional regions, so that the monitoring is carried out when the user builds the functional regions, when frequent keying-in instructions and deleting instructions occur and the frequency reaches a preset value, the user is usually not familiar enough, more operation errors are caused or the user frequently inputs and deletes the instructions with fussy emotion, and at the moment, the user is recommended to the user-defined functional regions, so that the efficiency of the user is improved, and the intelligence of constructing the GIS is also enhanced.

Further, the step S4 includes the step S403 of recommending an array: when the functional area is built, the arrangement mode of a user when the functional components are dragged and dropped is monitored, whether the functional components are repeatedly arranged exists or not is monitored, and when the functional components are repeatedly arranged by the user, the array function is recommended to the user.

Has the advantages that: when a user repeatedly arranges or drags and drops a certain functional component, the repeated arrangement operation of the user is detected, the array function is recommended to the user, the time wasted by the repeated operation of the user in arrangement is reduced, and the efficiency of constructing the GIS system is improved.

Further, the S4 further includes: an automatic alignment step, wherein any step of visually deploying and allocating the functional components in S4 may perform the automatic alignment step: when the user drags and drops the functional components to arrange, the functional components are automatically aligned when adjacent functional components are approached.

Has the advantages that: generally, the operation interface is more attractive and tidy due to alignment, when a user drags and drops a functional component, the user intends to align the adjacent functional component when the functional component is close to the adjacent functional component, and the automatic alignment is performed at the moment, so that the time wasted in continuous adjustment on position arrangement is reduced.

Further, the S4 further includes a step of retrieving the functional components, where any step in the step of visually deploying and allocating the functional components in S4 is performed before or after: the method comprises a retrieval frame, wherein the retrieval frame is associated with all functional components, when a user searches for the functional components, the name of the functional components is input into the retrieval frame for searching, and the functional components are popped up below the retrieval frame.

Has the advantages that: when the user is not skilled enough and cannot accurately find the required functional component, the search frame is provided, and the user searches the functional component through the search frame, so that the time consumed for searching the functional component when the operation is unfamiliar can be reduced, and the use experience of the user is improved.

Further, the S4 further includes an association retrieval step, which is performed when the retrieval function component step is performed: when a user inputs the name of the functional component in the search box, a plurality of characters of the name of the functional component are input, the search box automatically associates, and the functional component required by the user is popped up below the search box.

Has the advantages that: when a user searches a functional component in a search box, generally because the user is not familiar with the functional component, the user may have a fuzzy impression on the name of the functional component, and cannot input an accurate and complete name of the functional component.

Further, the S4 further includes a step of customizing a shortcut key: and sequencing the use frequency of the functional components used by the user from high to low, and setting a self-defined shortcut key for the functional components used at high frequency by the user according to the sequencing.

Has the advantages that: aiming at a user who often constructs a GIS system, the requirements for different functional components are embodied on the use frequency of the functional components when the user constructs the GIS system, and for some functional components used at high frequency, the user can set shortcut keys according to the requirements of the user, so that the speed of a skilled user when constructing the GIS system is improved.

Further, the S4 further includes an automatic saving step: automatic saving is performed at regular intervals in any step.

Has the advantages that: when the user carries out visual deployment and distribution of the functional components, automatic saving is carried out at fixed intervals, and content loss caused by the fact that the user forgets to save when a fault occurs is prevented.

Further, the S6 further includes S601, a strobe prompt: and recommending the successfully matched functional components to the user in an instruction mode, and simultaneously sending stroboflash at the positions of the functional components.

Has the advantages that: when the functional component is recommended to intelligence, adopt this functional component stroboscopic mode to remind the position of the required functional component of user, make the user can find required functional component sooner, this stroboscopic can deepen the user simultaneously to the impression of functional component position promotes user's proficiency.

Drawings

FIG. 1 is a flow chart of a method for fast constructing a GIS system by zero programming according to the present invention.

Detailed Description

The following is further detailed by way of specific embodiments:

in the first embodiment, as shown in fig. 1, the method for fast constructing a GIS system through zero programming in the present embodiment includes the following steps:

s1, initializing a functional component warehouse: loading the functional components to form a functional component warehouse;

s2, associating with a GIS database: the functional component is associated with the GIS database, and can call data in the GIS database according to the corresponding function;

s3, calling a functional component: calling the required functional components in the functional component warehouse;

s4, building a functional area: the functional components have visual deployment and distribution functions, and a functional area can be formed by dragging the functional components;

s401, building a user-defined function area: the method comprises the steps of collecting functional components with high use frequency of a user in daily use in advance, and configuring the functional components into a user-defined functional area.

The method comprises the steps that a set of common functional components of a user is formed in advance, a user-defined functional area is formed, the use habits and application scenes of different users are different, the common functional components are also different, the efficiency of constructing the GIS system by the same user can be reduced by the traditional functional component set mode, the time of searching the functional components by the user in the construction is reduced through the construction of the specific user-defined functional area, and the construction efficiency is further improved.

402. A frequency detection step: and monitoring the frequency of the user for inputting and deleting the instruction while building the functional area, and recommending the user-defined functional area for the user when the frequency of the user for repeatedly inputting and deleting the instruction reaches a preset value.

The frequency detection adopts the existing frequency detection software to detect the frequency of the input instruction and the deletion instruction of the user, the individual users have difference and different proficiency of operation, although some skilled users have common functional components, the proficiency of the users is enough, and the users do not need to recommend the user-defined functional area, so that the monitoring is carried out when the user builds the functional area, when frequent input instructions and deletion instructions occur and the frequency reaches a preset value, the users are usually not familiar enough, more operation errors or emotional irritability occurs and the deletion is frequently input, at the moment, the user is recommended to the user-defined functional area, the efficiency of the user is improved, and the intelligence of constructing the GIS system is also enhanced.

S403, an array recommending step: when the functional area is built, the arrangement mode of a user when the functional components are dragged and dropped is monitored, whether the functional components are repeatedly arranged exists or not is monitored, and when the functional components are repeatedly arranged by the user, an instruction is popped up to recommend the array function to the user.

When the user performs repeated arrangement drag and drop, the operation of repeatedly arranging the functional components by the user can be detected, the array function is recommended to the user, the time wasted by repeated operation of the user is reduced, and the efficiency of constructing the GIS system is improved.

S4 further includes: an automatic alignment step, wherein any step of visually deploying and allocating the functional components in S4 may perform the automatic alignment step: when the user drags and drops the functional components to arrange, the functional components are automatically aligned when adjacent functional components are approached.

Generally, the operation interface is more attractive and tidy due to alignment, when a user drags and drops a functional component, the user intends to align the adjacent functional component when the functional component is close to the adjacent functional component, and the automatic alignment is performed at the moment, so that the time wasted in continuous adjustment on position arrangement is reduced.

S4 further includes a retrieve function component step, which may be performed during or before any step in the visual deployment assignment of function components in S4: the method comprises a retrieval frame, wherein the retrieval frame is associated with all functional components, when a user searches for the functional components, the name of the functional components is input into the retrieval frame for searching, and the functional components are popped up below the retrieval frame.

When the user is not skilled enough and cannot accurately find the required functional component, the search frame is provided, and the user searches the functional component through the search frame, so that the time consumed for searching the functional component when the operation is unfamiliar can be reduced, and the use experience of the user is improved.

S4 further includes an association retrieval step, which is performed when the retrieval function component step is performed: when a user inputs the name of the functional component in the search box, a plurality of characters of the name of the functional component are input, the search box automatically associates, and the functional component required by the user is popped up below the search box.

When a user searches a functional component in a search box, generally because the user is not familiar with the functional component, the user may have a fuzzy impression on the name of the functional component, and cannot input an accurate and complete name of the functional component.

The S4 further comprises the step of customizing a shortcut key: and sequencing the use frequency of the functional components used by the user from high to low, and setting a self-defined shortcut key for the functional components used at high frequency by the user according to the sequencing.

Aiming at a user who often constructs a GIS system, the requirements for different functional components are embodied on the use frequency of the functional components when the user constructs the GIS system, and for some functional components used at high frequency, the user can set shortcut keys according to the requirements of the user, so that the speed of a skilled user when constructing the GIS system is improved.

S4 further includes an auto-save step: automatic saving is performed at regular intervals in any step.

S5, recognizing user emotion: the method comprises the steps of acquiring facial image data of a user while calling a functional component, analyzing micro-expression characteristics in a facial image according to the facial image data, identifying meanings of the micro-expression characteristics, judging whether the user has an anxiety or angry emotion, and acquiring voice data of the user after judging that the user has the anxiety or angry emotion.

In the embodiment, the spacious emotion recognition technology is adopted, and 20 micro-expression characteristic meanings such as 'lifting cheek', 'wrinkling nose', 'squeezing out dimple', 'tightening lips' can be automatically analyzed.

S6, recognizing user voice data: after voice data of a user is collected, analyzing information content of the voice data according to the collected voice data, extracting keywords, transmitting the keywords to a functional component warehouse, matching the keywords with names of functional components in the functional component warehouse, and recommending the successfully matched functional components to the user in an instruction mode.

S601, stroboscopic prompt: and recommending the successfully matched functional components to the user in an instruction mode, and simultaneously sending stroboflash at the positions of the functional components.

When the functional component is recommended to intelligence, adopt this functional component stroboscopic mode to remind the position of the required functional component of user, make the user can find required functional component sooner, this stroboscopic can deepen the user simultaneously to the impression of functional component position promotes user's proficiency.

S7, user feedback: and judging whether the user adopts the recommended instruction according to whether the recommended functional component enters the functional area, and collecting feedback of the user on the recommended instruction after the user adopts the recommended instruction.

The difficulty of constructing the GIS system is better reduced by adding facial emotion recognition and user voice recognition of a user, when the user is not familiar with an operation interface and cannot accurately find a required functional component, the change of micro expression generally occurs, the emotional states of anxiety and anger occur, after the fact that the emotional states of anxiety and anger occur to the user is judged, the collected voice content of the user is analyzed, keywords are extracted and matched with the names of the functional components prestored in the functional component warehouse, the functional components corresponding to the keywords are found in the functional component warehouse and recommended to the user, the feedback of the user is collected on the effectiveness of recommended instructions, the user can construct the GIS system more simply and intelligently, and the difficulty of constructing the GIS system and the use threshold of the user are reduced.

The foregoing is merely an example of the present invention, and common general knowledge in the field of known specific structures and characteristics is not described herein in any greater extent than that known in the art at the filing date or prior to the priority date of the application, so that those skilled in the art can now appreciate that all of the above-described techniques in this field and have the ability to apply routine experimentation before this date can be combined with one or more of the present teachings to complete and implement the present invention, and that certain typical known structures or known methods do not pose any impediments to the implementation of the present invention by those skilled in the art. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several changes and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims (10)

1. A method for zero programming rapid construction of a GIS system comprises the following steps:

s1, initializing a functional component warehouse: loading the functional components to form a functional component warehouse;

s2, associating with a GIS database: the functional component is associated with the GIS database, and can call data in the GIS database according to the corresponding function;

the method is characterized by further comprising the following steps:

s3, calling a functional component: calling the required functional components in the functional component warehouse;

s4, building a functional area: the functional components have visual deployment and distribution functions, and a functional area can be formed by dragging the functional components;

s5, recognizing user emotion: acquiring facial image data of a user while calling a functional component, analyzing micro-expression characteristics in a facial image according to the facial image data, identifying the meaning of the micro-expression characteristics, judging whether the user has a nervous or angry emotion, and acquiring voice data of the user after judging that the user has a nervous or angry emotion;

s6, recognizing user voice data: after voice data of a user is collected, analyzing the information content of the voice data according to the collected voice data, extracting a keyword, transmitting the keyword to a functional component warehouse, matching the keyword with the name of a functional component in the functional component warehouse, and recommending the successfully matched functional component to the user in an instruction mode;

s7, user feedback: and judging whether the user adopts the recommended instruction according to whether the recommended functional component enters the functional area, and collecting feedback of the user on the recommended instruction after the user adopts the recommended instruction.

2. The method for zero-programming rapid construction of the GIS system according to claim 1, wherein: the S4 further comprises S401 and a user-defined functional area is built: the method comprises the steps of collecting functional components with high use frequency of a user in daily use in advance, and configuring the functional components into a user-defined functional area.

3. The method for zero-programming rapid construction of the GIS system according to claim 2, characterized in that: the S4 further includes 402, a frequency detecting step: and monitoring the frequency of the user for inputting and deleting the instruction while building the functional area, and recommending the user-defined functional area for the user when the frequency of the user for repeatedly inputting and deleting the instruction reaches a preset value.

4. The method for zero-programming rapid construction of the GIS system according to claim 1, wherein: the S4 further includes S403, an array recommending step: when the functional area is built, the arrangement mode of a user when the functional components are dragged and dropped is monitored, whether the functional components are repeatedly arranged exists or not is monitored, and when the functional components are repeatedly arranged by the user, the array function is recommended to the user.

5. The method for zero-programming rapid construction of the GIS system according to claim 1, wherein: the S4 further includes: an automatic alignment step, wherein any step of visually deploying and allocating the functional components in S4 may perform the automatic alignment step: when the user drags and drops the functional components to arrange, the functional components are automatically aligned when adjacent functional components are approached.

6. The method for zero-programming rapid construction of the GIS system according to claim 1, wherein: the S4 further includes a step of retrieving the functional components, which may be performed during or before or after any step in the step of visually deploying and allocating the functional components in S4: the method comprises a retrieval frame, wherein the retrieval frame is associated with all functional components, when a user searches for the functional components, the name of the functional components is input into the retrieval frame for searching, and the functional components are popped up below the retrieval frame.

7. The method for zero-programming rapid construction of the GIS system according to claim 6, wherein: the S4 further includes an association retrieval step, which is performed when the retrieval function component step is performed: when a user inputs the name of the functional component in the search box, a plurality of characters of the name of the functional component are input, the search box automatically associates, and the functional component required by the user is popped up below the search box.

8. The method for zero-programming rapid construction of the GIS system according to claim 1, wherein: the step of S4 further comprises the step of customizing shortcut keys: and sequencing the use frequency of the functional components used by the user from high to low, and setting a self-defined shortcut key for the functional components used at high frequency by the user according to the sequencing.

9. The method for zero-programming rapid construction of the GIS system according to claim 1, wherein: the S4 further includes an auto-save step: automatic saving is performed at regular intervals in any step.

10. The method for zero-programming rapid construction of the GIS system according to claim 1, wherein: the S6 further includes S601, a strobe prompt: and recommending the successfully matched functional components to the user in an instruction mode, and simultaneously sending stroboflash at the positions of the functional components.

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