CN117974167B

CN117974167B - Synthetic data processing method of three-dimensional copper-based metal organic framework

Info

Publication number: CN117974167B
Application number: CN202410361585.3A
Authority: CN
Inventors: 姚捷; 孙志明; 陈鹏鹏; 张曦冉; 杨月华; 巴磊; 张学宁; 张敏
Original assignee: Jiangsu Health Development Research Center
Current assignee: Jiangsu Health Development Research Center
Priority date: 2024-03-28
Filing date: 2024-03-28
Publication date: 2024-06-14
Anticipated expiration: 2044-03-28
Also published as: CN117974167A

Abstract

The invention provides a synthetic data processing method of a three-dimensional copper-based metal organic framework, which comprises the steps of decomposing a synthetic step of the three-dimensional copper-based metal organic framework to obtain a synthetic acquisition chain, and obtaining a data acquisition display template according to the synthetic attribute of each synthetic node; judging the last synthetic node in the synthetic acquisition chain to finish synthesis, determining the last synthetic node as a tracing starting point, and extracting a first synthesis moment of the tracing starting point; acquiring time information of acquisition information corresponding to a data acquisition display template of each synthetic node, and calculating second synthetic time corresponding to other traced points in the synthetic acquisition chain based on the first synthetic time and the time sequence relation of the synthetic nodes; processing the acquired information of the data acquisition display template in a segmentation way based on the second synthesis moment to obtain the same group of segmented acquired information; and generating a corresponding traceability identity code based on the information attribute of each piece of segmented acquisition information, and correspondingly storing the traceability identity code, the synthesized acquisition chain and the segmented acquisition information.

Description

Synthetic data processing method of three-dimensional copper-based metal organic framework

Technical Field

The invention relates to a data processing technology, in particular to a synthetic data processing method of a three-dimensional copper-based metal organic framework.

Background

The metal organic framework is a material with larger specific surface area, porous surface structure and adjustable physical and chemical functions, and has wide application prospect. The three-dimensional copper-based metal organic framework with the capability of slowly releasing copper ions designs and prepares the three-dimensional copper-based MOF nano sheet-shaped antibacterial array with a hierarchical structure through a two-step in-situ growth method. Bacteria can be effectively inactivated through the sharp nano-sheet array, meanwhile, the sustained release of low-concentration bactericidal copper ions can provide long-term antibacterial activity, toxicity caused by sudden release of accumulated metal ions is avoided, and long-term durability is improved due to synergistic physical and chemical damage to microorganisms, so that the three-dimensional copper-based metal organic framework with the capability of slowly releasing the copper ions can be applied to medical products such as contraceptive tools.

The antibacterial effect of the three-dimensional copper-based metal framework with the capability of slowly releasing copper ions is closely related to the synthesis process, and the effect is a precondition that a user is relieved to use the product. In the prior art, a user cannot trace the synthesis process of a corresponding product when buying the product, so that the trust degree of the product is reduced, and the specific synthesis process and synthesis data cannot be traced quickly and effectively, thus influencing the management and risk control of the product.

Therefore, how to combine the synthetic data of the product to generate corresponding traceability data enables the user to carry out data traceability on the product becomes a problem to be solved urgently.

Disclosure of Invention

The embodiment of the invention provides a synthetic data processing method of a three-dimensional copper-based metal organic framework, which can be used for generating corresponding traceable data by combining synthetic data of a product, so that a user can trace the data of the product.

In a first aspect of an embodiment of the present invention, there is provided a method for processing synthetic data of a three-dimensional copper-based metal-organic framework, including:

decomposing the synthesis step of the three-dimensional copper-based metal organic framework to generate a corresponding synthesis acquisition chain, wherein the synthesis acquisition chain comprises a plurality of synthesis nodes connected based on the processing sequence step, and obtaining a corresponding data acquisition display template according to the synthesis attribute of each synthesis node;

After judging that the last synthetic node in the synthetic acquisition chain completes synthesis, determining the last synthetic node in the synthetic acquisition chain as a tracing starting point, and extracting a first synthesis time corresponding to the tracing starting point;

Acquiring time information of acquisition information corresponding to a data acquisition display template of each synthetic node, and calculating based on the first synthetic time and a time sequence relation between the synthetic nodes to obtain second synthetic time corresponding to other traced points in a synthetic acquisition chain;

Processing the acquired information of the data acquisition display template in a segmented manner based on the second synthesis time to obtain the segmented acquired information of the same group;

And generating a corresponding traceability identity code based on the information attribute of each piece of segmented acquisition information, and correspondingly storing the traceability identity code, the synthesized acquisition chain and the segmented acquisition information.

Optionally, in one possible implementation manner of the first aspect, the decomposing the synthesizing step of the three-dimensional copper-based metal-organic framework generates a corresponding synthesized acquisition chain, where the synthesized acquisition chain includes a plurality of synthesis nodes connected based on a processing sequence step, and the obtaining a corresponding data acquisition display template according to a synthesis attribute of each synthesis node includes:

Generating a process topology node diagram of the three-dimensional copper-based metal organic framework synthesis step in an interaction manner with a management end, and decomposing the process topology node diagram to obtain synthesis nodes corresponding to each process topology node;

acquiring each process topology node in the process topology node diagram, and connecting the synthesis nodes based on the process to obtain a synthesis acquisition chain;

And extracting corresponding Internet of things equipment according to the synthetic attribute of each synthetic node, wherein each synthetic attribute is provided with preset Internet of things equipment, and performing template division on the initial template based on the Internet of things equipment to obtain a corresponding data acquisition display template.

Optionally, in one possible implementation manner of the first aspect, the performing template division on the initial template based on the internet of things device to obtain a corresponding data acquisition display template includes:

If the video equipment is judged to exist in the Internet of things equipment, a corresponding video total area is established in the initial template, and if the sensor equipment is judged to exist in the Internet of things equipment, a corresponding sensor total area is established in the initial template;

Establishing video windows corresponding to each video device, arranging the video windows at basic points of an initial template according to a preset arrangement strategy to obtain a video window sequence in a video total area, and adjusting the video total area to obtain a video total area after self-adaption adjustment;

setting the sensor total area and the video total area adjacently according to a preset arrangement mode, establishing an information window corresponding to each sensor device, and adjusting the sensor total area based on the information window to obtain an adaptive adjusted sensor total area;

and obtaining a corresponding data acquisition display template based on the video total area and the sensor total area.

Optionally, in one possible implementation manner of the first aspect, the establishing a video window corresponding to each video device, arranging the video windows at a base point of an initial template according to a preset arrangement policy to obtain a video window sequence in a video total area, adjusting the video total area to obtain an adaptively adjusted video total area, and including:

According to the equipment number of the video equipment, vertically arranging basic points of all video windows in a video total area, wherein the basic points of the video total area correspond to the left upper corner points of the video windows, the corner points of the left upper corner of the video total area are used as first corner points, and the first corner points are connection points formed by fixed line segments of the video total area;

after judging that the strategy extremum of vertical arrangement is reached, arranging unordered video windows on one side of the arranged video windows, and obtaining a video window sequence after judging that all video windows are arranged;

And obtaining an unfixed line segment of the video total area, and moving and adjusting the unfixed line segment according to the first angle point direction until the distance between the unfixed line segment and the nearest video window is smaller than or equal to the number of preset pixel points, so as to obtain the video total area after self-adaptive adjustment.

Optionally, in one possible implementation manner of the first aspect, the setting the sensor total area and the video total area adjacent to each other in a preset arrangement manner, establishing an information window corresponding to each sensor device, adjusting the sensor total area based on the information window, and obtaining an adaptively adjusted sensor total area includes:

determining that an edge line of a sensor total area is overlapped with an edge line corresponding to a video total area, and determining a second corner point of a fixed line segment corresponding to the sensor total area;

Vertically arranging all the sensor windows by the second corner points according to the equipment numbers of the sensor equipment;

After judging that the strategy extremum of vertical arrangement is reached, arranging unordered sensor windows on one side of the arranged sensor windows, and obtaining a sensor window sequence after judging that all the sensor windows are arranged;

and obtaining an unfixed line segment of the sensor total area, and moving and adjusting the unfixed line segment according to the second angular point direction until the distance between the unfixed line segment and the nearest sensor window is smaller than or equal to the number of preset pixel points, so as to obtain the sensor total area after self-adaptive adjustment.

Optionally, in one possible implementation manner of the first aspect, the acquiring time information of the collection information corresponding to the data collection display template of each synthetic node, calculating based on the first synthesis time and a time sequence relationship between the synthetic nodes, and obtaining a second synthesis time corresponding to other traced points in the synthetic collection chain includes:

Extracting delay processing time length in a time sequence relation between each synthetic node and a tracing starting point;

Obtaining a second synthesis time corresponding to the corresponding synthesis node based on the first synthesis time and the delay processing time;

And counting the synthesis nodes in the synthesis acquisition chain as the second synthesis time corresponding to the traced points to obtain a corresponding tracing synthesis time table.

Optionally, in one possible implementation manner of the first aspect, the processing, based on the second synthesis time, the acquired information of the data acquisition display template in segments respectively, to obtain the same set of segmented acquired information includes:

Determining the processing time period of each traced point for the synthesis treatment of the three-dimensional copper-based metal-organic frameworks of different batches;

determining that the processing time periods of the second synthesis time of each traced point are the same group based on the tracing synthesis time table, and carrying out segmented processing on the acquired information of the data acquisition display template based on the processing time periods to obtain segmented acquired information corresponding to each traced point;

and counting the segment acquisition information of all the processing time periods of the same group, wherein the segment acquisition information at least comprises the starting time, the ending time, the video information storage amount and the sensor information storage amount of the processing time periods.

Optionally, in one possible implementation manner of the first aspect, the generating a corresponding traceability identity code based on the information attribute of each piece of collected information, and storing the traceability identity code, the composite collection chain, and the piece of collected information correspondingly includes:

Generating corresponding information gaps according to the number of the segmented acquisition information, obtaining corresponding intermediate time according to the starting time and the ending time of each segmented acquisition information, and extracting the number of the intermediate time to obtain a first character;

Determining the total storage amount of the video of the segmented acquisition information and adding a corresponding video suffix to obtain a second character, and determining the total storage amount of the sensor of the segmented acquisition information and adding a corresponding sensor suffix to obtain a third character;

Sequentially sequencing the first character, the second character and the third character, filling the sequenced first character, the sequenced second character and the sequenced third character into an information space to obtain a combined character, obtaining the segmentation order of the day on which the segmentation acquisition information is located, and sequencing and calculating the combined character based on the segmentation order to obtain the traceability identity code.

Optionally, in one possible implementation manner of the first aspect, the sequentially sorting the first character, the second character, and the third character, filling the first character, the second character, and the third character into an information space to obtain a combined character, obtaining a segmentation order of a day on which the segmentation collection information is located, and calculating the combined character based on the segmentation order to obtain the traceability identity code, including:

Determining an arrangement mode corresponding to each segmentation sequence, wherein each segmentation sequence has a corresponding arrangement mode, and the arrangement mode has an arrangement sequence of a first character, a second character and a third character;

and sequencing the first character, the second character and the third character based on the arrangement mode to obtain a character to be converted, and carrying out hash calculation on the character to be converted to obtain the traceability identity code.

Optionally, in one possible implementation manner of the first aspect, the method further includes:

If any tracing end is judged to upload the tracing identity code, determining corresponding segmented acquisition information based on the tracing identity code, and generating a calling link corresponding to the segmented acquisition information;

determining that the calling links of the synthesis nodes of the synthesis acquisition chains corresponding to each piece of segment acquisition information are correspondingly set to obtain interaction chains, and transmitting the interaction chains and the piece of segment acquisition information to a tracing end for tracing interaction;

And if the traceability terminal is judged to feed back the traceability authenticity verification, the segmented acquisition information is processed based on the generation strategy of the traceability identity code to obtain the verification identity code, and if the traceability identity code corresponds to the verification identity code, a first feedback result is output to the traceability terminal.

In a second aspect of the embodiments of the present invention, there is provided a storage medium having stored therein a computer program for implementing the method of the first aspect and the various possible designs of the first aspect when the computer program is executed by a processor.

The beneficial effects of the invention are as follows:

1. according to the invention, the synthesis acquisition chain of the three-dimensional copper-based metal organic framework in the same batch can be generated, and each synthesis node in the synthesis acquisition chain has corresponding segmented acquisition information and corresponding traceability identity codes, so that a subsequent user can quickly and effectively trace back specific synthesis process and synthesis data, and the management and risk control of products are improved. The invention can decompose the synthesis steps of the three-dimensional copper-based metal organic framework to generate corresponding synthesis acquisition chains and generate the data acquisition display template corresponding to each synthesis node, so that all data can be displayed to a user after the node is triggered by subsequent personnel, thereby facilitating quick backtracking, and facilitating management and improving the reliability of products. The invention determines the second synthesis time corresponding to other traced points by tracing the first synthesis time corresponding to the starting point, and performs the segmentation processing on the acquired information in the data acquisition display template by the second synthesis time, thereby obtaining the segmented acquired information of the same batch. And generating a traceability identity code corresponding to each piece of sectional acquisition information according to the production batch, and correspondingly storing the traceability identity code, the synthetic acquisition chain and the sectional acquisition information.

2. According to the method and the system, the data acquisition display templates corresponding to the Internet of things equipment are generated according to different customizations of the Internet of things equipment corresponding to each synthetic node, so that the interface for displaying the data is concise, and meanwhile, the data are orderly arranged, so that the observation of personnel is facilitated. According to the invention, the video windows and the sensor windows are vertically arranged according to the equipment numbers, and after the vertical arrangement cannot be performed, the vertical arrangement is continuously performed on one side of the video windows, so that all data are displayed in the corresponding video total area and the corresponding sensor total area.

3. The invention can generate the traceability identity code of each piece of the acquired information, and is convenient for subsequent personnel to trace and verify data through the traceability identity code, so that a user can trace back the corresponding synthetic process of the product quickly, and the corresponding verification identity code is generated through the piece of the acquired information displayed by the user according to the generation strategy of the traceability identity code, if the traceability identity code is consistent with the verification identity code, the piece of the acquired information and the traceability identity code uploaded by the user are indicated to be the same batch, thereby improving the reliability of the product and enabling the synthetic process to be traced back.

Drawings

FIG. 1 is a flow chart of a process for synthesizing data for a three-dimensional copper-based metal-organic framework according to the present invention;

FIG. 2 is a schematic diagram of a video window sequence provided by the present invention;

FIG. 3 is a schematic diagram of a video total area after adaptive adjustment according to the present invention;

FIG. 4 is a schematic diagram of a sensor window sequence provided by the present invention;

Fig. 5 is a schematic diagram of a total sensor area after adaptive adjustment according to the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The terms "first," "second," "third," "fourth" and the like in the description and in the claims and in the above drawings, if any, are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the invention described herein may be implemented in sequences other than those illustrated or otherwise described herein.

It should be understood that, in various embodiments of the present invention, the sequence number of each process does not mean that the execution sequence of each process should be determined by its functions and internal logic, and should not constitute any limitation on the implementation process of the embodiments of the present invention.

It should be understood that in the present invention, "comprising" and "having" and any variations thereof are intended to cover non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements that are expressly listed or inherent to such process, method, article, or apparatus.

It should be understood that in the present invention, "plurality" means two or more. "and/or" is merely an association relationship describing an association object, meaning that there may be three relationships, e.g., a and/or B, may represent: a exists alone, A and B exist together, and B exists alone. The character "/" generally indicates that the context-dependent object is an "or" relationship. "comprising A, B and C", "comprising A, B, C" means that all three of A, B, C are comprised, "comprising A, B or C" means that one of A, B, C is comprised, "comprising A, B and/or C" means that any 1 or any 2 or 3 of A, B, C are comprised.

It should be understood that in the present invention, "B corresponding to a", "a corresponding to B", or "B corresponding to a" means that B is associated with a, from which B can be determined. Determining B from a does not mean determining B from a alone, but may also determine B from a and/or other information. The matching of A and B is that the similarity of A and B is larger than or equal to a preset threshold value.

As used herein, the term "if" may be interpreted as "at … …" or "at … …" or "in response to a determination" or "in response to a detection", depending on the context.

The technical scheme of the invention is described in detail below by specific examples. The following embodiments may be combined with each other, and some embodiments may not be repeated for the same or similar concepts or processes.

The invention provides a synthetic data processing method of a three-dimensional copper-based metal organic framework, which is shown in fig. 1 and comprises the following steps of S1-S5:

s1, decomposing the synthesis steps of the three-dimensional copper-based metal organic framework to generate a corresponding synthesis acquisition chain, wherein the synthesis acquisition chain comprises a plurality of synthesis nodes connected based on the processing sequence steps, and obtaining a corresponding data acquisition display template according to the synthesis attribute of each synthesis node.

It should be noted that, the synthesis of the three-dimensional copper-based metal organic framework needs to undergo multiple synthesis steps, for example, the steps of cleaning a pure copper sheet, soaking with a corresponding mixed solution, and the like, and the antibacterial effect of the three-dimensional copper-based metal organic framework with the capability of slowly releasing copper ions is closely related to the synthesis process.

The method comprises the steps of sequentially ultrasonically cleaning a pure copper sheet (tube) in dilute sulfuric acid, deionized water and acetone for about 15 minutes and drying, then adding the dried pure copper sheet (tube) into a mixed solution of ammonium persulfate and sodium hydroxide, soaking for 15 minutes, taking out after the surface turns blue, cleaning for 2-3 times by using deionized water, drying to obtain a copper sheet (tube) with a nano copper hydroxide array constructed on the surface, putting the copper sheet (tube) with the nano copper hydroxide array constructed on the surface into a mixed solution of deionized water, N-dimethylformamide, ethanol and 500-1000 mg of terephthalic acid, putting the copper sheet (tube) into an oven at 45-70 ℃ for reacting for 35 minutes, taking out after the reaction is finished, naturally cooling to room temperature, washing for 2-3 times by using ethanol, and drying at room temperature, thereby obtaining a three-dimensional copper-based metal organic frame with slow-release copper ion capability, wherein the surface is light blue, and the three-dimensional copper-based metal organic frame can be applied to various medical products such as contraception and the like.

Therefore, the server decomposes the synthesizing step of the three-dimensional copper-based metal organic framework to obtain a plurality of synthesizing nodes, and connects the synthesizing nodes according to the procedure to generate a corresponding synthesizing acquisition chain, wherein the synthesizing acquisition chain comprises the plurality of synthesizing nodes connected based on the processing sequence step.

Specifically, the server obtains a data acquisition display template corresponding to each synthesized node according to the synthesized attribute of the synthesized node.

In some embodiments, in step S1 (decomposing the synthesis step of the three-dimensional copper-based metal-organic framework to generate a corresponding synthesis acquisition chain, where the synthesis acquisition chain includes a plurality of synthesis nodes connected based on the processing sequence step, and obtaining a corresponding data acquisition display template according to a synthesis attribute of each synthesis node), the method includes S11-S13:

s11, generating a process topology node diagram of the three-dimensional copper-based metal organic framework synthesis step in an interaction manner with the management end, and decomposing the process topology node diagram to obtain synthesis nodes corresponding to each process topology node.

In the invention, the pure copper sheet is subjected to synthesis reaction through a plurality of process steps, so that the three-dimensional copper-based metal organic framework is obtained, and therefore, a process topology node diagram corresponding to the synthesis step can be generated in a subsequent interaction manner with the management terminal.

It can be understood that the server and the management end interactively generate a process topology node diagram of the three-dimensional copper-based metal-organic framework synthesis step, namely a topology node diagram corresponding to the corresponding synthesis process step.

For example, a topological connection diagram of the corresponding three-dimensional copper-based metal organic framework is obtained through a plurality of process steps, for example, the step of ultrasonic cleaning in dilute sulfuric acid, deionized water and acetone corresponds to a cleaning process topological node; putting the topological node into a mixed solution added with ammonium persulfate and sodium hydroxide, and soaking for 15 minutes to obtain a corresponding soaked process topological node; putting the copper sheet (tube) with the nano copper hydroxide array on the surface into a mixed solution of deionized water, N-dimethylformamide, ethanol and 500-1000 mg of terephthalic acid, putting into a baking oven at 45-70 ℃ for reaction for 35 minutes, taking out after the reaction is finished, and connecting (cleaning, soaking and reacting) the process topology nodes according to the sequence of a plurality of process steps to obtain a process topology node diagram.

Specifically, the server may decompose the process topology node map to obtain synthetic nodes corresponding to each process topology node, for example, the process topology nodes of cleaning, soaking and reacting correspond to the synthetic nodes of cleaning, soaking and reacting respectively, and are illustrated in 3 steps for convenience of understanding. Wherein each process topology node has a corresponding composite node.

S12, acquiring a procedure of each process topology node in the process topology node diagram, and connecting the synthetic nodes based on the procedure to obtain a synthetic acquisition chain.

It can be understood that the server can acquire the procedure of each process topology node in the process topology node diagram, and the synthetic acquisition chain is obtained by connecting the synthetic nodes based on the sequence of the procedure.

It is understood that the acquisition chain is obtained by sequentially connecting the corresponding synthetic nodes according to the process flows of cleaning, soaking and reacting.

S13, extracting corresponding Internet of things equipment according to the synthesis attribute of each synthesis node, wherein each synthesis attribute is provided with preset Internet of things equipment, and performing template division on the initial template based on the Internet of things equipment to obtain a corresponding data acquisition display template.

It is easy to understand that different internet of things devices are arranged in each synthesis step, for example, videos in the synthesis process are collected through a camera, subsequent backtracking is facilitated, whether the values of the solutions in each synthesis step meet the standard or not is monitored in real time through a pH value sensor, a concentration sensor and the like, and subsequent users can backtrack conveniently.

The synthetic attribute is the acquisition attribute of the synthetic node, for example, a dried pure copper sheet (tube) is added into a mixed solution of ammonium persulfate and sodium hydroxide for soaking for 15 minutes in a soaking link, the copper sheet (tube) with the surface constructed with the nano copper hydroxide array is obtained after the surface is changed to blue and is taken out, and is washed for 2-3 times by deionized water and then dried, the acquisition time is required, the surface of the pure copper sheet (tube) is acquired through a camera and is changed to blue, the pH value of the mixed solution is detected through a pH value sensor, and the like, and different synthetic nodes need different Internet of things equipment, so that the copper sheet (tube) has different synthetic attributes.

The internet of things device may be a camera, a sensor, etc. Each composite attribute has preset internet of things equipment.

It can be understood that the server can perform template division on the initial template based on the internet of things equipment to obtain a corresponding data acquisition display template.

In some embodiments, in step S13 (the initial template is partitioned based on the internet of things device to obtain a corresponding data acquisition and display template), the method includes S131-S134:

S131, if the video equipment is judged to exist in the Internet of things equipment, a corresponding video total area is established in the initial template, and if the sensor equipment is judged to exist in the Internet of things equipment, a corresponding sensor total area is established in the initial template.

It can be understood that if the video equipment is judged to exist in the internet of things equipment, a corresponding video total area is established in the initial template, and if the sensor equipment is judged to exist in the internet of things equipment, a corresponding sensor total area is established in the initial template.

S132, establishing video windows corresponding to each video device, arranging the video windows at basic points of an initial template according to a preset arrangement strategy to obtain a video window sequence in a video total area, and adjusting the video total area to obtain a video total area after self-adaption adjustment.

It should be noted that, because the data that needs to be gathered of different synthetic nodes are different, therefore, the number of corresponding video devices is different, therefore, the number of video windows in the total region of video corresponding to each synthetic node is different, the placement is relatively disordered, the viewing by people is inconvenient, the user experience is lower, therefore, the video windows can be discharged according to a preset arrangement strategy later, the total region of video is adjusted from the adaptation, the adjusted total region of video can just display the video windows with corresponding number, and the viewing by the subsequent people is convenient.

It can be understood that the server establishes a video window corresponding to each video device, arranges the video windows at the basic points of the initial template according to a preset arrangement policy to obtain a video window sequence in a video total area, and adjusts the video total area to obtain a video total area after self-adaptive adjustment.

In some embodiments, in step S132 (a video window corresponding to each video device is established, the video windows are arranged at the base points of the initial template according to a preset arrangement policy to obtain a video window sequence in a total video area, the total video area is adjusted to obtain a total video area after adaptive adjustment), including S1321-S1323:

S1321, vertically arranging the basic points of all the video windows in the video total area according to the equipment number of the video equipment, wherein the basic points of the video total area correspond to the left upper corner points of the video windows, the corner points of the left upper corner of the video total area are used as first corner points, and the first corner points are connection points formed by fixed line segments of the video total area.

The basic point of the initial template corresponds to a first corner point of the video window, the first corner point is a connection point formed by a fixed line segment of a video total area, and the basic point is a preset point. It will be appreciated that the base points are arranged in turn at fixed line segments to the left of the overall video area.

It can be understood that the server sequentially vertically arranges the base points of the video total area for all video windows according to the device numbers of the video devices, and it is easy to understand that when the video windows are set, the corner points of the upper left corner of the video windows are sequentially aligned with the base points of the video total area, and the corner points of the upper left corner of the video total area are used as first corner points, and the first corner points are connection points formed by fixed line segments of the video total area, so that the fixed line segments are an upper area line and a left area line of the video total area, and the area lines of the lower side and the right side are non-fixed line segments.

For example, referring to fig. 2, the corresponding composite node is soaked, having 4 video devices (devices 1-4), and thus, having 4 video windows (video windows 1-4), the upper left corner points of the corresponding video windows are sequentially aligned with the base point pairs Ji Shuxiang in the video total area according to the device numbers of the video devices, and it is not difficult to see the base point aligned with the upper left corner point of the video window 1 in the video total area as the first corner point.

S1322, after judging that the strategy extreme value of vertical arrangement is reached, arranging unordered video windows on one side of the arranged video windows, and obtaining a video window sequence after judging that all video windows are arranged.

It can be understood that after the server determines that the policy extremum of the vertical arrangement is reached, that is, after the server determines that the vertical arrangement of the next video window cannot be continued, the server arranges the unordered video windows on one side of the arranged video windows, and obtains the video window sequence after determining that the arrangement of all video windows is completed.

The policy extremum is a number extremum of vertically arranged video windows, for example, the vertical ordering in the total video area can only be arranged by 3 at most, and the policy extremum is 3 when the number of the policy extremum is 1,2 and 3.

It will be understood that, referring to fig. 2, corresponding video windows are vertically arranged sequentially from the base point of the upper left corner of the initial template according to the sequence of the device numbers until the first vertical row is full and the next video window cannot be arranged, video windows (No. 4) which are not ordered are continuously arranged from top to bottom on the right side of the first vertical row, and the sequence of video windows is continuously repeated until all video windows are arranged completely.

S1323, obtaining an unfixed line segment of the video total area, and moving and adjusting the unfixed line segment according to the first angle direction until the distance between the unfixed line segment and the nearest video window is smaller than or equal to the number of preset pixels, so as to obtain the video total area after self-adaptive adjustment.

It is easy to understand that the number of cameras corresponding to different synthesis nodes is different, and after all video windows are sequenced in the video total area, a blank area still exists in the video total area, so that the video total area can be adaptively adjusted, the video total area after self-adaptive adjustment can exactly and completely display the corresponding video window, and the video total area is convenient for subsequent personnel to check.

It can be understood that the server may acquire an unfixed line segment of the video total area, and move and adjust the unfixed line segment according to the direction of the first angle point, that is, close to the first angle point until the distance between the unfixed line segment and the nearest video window is less than or equal to the number of preset pixels, so as to obtain the video total area after self-adaptive adjustment.

Referring to fig. 3, the present invention moves the lower and right region lines as non-fixed line segments toward the first corner, moves the lower non-fixed line segment upward, and moves the right non-fixed line segment leftward, thereby generating an adaptively adjusted video total region.

Through the implementation mode, the area size of the video total area can be adapted to the number of video windows, and people can check conveniently.

S133, setting the sensor total area and the video total area adjacently according to a preset arrangement mode, establishing an information window corresponding to each sensor device, and adjusting the sensor total area based on the information window to obtain the sensor total area after self-adaption adjustment.

It should be noted that, because the data that needs to be gathered of different synthetic nodes are different, therefore, the sensor equipment quantity that corresponds is different, consequently, the information window quantity in the total district of the corresponding sensor of every synthetic node is different, put comparatively messy, inconvenient personnel look over for user experience is felt lowly, consequently, can arrange the information window according to predetermineeing the arrangement policy afterwards, and adjust the total district of sensor from the adaptation, make the total district of sensor after the adjustment can show the information window of corresponding quantity just, make things convenient for follow-up personnel to look over.

It can be understood that the server will set the sensor total area and the video total area adjacently according to a preset arrangement manner, that is, the sensor total area is set on one side of the video total area in an abutting manner, the sensor total area is set on the right side of the video total area in an abutting manner, an information window corresponding to each sensor device is established, the sensor total area is adjusted based on the information window, and the sensor total area after self-adaptive adjustment is obtained.

In some embodiments, in step S133 (the sensor total area and the video total area are adjacently arranged according to a preset arrangement manner, an information window corresponding to each sensor device is established, the sensor total area is adjusted based on the information window, and an adaptively adjusted sensor total area is obtained), including S1331-S1334:

s1331, determining that edge lines of the total area of the sensor are overlapped with edge lines corresponding to the total area of the video, and determining a second corner point of a fixed line segment corresponding to the total area of the sensor.

It will be appreciated that the server will determine that the edge line of the sensor total area coincides with the edge line corresponding to the video total area, i.e. will place the sensor total area and the video total area against each other, e.g. will place the edge line on the right side of the video total area coincides with the edge line on the left side of the sensor total area. And determining a second corner point of the fixed line segment corresponding to the total sensor area, namely, a vertex angle of the upper left corner of the total sensor area as the second corner point.

The second corner point is a connection point formed by a fixed line segment of the total area of the sensor.

S1332, vertically arranging all the sensor windows by the second corner points according to the equipment numbers of the sensor equipment.

It will be appreciated that all sensor windows are arranged vertically in sequence by the second corner point according to the device number of the sensor device.

It will be appreciated that the corresponding sensor windows are arranged vertically in sequence from top to bottom from the second corner point (the top left corner vertex) of the total sensor area.

S1333, after judging that the strategy extreme value of the vertical arrangement is reached, arranging unordered sensor windows on one side of the arranged sensor windows, and obtaining a sensor window sequence after judging that all the sensor windows are arranged.

It can be understood that after the policy extremum of the vertical arrangement is judged, the policy extremum is the same as that of the arrangement video window, namely, after the vertical arrangement of the sensor windows cannot be continuously vertically ordered, the unordered sensor windows are arranged on one side of the arranged sensor windows, and after all the sensor windows are judged to be arranged, a sensor window sequence is obtained.

Referring to fig. 4,6 sensor windows (No. 1-6) are vertically arranged sequentially from the second corner from top to bottom, so as to obtain a sensor window sequence.

It is to be understood that, according to the sequence of the device numbers, the corresponding sensor windows are vertically arranged sequentially from the second corner point until the first vertical row is full of the next sensor window, and the sensor windows which are not ordered are continuously arranged from top to bottom on the right side of the first vertical row until all the sensor windows are arranged to obtain a sensor window sequence.

S1334, obtaining an unfixed line segment of the sensor total area, and moving and adjusting the unfixed line segment according to the second angular point direction until the distance between the unfixed line segment and the nearest sensor window is smaller than or equal to the number of preset pixel points, so as to obtain the sensor total area after self-adaptive adjustment.

The number of preset pixels is the number of artificially preset pixels, for example, 50 pixels, it is easy to understand that the self-adaptive adjustment is performed on the total video area and the total sensor area, the lower area line moves upwards and the right area line moves leftwards, and when the number of the pixels is less than or equal to 50 from the nearest sensor and the nearest video window, the area after the response self-adaptive adjustment is obtained.

It is easy to understand that the number and types of the sensors corresponding to different synthetic nodes are different, and after all the sensor windows are ordered, a blank area still exists in the sensor total area, so that the sensor total area is adaptively adjusted, and the sensor total area after the self-adaption adjustment can exactly and completely display the corresponding sensor window.

It can be understood that the server may obtain the non-fixed line segments of the total sensor area, and move the non-fixed line segments together and adjust the non-fixed line segments according to the second angular point direction until the distance between the non-fixed line segments and the nearest sensor window is less than or equal to the number of preset pixels, so as to obtain the total sensor area after self-adaptive adjustment.

For example, referring to fig. 5, consistent with the principle of adaptively adjusting the video total area, the present invention automatically adjusts the sensor total area, moves the non-fixed line segment at the lower side of the sensor total area upwards, and moves the non-fixed line segment at the right side of the sensor total area leftwards until the distance between the non-fixed line segment and the nearest sensor window is less than or equal to the preset number of pixels, thereby obtaining the sensor total area after the self-adaptive adjustment.

Through the embodiment, the area size of the total area of the sensor can be adapted to the number of the sensor windows, so that people can conveniently check the total area, and the data acquisition display template can be used for displaying the total area of the sensor to the people after the subsequent people click any one of the synthetic nodes, so that the people can check all data, for example, all video data and sensor data.

S134, obtaining a corresponding data acquisition display template based on the video total area and the sensor total area.

S2, after the last synthetic node in the synthetic acquisition chain is judged to finish synthesis, determining the last synthetic node in the synthetic acquisition chain as a tracing starting point, and extracting a first synthesis time corresponding to the tracing starting point.

It can be understood that after the server determines that the last synthesis node in the synthesis acquisition chain completes synthesis, that is, after the synthesis of the three-dimensional copper-based metal organic framework is determined to be completed, the server determines the last synthesis node in the synthesis acquisition chain as a tracing start point, and extracts a completion time corresponding to the tracing start point as a first synthesis time.

For example, when the three-dimensional copper-based metal-organic framework is 10 points at the time of completion of synthesis, 10 points are taken as the first synthesis time.

S3, acquiring time information of acquisition information corresponding to the data acquisition display templates of each synthetic node, and calculating based on the first synthetic time and the time sequence relation among the synthetic nodes to obtain second synthetic time corresponding to other traced points in the synthetic acquisition chain.

It should be noted that, each synthesis node has a corresponding camera, a sensor, etc. for collecting data corresponding to each synthesis step, for example, a ph sensor, a concentration sensor, etc., for example, in a cleaning step, a pure copper sheet (tube) is sequentially ultrasonically cleaned and dried in dilute sulfuric acid, deionized water, acetone, and a camera collecting and synthesizing process is provided with a concentration sensor for detecting the concentration of dilute sulfuric acid.

Therefore, the data acquisition display template records the time information corresponding to the acquired information acquired by the corresponding cameras, sensors and the like, the server can acquire the time information of the acquired information corresponding to the data acquisition display template of each synthetic node, and then the second synthetic time corresponding to other traced points in the synthetic acquisition chain is obtained based on the first synthetic time and the time sequence relation calculation among the synthetic nodes.

For example, the three-dimensional copper-based metal-organic framework has 3 synthesis steps in total, and thus has 3 synthesis nodes, the first synthesis time is 10 points, the first step requires 15 minutes for cleaning, the second step requires 15 minutes for soaking, and the third step requires 35 minutes for reaction, and thus the second synthesis time of the synthesis node of the second one corresponding to the second step is 9.25, and the second synthesis time of the synthesis node of the first one corresponding to the first step is 9.10.

In some embodiments, in step S3 (obtaining time information of the collection information corresponding to the data collection presentation template of each synthetic node, and calculating based on the first synthesis time and the time sequence relationship between the synthetic nodes to obtain a second synthesis time corresponding to other traced points in the synthetic collection chain), the method includes S31-S33:

s31, extracting delay processing time length in the time sequence relation between each synthesized node and the tracing starting point.

It can be appreciated that the server will extract the delay processing duration in the timing relationship of each composite node to the traceback starting point. That is, the processing time period corresponding to each synthetic node is obtained as the delayed processing time period, for example, the first step of washing takes 15 minutes, the second step of soaking takes 15 minutes, the third step of reaction takes 35 minutes, and the delayed processing time periods in the time sequence relationship are 35 minutes, 15 minutes and 15 minutes.

The delay processing time is the processing time of each composite node.

S32, obtaining a second synthesis time corresponding to the corresponding synthesis node based on the first synthesis time and the delay processing time.

It can be understood that the second synthesis time corresponding to the corresponding synthesis node can be obtained through the first synthesis time and the delay processing time.

Therefore, the second synthesis time of the synthesis node of the second one corresponding to the second step is 9.25, and the second synthesis time of the synthesis node of the first one corresponding to the first step is 9.10.

S33, counting the synthesis nodes in the synthesis acquisition chain as a second synthesis time and a first synthesis time corresponding to the traced points, and obtaining a corresponding tracing synthesis time table.

It can be understood that the server may count the second synthesis time and the first synthesis time corresponding to the synthesized node in the synthesis acquisition chain as the traced point, so as to obtain a corresponding tracing synthesis time table, i.e. count the completion time of the operation of each synthesis node, for example, wash to 9.10, soak to 9.25, and react to 10 points.

S4, processing the acquired information of the data acquisition display template in a segmented mode based on the second synthesis time to obtain the same group of segmented acquired information.

After each synthesis step is completed, the synthesis of the three-dimensional copper-based metal organic framework of the next batch is performed immediately.

Therefore, the server can respectively process the acquired information of the data acquisition display templates in a segmentation way based on the second synthesis time of the same batch, so that the same group of segmented acquired information is obtained.

For example, the second synthesis time of the second synthesis node corresponding to the second step is 9.25, the second synthesis time of the first synthesis node corresponding to the first step is 9.10, the processing time period corresponding to the first synthesis node is 8.55-9.10, the processing time period corresponding to the second synthesis node is 9.10-9.25, the processing time period corresponding to the third synthesis node is 9.25-10.00, and then the corresponding acquired data are subjected to segmentation processing according to the respective processing time periods, so that the segmented acquired information of the same group is obtained.

In some embodiments, in step S4 (processing the collected information of the data collection presentation template in segments based on the second synthesis time respectively to obtain the same set of segment collected information) includes S41-S43:

s41, determining the processing time period of each traced point for the three-dimensional copper-based metal-organic framework synthesis processing of different batches.

After each synthesis step is completed, the synthesis of the three-dimensional copper-based metal organic framework of the next batch is performed immediately. For example, every 15 minutes a lot is cleaned, and is always in process, 8.55-9.10 being one lot and 9.10-9.25 being another lot.

Thus, the server will determine the processing time period for each traced point to a different batch of three-dimensional copper-based metal-organic framework synthesis processes.

S42, determining that the processing time periods of the second synthesis time of each traced point are the same group based on the tracing synthesis time table, and carrying out segmented processing on the acquired information of the data acquisition display template based on the processing time periods to obtain segmented acquired information corresponding to each traced point.

It will be appreciated that the server will determine the processing time period at which the second synthesis time of the traced back point is located as the same set of processing time periods based on the traced back synthesis time schedule of the same batch.

Specifically, the acquired information of the data acquisition display template is processed in a segmentation mode based on the same group of processing time periods, and segmented acquired information corresponding to each traced point is obtained. The method comprises the steps of processing the acquired information of the data acquisition display template in a segmentation mode based on the processing time period of the same batch, so that segmented acquired information corresponding to each traced point of the same batch is obtained. For example, the processing time period corresponding to the first synthetic node is 8.55-9.10, the processing time period corresponding to the second synthetic node is 9.10-9.25, and the processing time period corresponding to the third synthetic node is 9.25-10.00.

Through the embodiment, the method and the device can obtain the related synthesis data of the three-dimensional copper-based metal organic framework synthesized in the same batch, and facilitate subsequent personnel to trace back the products in the corresponding batch.

S43, counting the segment collection information of all the processing time periods of the same group, wherein the segment collection information at least comprises the starting time, the ending time, the video information storage amount and the sensor information storage amount of the processing time periods.

It will be appreciated that the server will count the segment collection information for all processing time periods of the same group, wherein the segment collection information includes at least the start time, the end time, the video information storage amount, and the sensor information storage amount of the processing time period. The processing time period corresponding to the first synthetic node is 8.55-9.10, the start time is 8.55, and the end time is 9.10, wherein the storage amount of video information is the storage amount of videos of each synthetic node, for example, the storage amount of video information can be 100kb, and the storage amount of sensor information is the storage amount of detection information corresponding to a sensor of the synthetic node.

S5, generating corresponding traceability identity codes based on the information attribute of each piece of segmented acquisition information, and storing the traceability identity codes, the synthesized acquisition chain and the segmented acquisition information correspondingly.

It can be understood that the server generates a corresponding traceability identity code according to the information attribute of each piece of the acquisition information, and correspondingly stores the traceability identity code, the synthetic acquisition chain and the piece of the acquisition information.

In some embodiments, in step S5 (generating a corresponding traceability identity code based on the information attribute of each piece of collected information, and storing the traceability identity code, the composite collection chain, and the piece of collected information correspondingly) includes S51-S53:

S51, corresponding information gaps are generated according to the number of the segmented acquisition information, corresponding intermediate time is obtained according to the starting time and the ending time of each segmented acquisition information, and the number of the intermediate time is extracted to obtain a first character.

It will be appreciated that the server may generate corresponding information slots according to the number of segment collection information, for example, with 3 composite nodes, and then generate 3 information slots with 3 segment collection information.

Specifically, the server obtains a corresponding intermediate time according to the start time and the end time of each segment for collecting information, for example, 2023/02/05,8.55-9.10, the intermediate time is 2023/02/05,9.02.30, and then the number of the intermediate time is extracted to obtain a first character, for example, the first character is 2023020590230.

S52, determining the total storage amount of the video of the segment collection information and adding a corresponding video suffix to obtain a second character, and determining the total storage amount of the sensor of the segment collection information and adding a corresponding sensor suffix to obtain a third character.

It can be understood that the server determines the total storage amount of the video of the corresponding segment acquisition information and adds a corresponding video suffix to obtain a second character, and simultaneously determines the total storage amount of the sensor of the corresponding segment acquisition information and adds a corresponding sensor suffix to obtain a third character.

The video suffix is the name suffix of the step of acquiring the video corresponding to the segmented acquisition information, for example, the step of cleaning acquires the video, and the corresponding video suffix is cleaning.

And S53, sequentially sequencing the first character, the second character and the third character, filling the sequenced first character, the sequenced second character and the sequenced third character into an information space to obtain a combined character, obtaining the segmentation order of the day on which the segmentation acquisition information is located, and sequencing and calculating the combined character based on the segmentation order to obtain the traceability identity code.

It can be understood that the server can sequentially sort the first character, the second character and the third character and fill the first character, the second character and the third character into the information space to obtain the combined character, and meanwhile, can acquire the segmentation sequence of the day on which the segmentation acquisition information is located, and re-sort and calculate the combined character according to the segmentation sequence to obtain the traceability identity code.

In some embodiments, in step S53 (the first character, the second character, and the third character are sequentially ordered and then filled into an information space to obtain a combined character, a segmentation order of a day on which the segmentation collection information is located is obtained, and a traceability identity code is obtained by sequencing and calculating the combined character based on the segmentation order), including S531-S532:

s531, determining an arrangement mode corresponding to each segment sequence, wherein each segment sequence has a corresponding arrangement mode, and the arrangement mode has an arrangement sequence of a first character, a second character and a third character.

It should be noted that, the three-dimensional copper-based metal organic frame is a first batch, the segmentation order is 1, the three-dimensional copper-based metal organic frame is a second batch, the segmentation order is 2, and so on, the segmentation order of the corresponding synthetic nodes of each batch can be determined.

Wherein each segment order has a corresponding arrangement.

It will be appreciated that the server determines the arrangement corresponding to each segment order, where the arrangement is an arrangement having a first character, a second character, and a third character.

For example, the first group of the corresponding arrangement sequences is (first character, second character, third character), the second group of the corresponding arrangement sequences is (second character, third character, first character), the third group of the corresponding arrangement sequences is (third character, first character, second character), the fourth group of the corresponding arrangement sequences is (first character, second character, third character), and the above steps are repeated continuously, so that the arrangement mode of the corresponding characters of each group can be obtained.

S532, ordering the first character, the second character and the third character based on the arrangement mode to obtain a character to be converted, and carrying out hash calculation on the character to be converted to obtain the traceability identity code.

It can be understood that the server sorts the first character, the second character and the third character based on the arrangement mode to obtain the character to be converted, and hashes the character to be converted to obtain the traceability identity code. It is easy to understand that the corresponding traceability identity code is generated by encrypting through hash calculation.

On the basis of the above embodiment, the method further comprises:

if any tracing end is judged to upload the tracing identity code, corresponding segmented acquisition information is determined based on the tracing identity code, and a calling link corresponding to the segmented acquisition information is generated.

It can be understood that if the judgment personnel upload the corresponding traceability identity code, the server determines the corresponding segmented acquisition information based on the traceability identity code and generates the retrieval link corresponding to the segmented acquisition information.

The calling link is a link for calling the corresponding segment acquisition information.

And determining that the calling links of the synthesis nodes of the synthesis acquisition chains corresponding to the segmented acquisition information are correspondingly set to obtain interaction chains, and transmitting the interaction chains and the segmented acquisition information to a tracing end for tracing interaction.

It can be understood that the server will set the synthetic node of the synthetic acquisition chain corresponding to each piece of the segmented acquisition information to the corresponding call link, so as to obtain the interactive chain. After the subsequent user triggers the nodes on the interactive chain, the user can be considered to trigger the corresponding calling links, and the corresponding segmented acquisition information is called to display the user.

Specifically, the server sends the interaction chain and the segment acquisition information to the tracing end for tracing interaction.

It should be noted that, the three-dimensional copper-based metal organic frame with the capability of slowly releasing copper ions can provide long-term antibacterial activity due to the sustained release of low-concentration bactericidal copper ions, avoid toxicity caused by the sudden release of accumulated metal ions, and simultaneously improve long-term durability due to the synergistic physical and chemical damage to microorganisms.

Because the server sends the corresponding segmented acquisition information to display the user, the user cannot know whether the segmented acquisition information is the acquisition information of the batch corresponding to the product, and therefore the invention can verify the authenticity of the product.

It is not easy to understand that if the tracing end is judged to feed back the tracing authenticity verification, that is, the authenticity verification needs to be performed, the corresponding segmented acquisition information is processed based on the generation strategy of the tracing identity code to obtain the verification identity code, that is, the same processing is performed on the segmented acquisition information displayed by the user through the generation principle of the steps S51-S53 to obtain the corresponding verification identity code, and if the tracing identity code corresponds to the verification identity code, the first feedback result, that is, the correct result is output to the tracing end.

The present invention also provides a storage medium having stored therein a computer program for implementing the methods provided by the various embodiments described above when executed by a processor.

The storage medium may be a computer storage medium or a communication medium. Communication media includes any medium that facilitates transfer of a computer program from one place to another. Computer storage media can be any available media that can be accessed by a general purpose or special purpose computer. For example, a storage medium is coupled to the processor such the processor can read information from, and write information to, the storage medium. In the alternative, the storage medium may be integral to the processor. The processor and the storage medium may reside in an Application SPECIFIC INTEGRATED Circuits (ASIC). In addition, the ASIC may reside in a user device. The processor and the storage medium may reside as discrete components in a communication device. The storage medium may be read-only memory (ROM), random-access memory (RAM), CD-ROMs, magnetic tape, floppy disk, optical data storage device, etc.

The present invention also provides a program product comprising execution instructions stored in a storage medium. The at least one processor of the device may read the execution instructions from the storage medium, the execution instructions being executed by the at least one processor to cause the device to implement the methods provided by the various embodiments described above.

In the above embodiments of the terminal or the server, it should be understood that the Processor may be a central processing unit (english: central Processing Unit, abbreviated as CPU), or may be other general purpose processors, digital signal processors (english: DIGITAL SIGNAL Processor, abbreviated as DSP), application specific integrated circuits (english: application SPECIFIC INTEGRATED Circuit, abbreviated as ASIC), or the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The steps of a method disclosed in connection with the present invention may be embodied directly in a hardware processor for execution, or in a combination of hardware and software modules in a processor for execution.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention.

Claims

1. The synthetic data processing method of the three-dimensional copper-based metal organic framework is characterized by comprising the following steps of:

Generating a corresponding traceability identity code based on the information attribute of each piece of segmented acquisition information, and correspondingly storing the traceability identity code, the synthesized acquisition chain and the segmented acquisition information;

the synthesis step of the three-dimensional copper-based metal organic framework is decomposed to generate a corresponding synthesis acquisition chain, the synthesis acquisition chain comprises a plurality of synthesis nodes connected based on the processing sequence steps, and a corresponding data acquisition display template is obtained according to the synthesis attribute of each synthesis node, and the synthesis acquisition chain comprises the following steps:

extracting corresponding Internet of things equipment according to the synthesis attribute of each synthesis node, wherein each synthesis attribute is provided with preset Internet of things equipment, and performing template division on an initial template based on the Internet of things equipment to obtain a corresponding data acquisition display template;

the method for carrying out template division on the initial template based on the Internet of things equipment to obtain a corresponding data acquisition display template comprises the following steps:

Obtaining a corresponding data acquisition display template based on the video total area and the sensor total area;

The method for establishing the video window corresponding to each video device comprises the steps of arranging the video windows at basic points of an initial template according to a preset arrangement strategy to obtain a video window sequence in a video total area, adjusting the video total area to obtain a video total area after self-adaption adjustment, and comprises the following steps:

obtaining an unfixed line segment of a video total area, and moving and adjusting the unfixed line segment according to the first angle point direction until the distance between the unfixed line segment and a nearest video window is smaller than or equal to the number of preset pixel points, so as to obtain the video total area after self-adaptive adjustment;

Setting the sensor total area and the video total area adjacently according to a preset arrangement mode, establishing an information window corresponding to each sensor device, adjusting the sensor total area based on the information window, and obtaining an adaptive adjusted sensor total area, wherein the adaptive adjustment method comprises the following steps:

Obtaining an unfixed line segment of the sensor total area, and moving and adjusting the unfixed line segment according to the second angular point direction until the distance between the unfixed line segment and the nearest sensor window is smaller than or equal to the number of preset pixel points, so as to obtain the sensor total area after self-adaptive adjustment;

The generating a corresponding traceability identity code based on the information attribute of each piece of the collected information, and correspondingly storing the traceability identity code, the synthesized collection chain and the piece of the collected information comprises the following steps:

sequentially sequencing the first character, the second character and the third character, filling the sequenced first character, the sequenced second character and the sequenced third character into an information space to obtain combined characters, obtaining a segmentation sequence of the day on which the segmentation acquisition information is located, and sequencing and calculating the combined characters based on the segmentation sequence to obtain a traceability identity code;

sequentially sequencing the first character, the second character and the third character, filling the sequenced first character, the second character and the third character into an information space to obtain a combined character, obtaining a segmentation sequence of the day on which the segmentation acquisition information is located, and sequencing and calculating the combined character based on the segmentation sequence to obtain a traceability identity code, wherein the method comprises the following steps:

Sequencing the first character, the second character and the third character based on the arrangement mode to obtain a character to be converted, and carrying out hash calculation on the character to be converted to obtain a traceability identity code;

further comprises:

2. The method for processing synthetic data of three-dimensional copper-based metal-organic framework according to claim 1, wherein,

The obtaining the time information of the collection information corresponding to the data collection display template of each synthetic node, and calculating based on the first synthesis time and the time sequence relation between the synthetic nodes to obtain a second synthesis time corresponding to other traced points in the synthetic collection chain, including:

And counting the synthesis nodes in the synthesis acquisition chain as a second synthesis time and a first synthesis time corresponding to the traced point to obtain a corresponding tracing synthesis time table.

3. The method for processing synthetic data of three-dimensional copper-based metal-organic framework according to claim 2, wherein,

The step of processing the acquired information of the data acquisition display template based on the second synthesis time to obtain the same group of segmented acquired information comprises the following steps: