CN114996225A - Development method for user-defined visual combined instrument control - Google Patents

Abstract

The invention provides a development method of a user-defined visual combination instrument control, which is characterized in that the respective working logs of different instruments are obtained through an instrument control terminal, the working logs are analyzed and processed, corresponding fault related data of the instruments are obtained through screening, and the fault related data are converted into file data in a visual format; arranging and integrating file data to obtain a file data queue, and uploading the file data queue to a cloud database for identification marking; according to a triggering instruction of a user to a display terminal, obtaining the current instrument data viewing requirement of the user, calling a matched file data queue from a cloud database, and displaying the called file data queue on the display terminal; according to the method, the working log of each instrument is used as a basis, screening determination and cloud storage of the fault related data of the instrument are achieved, and the visual file data are displayed, so that the accuracy and the intuition of checking the related data of the instrument are improved.

Description

Development method for user-defined visual combined instrument control

Technical Field

The invention relates to the technical field of instrument display control, in particular to a development method of a custom visual instrument control.

Background

Large-scale equipment typically includes a variety of instruments, each for performing a corresponding function, to enable proper operation of the large-scale equipment. In order to ensure that the operating states of different instruments and meters in the large-scale equipment can be known in real time, corresponding controls are usually developed to monitor the different instruments and meters so as to obtain the operating state data of the instruments and meters, and then the operating state data is displayed on a display, so that a user can obtain the actual operating states of the instruments and meters in time. Because the large-scale equipment comprises a large number of instruments and meters, the existing display mode cannot effectively display related data according to actual needs, and therefore the accuracy and the intuitiveness of checking the running state data of the instruments and meters are reduced.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides a development method of a user-defined visual combined instrument control, which comprises the steps of obtaining respective working logs of different instruments through an instrument control terminal, analyzing and processing the working logs, screening to obtain corresponding fault related data of the instruments, and converting the fault related data into file data in a visual format; arranging and integrating file data to obtain a file data queue, and uploading the file data queue to a cloud database for identification marking; according to a triggering instruction of a user to a display terminal, obtaining the current instrument data viewing requirement of the user, calling a matched file data queue from a cloud database, and displaying the called file data queue on the display terminal; according to the method, the working log of each instrument is used as a basis, the screening determination and cloud storage of the relevant data of the instrument faults are realized, and the corresponding matched visual file data is called for display according to the user requirements, so that the accuracy and the intuition of the relevant data checking of the instrument are improved.

The invention provides a development method of a custom visual combined instrument control, which comprises the following steps:

step S1, establishing a communication link between an instrument control terminal and different instruments, and respectively sending a work information acquisition request to each instrument through the instrument control terminal; generating a corresponding instrument working log according to a feedback result of the instrument on the working information acquisition request;

step S2, analyzing and processing the instrument working log, and screening out corresponding fault related data from the instrument working log; carrying out format conversion processing on the fault related data to obtain file data with a visual format;

step S3, arranging and integrating the file data to obtain a corresponding file data queue, and uploading the file data queue to a cloud database; identifying and marking the uploaded file data queue;

step S4, acquiring a trigger instruction from a user to a display terminal, analyzing the trigger instruction, and determining the current instrument data viewing requirement of the user; and according to the instrument data viewing requirement, calling a matched file data queue from the cloud database, and displaying the called file data queue on the display terminal.

In an embodiment disclosed in the present application, in the step S1, constructing a communication link between the instrument control terminal and different instruments, and sending the work information obtaining request to each instrument through the instrument control terminal specifically includes:

the method comprises the steps that an instrument control terminal is in bidirectional wireless communication connection with each instrument, and after the instrument is started, the instrument sends a notification message to the instrument control terminal; and after the instrument receives the notification message, the instrument control terminal sends a work information acquisition request to the instrument.

In an embodiment disclosed in the present application, in step S1, generating a corresponding instrument work log according to a feedback result of the instrument with respect to the work information obtaining request specifically includes:

after the instrument receives the work information acquisition request, extracting a time range corresponding to the work information required to be acquired by the instrument control terminal from the work information acquisition request; and calling instrument working logs with matched time ranges from the cache space of the instrument according to the time ranges.

In an embodiment disclosed in the present application, in step S2, analyzing the instrument work log, and screening out corresponding fault-related data from the instrument work log specifically includes:

identifying, analyzing and processing each item of log data in the instrument and meter working logs, and judging whether the log data belong to fault operation data or not; if the log data belong to the log data, corresponding log data are reserved; if not, discarding the corresponding log data.

In an embodiment disclosed in the present application, in step S2, performing recognition analysis processing on each log data in the instrument and meter work log, and determining whether the log data belongs to fault operation data specifically includes:

firstly, judging whether each log data of the instrument working log contains a preset instrument operation related character or not; if yes, determining that the log data belong to instrument operation related data; if not, determining that the log data does not belong to instrument operation related data;

and then judging whether the instrument operation state representation value in the log data of the instrument operation related data exceeds a preset standard value range, if so, determining that the log data belongs to fault operation data, and if not, determining that the log data does not belong to the fault operation data.

In an embodiment disclosed in the present application, in step S2, performing format conversion processing on the failure-related data to obtain file data with a visualization format specifically includes:

and converting the fault related data into a text format or a picture format to obtain visual text file data or visual picture file data.

In an embodiment of the present disclosure, in step S3, the arranging and integrating the file data to obtain a corresponding file data queue, and uploading the file data queue to a cloud database specifically includes:

arranging and integrating all the file data according to the sequence of the creation time of all the file data from early to late to obtain corresponding file data queues; and then compressing and packaging the file data queue and uploading the file data queue to a cloud database.

In an embodiment disclosed in the present application, in step S3, the identifying and marking the uploaded file data queue specifically includes:

and adding the equipment identity information of the corresponding instrument to the uploaded file data queue, thereby realizing the identification mark of the file data queue.

In an embodiment disclosed in the present application, in step S4, acquiring a trigger instruction from a user to a display terminal, analyzing the trigger instruction, and determining a current instrument data viewing requirement of the user specifically includes:

acquiring a trigger instruction from a user to a display terminal, analyzing the trigger instruction, and determining the equipment identity information of the instrument and meter which the user needs to view currently, wherein the equipment identity information is used as the instrument and meter data viewing requirement.

In an embodiment disclosed in the present application, in step S4, according to the instrument data viewing requirement, the method of retrieving a matched file data queue from the cloud database, and displaying the retrieved file data queue on the display terminal specifically includes:

according to the equipment identity information of the instrument and meter which needs to be checked by the user at present, a file data queue with matched equipment identity information is called from the cloud database; decompressing the called file data queue, and displaying the file data queue on the display terminal in a dynamic form;

the displaying of the decompressed file data queue by the display terminal in a dynamic form specifically includes:

step S401, extracting and obtaining visual text file data or visual picture file data from a decompressed file data queue, and determining data bit quantity of the text file data and text characters related to instruments and meters in the text file data, or determining data bit quantity of the picture file data and fault component pictures corresponding to the instruments and meters in the picture file data;

step S402, setting a corresponding first display area in a display panel of the display terminal for displaying the text file data in a dynamic form, including: the data bit quantity of each item of text file data is used as the display sequence of all text file data in the first display area from large to small, and only one item of text file data is displayed in the first display area in the same time period; determining the display duration of each item of text file data in the first display area in a positive correlation mode according to the number of text characters related to instruments and meters contained in each item of text file data; when a user touches a display panel of the display terminal for the first time, the first display area is indicated to sequentially display each item of text file data according to the display sequence and the display duration, and simultaneously, highlighting all text characters contained in each item of text file data in different colors in the display process of each item of text file data;

step S403, setting a corresponding second display area in a display panel of the display terminal for displaying the picture file data in a dynamic form, where the second display area is different from the first display area, and includes: taking the sequence of the data bit quantity of each item of picture file data from large to small as the display sequence of all the picture file data in the second display area, and only displaying one item of picture file data in the second display area in the same time period; acquiring the image resolution of a fault component image contained in each image file data, comparing the image resolution with a preset resolution threshold, and if the image resolution is greater than or equal to the preset resolution threshold, performing pixel interpolation processing on the fault component image and then displaying the fault component image in the second display area; if the picture resolution is smaller than a preset resolution threshold, directly displaying the fault component picture in the second display area;

and after the display of all the picture file data and the second display area is finished, shielding the second display area until the picture file data needs to be displayed next time.

Compared with the prior art, the self-defined visual combination instrument control development method obtains respective working logs of different instruments through the instrument control terminal, analyzes and processes the working logs, screens out corresponding fault related data of the instruments, and converts the fault related data into file data in a visual format; arranging and integrating file data to obtain a file data queue, and uploading the file data queue to a cloud database for identification and marking; according to a triggering instruction of a user to a display terminal, obtaining the current instrument data viewing requirement of the user, calling a matched file data queue from a cloud database, and displaying the called file data queue on the display terminal; according to the method, the working log of each instrument is used as a basis, the screening determination and cloud storage of the relevant data of the instrument faults are realized, and the corresponding matched visual file data is called for display according to the user requirements, so that the accuracy and the intuition of the relevant data checking of the instrument are improved.

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

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior art descriptions will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a flow chart of a method for developing a custom visual instrument control of a combination instrument provided by the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without inventive step based on the embodiments of the present invention, are within the scope of protection of the present invention.

Referring to fig. 1, fig. 1 is a schematic flowchart of a custom visualization combination instrument control development method according to an embodiment of the present invention. The development method of the custom visual combined instrument control comprises the following steps:

step S1, constructing a communication link between the instrument control terminal and different instruments, and respectively sending a work information acquisition request to each instrument through the instrument control terminal; generating a corresponding instrument working log according to a feedback result of the instrument on the working information acquisition request;

step S2, analyzing the instrument working log, and screening out corresponding fault-related data from the instrument working log; carrying out format conversion processing on the fault related data to obtain file data with a visual format;

step S3, arranging and integrating the file data to obtain a corresponding file data queue, and uploading the file data queue to a cloud database; and identifying and marking the uploaded file data queue;

step S4, acquiring a trigger instruction from a user to the display terminal, analyzing the trigger instruction, and determining the current instrument data viewing requirement of the user; and according to the instrument data checking requirement, calling a matched file data queue from the cloud database, and displaying the called file data queue on the display terminal.

The beneficial effects of the above technical scheme are: the development method of the custom visual combination instrument control obtains respective working logs of different instruments through an instrument control terminal, analyzes and processes the working logs, screens the corresponding fault related data of the instruments to obtain, and converts the fault related data into file data in a visual format; arranging and integrating file data to obtain a file data queue, and uploading the file data queue to a cloud database for identification marking; according to a triggering instruction of a user to a display terminal, obtaining the current instrument data viewing requirement of the user, calling a matched file data queue from a cloud database, and displaying the called file data queue on the display terminal; according to the method, the working log of each instrument is used as a basis, the screening determination and cloud storage of the relevant data of the instrument faults are realized, and the corresponding matched visual file data is called for display according to the user requirements, so that the accuracy and the intuition of the relevant data checking of the instrument are improved.

Preferably, in step S1, constructing a communication link between the instrument control terminal and different instruments, and sending the work information obtaining request to each instrument through the instrument control terminal specifically includes:

the method comprises the steps that a bidirectional wireless communication connection is established between an instrument control terminal and each instrument, and after the instrument is started, the instrument sends a notification message to the instrument control terminal; and after the instrument receives the notification message, the instrument control terminal sends a work information acquisition request to the instrument.

The beneficial effects of the above technical scheme are: through the mode, independent data communication connection between the instrument control terminal and each instrument can be established, so that the instrument control terminal can independently acquire corresponding work logs from each instrument, and the condition that the work logs fed back by different instruments are interfered is avoided.

Preferably, in step S1, generating a corresponding instrument work log according to a feedback result of the instrument with respect to the work information obtaining request specifically includes:

after the instrument receives the working information acquisition request, extracting a time range corresponding to the working information required to be acquired by the instrument control terminal from the working information acquisition request; and calling the instrument working log with the matched time range from the cache space of the instrument according to the time range.

The beneficial effects of the above technical scheme are: by the aid of the method, the instrument working logs in the corresponding time range can be selectively obtained, the situation that data congestion occurs due to the fact that the instrument feeds all data related to the working logs back to the instrument control terminal is avoided, and the smoothness of data receiving of the instrument control terminal is guaranteed.

Preferably, in this step, analyzing and processing the instrument work log, and screening out corresponding fault-related data from the instrument work log specifically includes:

identifying, analyzing and processing each log data in the instrument working log, and judging whether the log data belong to fault operation data or not; if the log data belong to the log data, corresponding log data are reserved; if not, discarding the corresponding log data.

The beneficial effects of the above technical scheme are: the instrument and meter working log usually comprises a large amount of data related to instruments and meters, but not all the data are directly related to the operation faults of the instruments and meters, and through the mode, detailed identification and judgment can be carried out on each log data of the working log, so that each log data can be screened quickly.

Preferably, in this step, performing recognition analysis processing on each log data in the instrumentation working log, and determining whether the log data belongs to the fault operation data specifically includes:

firstly, judging whether each log data of the instrument working log contains a preset instrument operation related character or not; if yes, determining that the log data belong to instrument operation related data; if not, determining that the log data does not belong to the instrument operation related data;

and then judging whether the instrument operation state representation value in the log data of the instrument operation related data exceeds a preset standard value range, if so, determining that the log data belongs to fault operation data, and if not, determining that the log data does not belong to the fault operation data.

The beneficial effects of the above technical scheme are: by the method, characters contained in the log data are matched and compared, and when the log data contain the preset instrument and meter operation related characters, whether the log data belong to the instrument and meter operation related data can be accurately and quickly determined; and then, comparing the values of the characteristic values of the running state of the instrument contained in the log data of the related data of the running of the instrument, so as to quantitatively judge whether the log data belongs to the fault running data or not, thereby improving the accuracy of identification and judgment of the fault running data.

Preferably, in step S2, performing format conversion processing on the fault-related data to obtain file data with a visualization format specifically includes:

and converting the fault related data into a text format or a picture format to obtain visual text file data or visual picture file data.

The beneficial effects of the above technical scheme are: by the mode, the fault related data are converted into the text file data in a visual form or the picture file data in a visual form, so that the fault related data can be visually converted in advance, and the fault related data can be directly used for visual display.

Preferably, in step S3, the arranging and integrating the file data to obtain a corresponding file data queue, and uploading the file data queue to the cloud database specifically includes:

arranging and integrating all the file data according to the sequence of the creation time of all the file data from early to late to obtain corresponding file data queues; and then the file data queue is compressed and packaged and then uploaded to a cloud database.

The beneficial effects of the above technical scheme are: by the method, the creation time of all the file data is arranged from early to late, so that the file data queue is obtained, the creation time can be conveniently used as an index subsequently, different file data can be quickly searched and positioned, and the accuracy of searching the file data is improved.

Preferably, the device identity information of the corresponding instrument and meter is added to the uploaded file data queue, so that the identification mark of the file data queue is realized.

The beneficial effects of the above technical scheme are: by the mode, the equipment identity information of the instrument is used as the marking information, the uniqueness is marked on each file data queue, so that the displayed data can be calibrated conveniently during subsequent visual display, and a user can directly obtain the instrument type corresponding to the displayed data.

Preferably, in step S4, the obtaining of the trigger instruction from the user to the display terminal, performing parsing processing on the trigger instruction, and determining the current instrument data viewing requirement of the user specifically includes:

acquiring a trigger instruction from a user to a display terminal, analyzing the trigger instruction, and determining the equipment identity information of the instrument and meter which the user needs to view currently, wherein the equipment identity information is used as the instrument and meter data viewing requirement.

The beneficial effects of the above technical scheme are: when a user performs touch control on the display terminal, a trigger instruction can be correspondingly generated, and the trigger instruction is analyzed, so that the current type of instrument data needing to be checked by the user can be determined, and the data can be accurately and quickly screened and acquired from the cloud database.

Preferably, in step S4, according to the instrument data viewing requirement, retrieving a matched file data queue from the cloud database, and displaying the retrieved file data queue on the display terminal specifically includes:

according to the equipment identity information of the instrument and meter which needs to be checked by the user at present, a file data queue with matched equipment identity information is called from the cloud database; decompressing the called file data queue and displaying the decompressed file data queue on the display terminal in a dynamic form;

the displaying of the decompressed file data queue by the display terminal in a dynamic form specifically includes:

step S401, extracting and obtaining the visual text file data or visual picture file data from the decompressed file data queue, and determining the data bit quantity of the text file data and the text characters related to the instrument and meter in the text file data, or determining the data bit quantity of the picture file data and the fault component picture corresponding to the instrument and meter in the picture file data;

step S402, setting a corresponding first display area in a display panel of the display terminal for displaying the text file data in a dynamic form, including: the data bit quantity of each text file data is used as the display sequence of all the text file data in the first display area from large to small, and only one text file data is displayed in the first display area in the same time period; determining the display duration of each item of text file data in the first display area in a positive correlation mode according to the number of text characters related to the instrument contained in each item of text file data; when a user touches a display panel of the display terminal for the first time, indicating the first display area to display each item of text file data in sequence according to the display sequence and the display duration, and simultaneously highlighting all text characters contained in each item of text file data in different colors in the display process of each item of text file data;

step S403, setting a corresponding second display area in the display panel of the display terminal for displaying the picture file data in a dynamic form, where the second display area is different from the first display area, and includes: the data bit quantity of each item of picture file data is used as the display sequence of all the picture file data in the second display area from large to small, and only one item of picture file data is displayed in the second display area in the same time period; acquiring the picture resolution of a fault component picture contained in each picture file data, comparing the picture resolution with a preset resolution threshold, and if the picture resolution is greater than or equal to the preset resolution threshold, performing pixel interpolation processing on the fault component picture and then displaying the fault component picture in the second display area; if the picture resolution is smaller than a preset resolution threshold, directly displaying the fault component picture in the second display area;

and after the display of all the picture file data and the second display area is finished, shielding the second display area until the picture file data needs to be displayed next time.

The beneficial effects of the above technical scheme are: by the mode, the file data queue with the identity information of the matched equipment is called from the cloud database and is directly displayed on the display terminal in a dynamic form of rolling display, so that a user can visually check the corresponding instrument and meter related data, and the convenience of data checking is improved. In addition, because the text file data and the picture file data have different data forms, the viewing habits of users on the text file data and the picture file data are different, the text file data and the picture file data can be displayed in a differentiated mode by setting the first display area and the second display area which are different from each other, and the users can conveniently and accurately acquire required information in the process of viewing the data. In addition, according to the data bit quantity of different text file data and the text characters related to instruments and meters, all the text file data are displayed in a sequential carousel dynamic display mode, so that a user can only view one text file data and highlight the text characters in the text file data in the same time period; according to the data bit quantity of different text file data and the fault component pictures corresponding to the instruments and meters contained in the data bit quantity, all the picture file data are displayed in a sequential carousel dynamic display mode, so that a user can only view one picture file data in the same time period, crosstalk of different picture file data is avoided, pixel interpolation processing is carried out on the corresponding picture file data, the resolution ratio of the corresponding picture file data is improved, and the user can conveniently and clearly view the fault conditions of the instruments and meters.

According to the content of the embodiment, the development method of the custom visual combination instrument control obtains respective working logs of different instruments through the instrument control terminal, analyzes and processes the working logs, screens the working logs to obtain corresponding fault related data of the instruments, and converts the fault related data into file data in a visual format; arranging and integrating file data to obtain a file data queue, and uploading the file data queue to a cloud database for identification marking; according to a triggering instruction of a user to a display terminal, obtaining the current instrument data viewing requirement of the user, calling a matched file data queue from a cloud database, and displaying the called file data queue on the display terminal; according to the method, the working logs of all instruments are used as the basis, screening determination and cloud storage of relevant data of the instruments are achieved, and the visual file data which are correspondingly matched are called according to user requirements to be displayed, so that the accuracy and the intuitiveness of checking the relevant data of the instruments are 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 (10)

1. The development method of the custom visual combined instrument control is characterized by comprising the following steps:

step S1, establishing a communication link between an instrument control terminal and different instruments, and respectively sending a work information acquisition request to each instrument through the instrument control terminal; generating a corresponding instrument working log according to a feedback result of the instrument on the working information acquisition request;

step S2, analyzing and processing the instrument working log, and screening out corresponding fault related data from the instrument working log; carrying out format conversion processing on the fault related data to obtain file data with a visual format;

step S3, arranging and integrating the file data to obtain a corresponding file data queue, and uploading the file data queue to a cloud database; identifying and marking the uploaded file data queue;

step S4, acquiring a trigger instruction from a user to a display terminal, analyzing the trigger instruction, and determining the current instrument data viewing requirement of the user; and according to the instrument data viewing requirement, calling a matched file data queue from the cloud database, and displaying the called file data queue on the display terminal.

2. The custom visualization combination instrument control development method of claim 1, wherein:

in step S1, constructing a communication link between the instrument control terminal and different instruments, and sending a work information acquisition request to each instrument through the instrument control terminal specifically includes:

the method comprises the steps that an instrument control terminal is in bidirectional wireless communication connection with each instrument, and after the instrument is started, the instrument sends a notification message to the instrument control terminal; and after the instrument receives the notification message, the instrument control terminal sends a work information acquisition request to the instrument.

3. The custom visualization instrumentation cluster control development method of claim 2, wherein:

in step S1, generating a corresponding instrument work log according to a feedback result of the instrument with respect to the work information acquisition request specifically includes:

after the instrument receives the working information acquisition request, extracting a time range corresponding to the working information required to be acquired by the instrument control terminal from the working information acquisition request; and calling instrument working logs with matched time ranges from the cache space of the instrument according to the time ranges.

4. The custom visualization instrumentation control development method of claim 3, wherein:

in step S2, analyzing and processing the instrument work log, and screening out corresponding fault-related data from the instrument work log specifically includes:

identifying, analyzing and processing each log data in the instrument working log, and judging whether the log data belong to fault operation data or not; if the log data belong to the log data, corresponding log data are reserved; if not, discarding the corresponding log data.

5. The custom visualization instrumentation control development method of claim 4, wherein:

identifying, analyzing and processing each item of log data in the instrument and meter working log, and judging whether the log data belong to fault operation data specifically comprises the following steps:

firstly, judging whether each log data of the instrument working log contains a preset instrument operation related character or not; if yes, determining that the log data belong to instrument operation related data; if not, determining that the log data does not belong to instrument operation related data;

and then judging whether the instrument operation state representation value in the log data of the instrument operation related data exceeds a preset standard value range, if so, determining that the log data belongs to fault operation data, and if not, determining that the log data does not belong to the fault operation data.

6. The custom visualization instrumentation cluster control development method of claim 5, wherein:

in step S2, performing format conversion processing on the fault-related data to obtain file data with a visual format specifically includes:

and converting the fault related data into a text format or a picture format to obtain visual text file data or visual picture file data.

7. The custom visualization instrumentation cluster control development method of claim 6, wherein:

in step S3, the arranging and integrating the file data to obtain a corresponding file data queue, and uploading the file data queue to a cloud database specifically includes:

arranging and integrating all the file data according to the sequence of the creation time of all the file data from early to late to obtain corresponding file data queues; and then compressing and packaging the file data queue and uploading the file data queue to a cloud database.

8. The custom visualization instrumentation cluster control development method of claim 7, wherein:

in step S3, the identifying and marking the uploaded file data queue specifically includes:

and adding the equipment identity information of the corresponding instrument to the uploaded file data queue, thereby realizing the identification mark of the file data queue.

9. The custom visualization combination instrument control development method of claim 8, wherein:

in step S4, acquiring a trigger instruction from the user to the display terminal, analyzing the trigger instruction, and determining the current instrument data viewing requirement of the user specifically includes:

acquiring a trigger instruction from a user to a display terminal, analyzing the trigger instruction, and determining the equipment identity information of the instrument and meter which the user needs to view currently, wherein the equipment identity information is used as the instrument and meter data viewing requirement.

10. The custom visualization instrumentation cluster control development method of claim 9, wherein:

in step S4, retrieving a matched file data queue from the cloud database according to the instrument data viewing requirement, and displaying the retrieved file data queue on the display terminal specifically includes:

according to the equipment identity information of the instrument and meter which needs to be checked by the user at present, a file data queue with matched equipment identity information is called from the cloud database; decompressing the called file data queue, and displaying the file data queue on the display terminal in a dynamic form;

the displaying of the decompressed file data queue by the display terminal in a dynamic form specifically includes:

step S401, extracting and obtaining visual text file data or visual picture file data from a decompressed file data queue, and determining data bit quantity of the text file data and text characters related to instruments and meters in the text file data, or determining data bit quantity of the picture file data and fault component pictures corresponding to the instruments and meters in the picture file data;

step S402, setting a corresponding first display area in a display panel of the display terminal for displaying the text file data in a dynamic form, including: the data bit quantity of each text file data is used as the display sequence of all the text file data in the first display area from large to small, and only one text file data is displayed in the first display area in the same time period; determining the display duration of each item of text file data in the first display area in a positive correlation mode according to the number of text characters related to instruments and meters contained in each item of text file data; when a user touches a display panel of the display terminal for the first time, the first display area is indicated to display each item of text file data in sequence according to the display sequence and the display duration, and simultaneously, all text characters contained in each item of text file data are highlighted in different colors in the display process of each item of text file data;

step S403, setting a corresponding second display area in a display panel of the display terminal for displaying the picture file data in a dynamic form, where the second display area is different from the first display area, and includes: taking the sequence of the data bit quantity of each item of picture file data from large to small as the display sequence of all the picture file data in the second display area, and only displaying one item of picture file data in the second display area in the same time period; acquiring the image resolution of a fault component image contained in each image file data, comparing the image resolution with a preset resolution threshold, and if the image resolution is greater than or equal to the preset resolution threshold, performing pixel interpolation processing on the fault component image and then displaying the fault component image in the second display area; if the picture resolution is smaller than a preset resolution threshold, directly displaying the fault component picture in the second display area;

and after the display of all the picture file data and the second display area is finished, shielding the second display area until the picture file data needs to be displayed next time.

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