CN115469871A - Customizable equipment management and control interface design method and system - Google Patents

Abstract

The invention provides a customizable device management and control interface design method and system, which relate to the technical field of digital processing, and comprise the following steps: acquiring operating environment information and hardware configuration information of target equipment; the communication data input device is used for importing user function requirement information and user preference information, carrying out UI design and generating basic window interface data; and checking and commissioning are carried out through the hardware configuration information, a hardware checking result is obtained, if the hardware is in a normal operation state, basic window interface data are loaded to the target equipment, a basic window interface is determined, optimization is carried out by combining with user preference information, an equipment management and control window interface is generated, and the equipment management and control window interface is transmitted to a target equipment terminal. The technical problems that an equipment management and control interface cannot meet the requirements and preferences of an equipment administrator and cannot be customized and modified are solved, the equipment management and control window interface is flexibly customized according to the requirements and preferences of the equipment administrator, and the technical effect of freely customizing and optimizing the equipment management and control interface is achieved.

Description

Customizable equipment management and control interface design method and system

Technical Field

The invention relates to the technical field of digital processing, in particular to a customizable device management and control interface design method and system.

Background

The equipment management and control interface is a medium between people and equipment, an equipment administrator exchanges information with the equipment through the equipment management and control interface and enters the equipment management and control interface, the first step of operation is carried out through the equipment management and control system, for the design of the equipment management and control interface, the operation experience and the visual comfort level of a user are considered, the equipment management and control interface is an interface where the equipment administrator resides for a long time, at the present stage, the equipment management and control interface cannot be subjected to custom customized modification, the requirement of the equipment administrator on the equipment management and control interface is ignored in the design process of the equipment management and control interface, the usability and the friendliness of the equipment management and control system are reduced, and even the working efficiency of the equipment administrator is influenced.

The technical problems that the requirement and preference of an equipment administrator cannot be met and custom modification cannot be carried out exist in an equipment management and control interface in the prior art.

Disclosure of Invention

The method and the system for designing the customizable equipment management and control interface solve the technical problems that the equipment management and control interface cannot meet the requirements and preferences of an equipment administrator and cannot be customized and modified, flexibly customize an equipment management and control window interface according to the requirements and preferences of the equipment administrator, and achieve the technical effect of freely customizing and optimizing the equipment management and control interface.

In view of the foregoing problems, the present application provides a customizable device management and control interface design method and system.

In a first aspect of the present application, a customizable device management and control interface design method is provided, where the method is applied to a device management and control interface design system, and the method includes: acquiring running environment information of target equipment, wherein the running environment information comprises operating environment information and hardware configuration information; the communication data input device is used for importing user function demand information and user preference information; carrying out UI design through the operating environment information and the user function requirement information to generate basic window interface data; checking and commissioning are carried out according to the hardware configuration information, and a hardware checking result is obtained; judging whether the hardware checking result is in a normal operation state or not; if the hardware checking result is in a normal operation state, loading the basic window interface data to the target equipment, testing and debugging to determine a basic window interface; and optimizing the basic window interface through the user preference information, generating an equipment control window interface, and transmitting the equipment control window interface to a target equipment terminal.

In a second aspect of the present application, a customizable device management and control interface design system is provided, where the system includes: : the system comprises an environment information acquisition unit, a hardware configuration unit and a hardware configuration unit, wherein the environment information acquisition unit is used for acquiring running environment information of target equipment, and the running environment information comprises operation environment information and hardware configuration information; the information import unit is used for communicating the data input device and importing the user function demand information and the user preference information; the window design unit is used for carrying out UI design through the operating environment information and the user function requirement information to generate basic window interface data; the checking and commissioning unit is used for checking and commissioning through the hardware configuration information to obtain a hardware checking result; an operating state judging unit for judging whether the hardware checking result is in a normal operating state; the test debugging unit is used for loading the basic window interface data to the target equipment for test debugging and determining a basic window interface if the hardware checking result is in a normal operation state; and the interface optimization unit is used for optimizing the basic window interface through the user preference information, generating an equipment control window interface and transmitting the equipment control window interface to a target equipment terminal.

One or more technical solutions provided in the present application have at least the following technical effects or advantages:

the method comprises the steps of obtaining operating environment information and hardware configuration information of target equipment; the communication data input device is used for importing user function demand information and user preference information; carrying out UI design through the operating environment information and the user function requirement information to generate basic window interface data; and checking and commissioning are carried out through the hardware configuration information, a hardware checking result is obtained, if the hardware checking result is in a normal operation state, the basic window interface data is loaded to the target equipment, test debugging is carried out, a basic window interface is determined, optimization is carried out in combination with the user preference information, an equipment control window interface is generated, and the equipment control window interface is transmitted to a target equipment terminal. According to the method and the device, the device management and control window interface is flexibly customized according to the requirements and preferences of the device administrator, and the technical effect of freely customizing and optimizing the device management and control interface is achieved.

Drawings

FIG. 1 is a schematic flow chart illustrating a customizable device management and control interface design method according to the present application;

fig. 2 is a schematic flow diagram illustrating a process of obtaining a hardware inspection result according to the customizable device management and control interface design method of the present application;

fig. 3 is a schematic flowchart illustrating a process of generating a first device management and control window interface according to a customizable device management and control interface design method of the present application;

fig. 4 is a schematic structural diagram of a customizable device management and control interface design system according to the present application.

Description of reference numerals: the system comprises an environment information acquisition unit 11, an information import unit 12, a window design unit 13, an inspection and commissioning unit 14, an operation state judgment unit 15, a test debugging unit 16 and an interface optimization unit 17.

Detailed Description

The method and the system for designing the customizable equipment management and control interface solve the technical problems that the equipment management and control interface cannot meet the requirements and preferences of an equipment administrator and cannot be customized and modified, flexibly customize an equipment management and control window interface according to the requirements and preferences of the equipment administrator, and achieve the technical effect of freely customizing and optimizing the equipment management and control interface.

Example one

As shown in fig. 1, the present application provides a customizable device management and control interface design method, where the method is applied to a device management and control interface design system, and the method includes:

step S100: acquiring running environment information of target equipment, wherein the running environment information comprises operating environment information and hardware configuration information;

step S200: the communication data input device is used for importing user function demand information and user preference information;

step S300: carrying out UI design through the operating environment information and the user function requirement information to generate basic window interface data;

specifically, the target device is usually an intelligent mechanical device, and a device management and control interface of the target device may support a customized design, and specifically, the operating environment information is operating environment information of the device management and control interface of the target device, and the operating environment information includes operating environment information (software) and hardware configuration information (hardware);

specifically, a device management and control interface design system and a data input device of a target device end are communicated, user function demand information and user preference information are input, the user function demand information comprises interface element demand information, grouping and arranging demand and other related demand information, and the user preference information comprises interface main color, font size and other related information;

specifically, UI design (User Interface) is carried out through the operation environment information and the User function requirement information, window construction is carried out, and basic window Interface data are generated and comprise basic parameters of relevant window Interface construction processes such as window handles and sub-window handles;

and based on the operating environment information and the user function requirement information, UI design is carried out, basic window interface data are generated, and a basic framework is provided for follow-up window customized management.

Step S400: checking and commissioning are carried out according to the hardware configuration information, and a hardware checking result is obtained;

further, as shown in fig. 2, the hardware configuration information is used to perform checking and commissioning, and a hardware checking result is obtained, where the step S400 includes:

step S410: determining a hardware configuration index according to the hardware configuration information;

step S420: sequentially carrying out single variable all-stage debugging and inspection on the basis of the hardware configuration index to obtain a hardware all-stage inspection result;

step S430: judging whether the hardware full-stage check result has warning or errors;

step S440: if no warning or error occurs, performing test run through the hardware configuration information and a preset test run period to obtain a hardware test run result;

step S450: and acquiring a hardware inspection result according to the hardware full-stage inspection result and the hardware commissioning result.

Specifically, before basic window interface data is loaded to target equipment, the target equipment needs to be checked and run in a commissioning mode, the hardware is comprehensively detected by combining the hardware configuration information, the state of the target equipment is detected in a running mode, and the state of the equipment meets the design requirement of an equipment management and control interface.

More specifically, index extraction is performed through the hardware configuration information, and a hardware configuration index is determined; based on the hardware configuration index, controlling to carry out single variable full-stage debugging (the full stage is from the lower limit of the index parameter of the single variable to the upper limit of the index parameter), sequentially carrying out single variable full-stage debugging and checking, and obtaining a hardware full-stage checking result (the hardware full-stage checking result is normal or abnormal, no warning or error occurs, the hardware full-stage checking result is output to be normal, warning occurs, the hardware full-stage checking result can be output to be normal, and error occurs, the hardware full-stage checking result is output to be abnormal); judging whether the hardware full-stage check result has warning or errors; if no warning or error occurs, the preset trial run period is a preset parameter index, and after the preset trial run period is in trial run through the hardware configuration information, a hardware trial run result is obtained, wherein the hardware trial run result (the hardware trial run result is normal or abnormal, no warning or error occurs, namely the hardware trial run result is output to be normal; a warning occurs, namely the hardware trial run result can be output to be normal; an error occurs, namely the hardware trial run result is output to be abnormal); and combining the hardware full-stage inspection result and the hardware test operation result, determining the hardware inspection result, performing full-stage inspection, setting fixed period time for test operation, performing equipment state detection in all aspects, and providing support for ensuring the stability of the hardware inspection result.

Further, a hardware full-phase checking result is obtained, and the step S420 includes:

step S421: constructing a hardware detection database;

step S422: generating a hardware detection model through the hardware detection database;

step S423: inputting parameter information corresponding to the hardware configuration index through the hardware detection model, checking and judging, and acquiring a warning detection result and an error detection result;

step S424: and acquiring a hardware full-stage inspection result according to the warning detection result and the error detection result.

Further, a hardware detection database is constructed, and the step S421 includes:

step S421-1: acquiring a historical index parameter information set of the equipment management and control interface design system through the hardware configuration index;

step S421-2: acquiring a historical operation and maintenance index parameter information set;

step S421-3: and constructing a hardware detection database through the historical index parameter information set and the historical operation and maintenance index parameter information set.

Specifically, the hardware configuration index is set as a mark retriever, and the historical data of the device management and control interface design system is retrieved to obtain a historical index parameter information set of the device management and control interface design system, where the historical index parameter information set is a specific parameter index of historical state information (for example, a graphics card in hardware, and the corresponding hardware configuration index may be a maximum resolution, a color depth, and a refresh frequency, and the historical state information is a display resolution, a display color depth, and a page refresh frequency of a historical state) corresponding to each hardware configuration index, and needs to be positioned and determined by combining with actual parameter information; acquiring a historical operation and maintenance index parameter information set through a historical operation and maintenance record, wherein the historical operation and maintenance index parameter information set comprises a plurality of parameter subsets, and the parameter subsets of the historical operation and maintenance index parameter information set are alarms or errors and corresponding operation, maintenance and maintenance troubleshooting schemes; and data merging and sorting are carried out through the historical index parameter information set and the historical operation and maintenance index parameter information set and the corresponding relation of data time, a hardware detection database is generated, and an effective data basis is provided for subsequent data analysis.

Specifically, a hardware detection database is constructed; establishing a hardware detection expert system by taking the hardware detection database as a knowledge base, and determining a hardware detection model based on input data and output data of the hardware detection expert system; inputting parameter information corresponding to the hardware configuration index into a hardware detection model based on the hardware detection model, checking and judging, and obtaining the output of the hardware detection model, wherein the output of the hardware detection model is a warning detection result and/or an error detection result; and combining a plurality of groups of the warning detection results and the error detection results, determining hardware full-stage detection results (namely a warning detection result set and an error detection result set), determining a hardware detection model, providing support for rapidly performing warning full-stage marking and error full-stage marking, and providing a model basis for subsequent data processing.

The input and output of the hardware detection expert system are taken as training data, a BP network model is taken as a model base, the input data of the hardware detection expert system is taken as the input of the model, the output data of the hardware detection expert system is taken as supervision data, supervision training is carried out, after the output of the model tends to be stable, an error comparison is carried out by combining a preset model error threshold value (the preset model error threshold value is a preset parameter index), and after the output of the model meets the limit of the preset model error threshold value, the hardware detection model is determined.

Step S500: judging whether the hardware checking result is in a normal operation state or not;

step S600: if the hardware checking result is in a normal operation state, loading the basic window interface data to the target equipment, testing and debugging to determine a basic window interface;

step S700: and optimizing the basic window interface through the user preference information, generating an equipment control window interface, and transmitting the equipment control window interface to a target equipment terminal.

Specifically, image information in the running process of target equipment is collected through image collection equipment, the image information is identified, the use description of the target equipment comprises each running state of the target equipment, the running state of the target equipment is determined through comparing each running state of the target equipment with the image information, and whether the running state of the target equipment corresponding to the hardware inspection result is in a normal running state or not is judged; if the hardware checking result is in a normal operation state, loading the basic window interface data to the target equipment through communication connection between an equipment management and control interface design system and the target equipment, testing and debugging after loading is finished, verifying the data loading condition (avoiding that a user function part is available or a user function is unavailable due to partial data loading), and determining a basic window interface; and performing interface setting optimization on the basic window interface through the user preference information, adjusting interface parameter information (interface color adjustment, font color adjustment and font size adjustment), determining an equipment control window interface after the adjustment is completed, synchronously transmitting the equipment control window interface to a target equipment terminal, and realizing flexible customization of the target equipment control interface under the condition of ensuring that functions are available.

Further, as shown in fig. 3, after optimizing the basic window interface through the user preference information and generating an equipment management and control window interface, the step S700 further includes:

step S710: acquiring a customized adding instruction;

step S720: adding the first user preference information to an interface design end through the customized adding instruction;

step S730: and optimizing the basic window interface through the first user preference information to generate a first equipment management and control window interface.

Further, a customized adding instruction is obtained, and the step S710 includes:

step S711: acquiring a user customized modification request through a target equipment terminal;

step S712: transmitting the user customized modification request to an interface design end for feasibility verification;

step S713: if the feasibility verification is passed, the interface design end sends out a modification acceptance instruction;

step S714: and acquiring a customized adding instruction through the modification receiving instruction and the user customized modification request.

Further, the embodiment of the present application further includes:

step S715: adding the user preference information and the first user preference information to a request additional storage unit of the user customization modification request;

step S716: and after the addition is finished, transmitting the user customized modification request to an interface design end.

Specifically, after a user uses the device management and control window interface to perform device management and control, the interface color and color distribution, font size, and interface layout corresponding to the user preference information may change, and based on the target device, the user sends a user customized modification request; adding the user preference information and the first user preference information to a request additional storage unit (the request additional storage unit may be a memory or a related information storage device) of the user customization modification request; after the addition is completed, transmitting the user customized modification request to an interface design end, and performing feasibility verification through a UI design professional of the interface design end; if the feasibility verification is passed, the UI design professional sends a modification acceptance instruction through the interface design end; and acquiring a customized adding instruction after the double verification of the equipment management and control interface design system is passed through the modification receiving instruction and the user customized modification request, so that the customized adding can be implemented, free customized optimization of the equipment management and control interface is realized, and support is provided for the customized optimization of the equipment management and control interface at any time.

Specifically, a customized adding instruction is obtained, first user preference information is added to an interface design end, the first user preference information is compared with the user preference information, an optimization scheme is determined, illustratively, the font size corresponding to the user preference information is four, the font size corresponding to the first user preference information is two, the corresponding optimization scheme is to adjust the font size to two, the example is to understand the scheme, and the actual requirement is to correspondingly adjust the specific parameter information; and optimizing the basic window interface through a corresponding optimization scheme based on the first user preference information to generate a first equipment control window interface and implement the updating of the equipment control window interface.

In summary, the method and system for designing the customizable device management and control interface provided by the present application have the following technical effects:

the method comprises the steps of obtaining operating environment information and hardware configuration information of target equipment; the communication data input device is used for importing user function requirement information and user preference information, carrying out UI design and generating basic window interface data; the method and the system achieve the technical effect of flexibly customizing the equipment management and control interface aiming at the requirements and preferences of an equipment manager and realize free customization and optimization of the equipment management and control interface.

As the hardware configuration indexes are determined through the hardware configuration information, single variable full-stage debugging and inspection are sequentially carried out, and a hardware full-stage inspection result is obtained; if the hardware full-stage check result has no warning or error, performing test run through hardware configuration information and a preset test run period to obtain a hardware test run result; the hardware inspection result is obtained by combining the hardware full-stage inspection result, the full-stage inspection is carried out, the fixed period time is set for trial operation, the self state of the equipment is ensured to meet the design requirement of an equipment management and control interface, the equipment state is detected in all aspects, and support is provided for ensuring the stability of the hardware inspection result.

Due to the fact that the customized adding instruction is obtained, the first user preference information is added through the first user preference information, the basic window interface is optimized, the first equipment management and control window interface is generated, free customized optimization of the equipment management and control interface is achieved while the fact that customized adding can be carried out is guaranteed, support is provided for customized optimization of the equipment management and control interface at any time, and updating of the equipment management and control interface is achieved.

Example two

Based on the same inventive concept as the customizable device management and control interface design method in the foregoing embodiment, as shown in fig. 4, the present application provides a customizable device management and control interface design system, wherein the system includes:

an environment information obtaining unit 11, where the environment information obtaining unit 11 is configured to obtain operation environment information of a target device, where the operation environment information includes operation environment information and hardware configuration information;

the information importing unit 12 is used for communicating the data input device and importing the user function requirement information and the user preference information;

the window design unit 13 is configured to perform UI design through the operating environment information and the user function requirement information to generate basic window interface data;

the checking and commissioning unit 14, the checking and commissioning unit 14 is configured to perform checking and commissioning according to the hardware configuration information, and obtain a hardware checking result;

an operating state determination unit 15, wherein the operating state determination unit 15 is used for determining whether the hardware checking result is in a normal operating state;

the test debugging unit 16 is configured to load the basic window interface data to the device management and control interface design system for test debugging if the hardware inspection result is in a normal operation state, and determine a basic window interface;

and the interface optimization unit 17 is configured to optimize the basic window interface through the user preference information, generate an equipment management and control window interface, and transmit the equipment management and control window interface to a target equipment terminal.

Further, the system comprises:

a configuration index determining unit, configured to determine a hardware configuration index according to the hardware configuration information;

the all-stage debugging and checking unit is used for sequentially carrying out single-variable all-stage debugging and checking on the basis of the hardware configuration index to obtain a hardware all-stage checking result;

the warning or error judgment unit is used for judging whether the hardware full-stage check result has warning or errors;

the test run unit is used for carrying out test run through the hardware configuration information and a preset test run period if no warning or error occurs, and acquiring a hardware test run result;

and the result acquisition unit is used for acquiring a hardware inspection result through the hardware full-stage inspection result and the hardware commissioning result.

Further, the system comprises:

the hardware detection system comprises a database construction unit, a hardware detection unit and a hardware detection unit, wherein the database construction unit is used for constructing a hardware detection database;

the detection model generation unit is used for generating a hardware detection model through the hardware detection database;

the checking and judging unit is used for inputting the parameter information corresponding to the hardware configuration index through the hardware detection model, checking and judging, and acquiring a warning detection result and an error detection result;

and the checking result acquisition unit is used for acquiring a hardware full-stage checking result according to the warning detection result and the error detection result.

Further, the system comprises:

a historical information acquisition unit, configured to acquire a historical index parameter information set of the equipment management and control interface design system through the hardware configuration index;

the operation and maintenance parameter acquisition unit is used for acquiring a historical operation and maintenance index parameter information set;

and the detection database construction unit is used for constructing a hardware detection database through the historical index parameter information set and the historical operation and maintenance index parameter information set.

Further, the system comprises:

the instruction acquisition unit is used for acquiring a customized adding instruction;

the information adding unit is used for adding the first user preference information to an interface design end through the customized adding instruction;

and the interface optimization unit is used for optimizing the basic window interface through the first user preference information to generate a first equipment management and control window interface.

Further, the system comprises:

a modification request acquisition unit, configured to acquire a user-customized modification request through a target device end;

the feasibility verification unit is used for transmitting the user customization modification request to an interface design end for feasibility verification;

the system comprises a modification receiving instruction sending unit, a verification unit and an interface design end, wherein the modification receiving instruction sending unit is used for sending a modification receiving instruction if the feasibility verification is passed;

and the adding instruction acquisition unit is used for acquiring a customized adding instruction through the modification receiving instruction and the user customized modification request.

Further, the system comprises:

a preference information adding unit, configured to add the user preference information and first user preference information to a request additional storage unit of the user customization modification request;

and the request transmission unit is used for transmitting the user customized modification request to an interface design end after the addition is finished.

The specification and drawings are merely exemplary of the application and various modifications and combinations can be made thereto without departing from the spirit and scope of the application. Such modifications and variations of the present application are within the scope of the claims of the present application and their equivalents, and the present application is intended to include such modifications and variations.

Claims (8)

1. A customizable equipment management and control interface design method is applied to an equipment management and control interface design system and comprises the following steps:

acquiring running environment information of target equipment, wherein the running environment information comprises operating environment information and hardware configuration information;

the communication data input device is used for importing user function demand information and user preference information;

carrying out UI design through the operating environment information and the user function requirement information to generate basic window interface data;

checking and commissioning are carried out according to the hardware configuration information, and a hardware checking result is obtained;

judging whether the hardware checking result is in a normal operation state or not;

if the hardware checking result is in a normal operation state, loading the basic window interface data to the target equipment, testing and debugging the basic window interface data, and determining a basic window interface;

and optimizing the basic window interface through the user preference information, generating an equipment control window interface, and transmitting the equipment control window interface to a target equipment terminal.

2. The method of claim 1, wherein the hardware configuration information is used for checking and commissioning to obtain a hardware checking result, and the method comprises:

determining a hardware configuration index according to the hardware configuration information;

sequentially carrying out single variable all-stage debugging and inspection on the basis of the hardware configuration index to obtain a hardware all-stage inspection result;

judging whether the hardware full-stage check result has warning or errors;

if no warning or error occurs, performing test operation according to the hardware configuration information and a preset test operation period to obtain a hardware test operation result;

and acquiring a hardware inspection result according to the hardware full-stage inspection result and the hardware commissioning result.

3. The method of claim 2, wherein hardware full-phase inspection results are obtained, the method comprising:

constructing a hardware detection database;

generating a hardware detection model through the hardware detection database;

inputting parameter information corresponding to the hardware configuration index through the hardware detection model, checking and judging, and acquiring a warning detection result and an error detection result;

and acquiring a hardware full-stage inspection result according to the warning detection result and the error detection result.

4. The method of claim 3, wherein a hardware detection database is constructed, the method comprising:

acquiring a historical index parameter information set of the equipment management and control interface design system through the hardware configuration index;

acquiring a historical operation and maintenance index parameter information set;

and constructing a hardware detection database through the historical index parameter information set and the historical operation and maintenance index parameter information set.

5. The method of claim 1, wherein the basic window interface is optimized according to the user preference information, and after a device management and control window interface is generated, the method further comprises:

acquiring a customized adding instruction;

adding the first user preference information to an interface design end through the customized adding instruction;

and optimizing the basic window interface through the first user preference information to generate a first equipment management and control window interface.

6. The method of claim 5, wherein a customized add instruction is obtained, the method comprising:

acquiring a user customized modification request through a target equipment terminal;

transmitting the user customized modification request to an interface design end for feasibility verification;

if the feasibility verification is passed, the interface design end sends out a modification acceptance instruction;

and acquiring a customized adding instruction through the modification receiving instruction and the user customized modification request.

7. The method of claim 6, wherein the method further comprises:

adding the user preference information and the first user preference information to a request additional storage unit of the user customization modification request;

and after the addition is finished, transmitting the user customized modification request to an interface design end.

8. A customizable equipment management and control interface design system, the system comprising:

the system comprises an environment information acquisition unit, a hardware configuration unit and a hardware configuration unit, wherein the environment information acquisition unit is used for acquiring running environment information of target equipment, and the running environment information comprises operation environment information and hardware configuration information;

the information import unit is used for communicating the data input device and importing the user function demand information and the user preference information;

the window design unit is used for carrying out UI design through the operating environment information and the user function requirement information to generate basic window interface data;

the checking and commissioning unit is used for checking and commissioning through the hardware configuration information to obtain a hardware checking result;

an operating state judging unit for judging whether the hardware checking result is in a normal operating state;

the test debugging unit is used for loading the basic window interface data to the target equipment for test debugging and determining a basic window interface if the hardware checking result is in a normal operation state;

and the interface optimization unit is used for optimizing the basic window interface through the user preference information, generating an equipment control window interface and transmitting the equipment control window interface to a target equipment terminal.

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