CN117499442B - Data efficient processing method for Internet of things energy monitoring device - Google Patents
Data efficient processing method for Internet of things energy monitoring device Download PDFInfo
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- H—ELECTRICITY
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Abstract
The invention relates to the field of energy monitoring data processing of the Internet of things, in particular to a data efficient processing method for an energy monitoring device of the Internet of things, which comprises the following steps: s1, acquiring operation data and corresponding operation data characteristics of an energy monitoring device of the Internet of things; s2, acquiring and verifying the integrity by utilizing the operation data of the energy monitoring device of the Internet of things to obtain an operation data integrity verification result; s3, performing hardware overall cooperativity verification according to the operation data integrity verification result by using the operation data of the Internet of things energy monitoring device to obtain a hardware overall cooperativity verification result of the Internet of things energy monitoring device; and S4, performing systematic integrated processing according to the hardware total cooperativity verification result and the corresponding operation data characteristics to obtain a data efficient processing result, and providing a data and data characteristic-based efficient data output method.
Description
Technical Field
The invention relates to the field of energy monitoring data processing of the Internet of things, in particular to a data efficient processing method for an energy monitoring device of the Internet of things.
Background
The energy monitoring data acquisition technology based on the Internet of things mainly solves the problem that energy monitoring data acquisition is carried out on an object-oriented mode of an energy monitoring node of the Internet of things, but the monitoring acquisition of the traditional energy monitoring device of the Internet of things is poor in data processing efficiency and accuracy effect on the common field of energy monitoring of the Internet of things such as a large-scale or large-scale factory, or the monitoring efficiency is improved, but the actual data output effect of the energy monitoring device of the Internet of things is poor due to interference of the verification means on data output in a large-scale, and meanwhile, certain risk exists in the field of energy monitoring only by means of data verification, and the data cannot be traced to hardware equipment of the Internet of things.
Disclosure of Invention
Aiming at the defects of the prior art, the invention provides a data efficient processing method for an Internet of things energy monitoring device, which improves the accuracy of output data and ensures the real-time performance of communication transmission by carrying out multi-stage and multi-target processing on the output data of the Internet of things energy monitoring device.
In order to achieve the above object, the present invention provides a data efficient processing method for an energy monitoring device of the internet of things, including:
s1, acquiring operation data and corresponding operation data characteristics of an energy monitoring device of the Internet of things;
s2, acquiring and verifying the integrity by utilizing the operation data of the energy monitoring device of the Internet of things to obtain an operation data integrity verification result;
S3, performing hardware overall cooperativity verification according to the operation data integrity verification result by using the operation data of the Internet of things energy monitoring device to obtain a hardware overall cooperativity verification result of the Internet of things energy monitoring device;
And S4, performing systematic integrated processing according to the hardware overall cooperativity verification result and the corresponding operation data characteristics to obtain a data efficient processing result.
Preferably, the acquiring the operation data and the corresponding operation data characteristics of the internet of things energy monitoring device includes:
s1-1, collecting real-time operation data of an energy monitoring device of the Internet of things;
s1-2, acquiring a hardware interface address of the energy monitoring device of the Internet of things as a real-time operation data hardware auxiliary tag;
s1-3, acquiring a communication link of the Internet of things energy monitoring device as a real-time operation data communication auxiliary tag;
s1-4, utilizing the real-time operation data, the real-time operation data hardware auxiliary tag and the real-time operation data communication auxiliary tag as operation data;
s1-5, taking the corresponding data type of the real-time operation data as the corresponding operation data characteristic of the real-time operation data.
Further, the acquiring the integrity verification by using the operation data of the internet of things energy monitoring device to obtain the operation data integrity verification result comprises the following steps:
S2-1, performing data hysteresis verification by using the operation data of the Internet of things energy monitoring device to correspond to real-time operation data to obtain a real-time operation data hysteresis verification result;
S2-2, performing data communication integrity verification by utilizing the real-time operation data hardware auxiliary tag corresponding to the operation data of the Internet of things energy monitoring device and the real-time operation data communication auxiliary tag to obtain a data communication integrity verification result;
s2-3, performing data rationality verification by using the operation data characteristics of the energy monitoring device of the Internet of things to obtain an operation data characteristic rationality verification result;
s2-4, using the real-time operation data hysteresis verification result, the data communication integrity verification result and the operation data feature rationality verification result as operation data integrity verification results.
Further, performing data hysteresis verification by using the operation data of the internet of things energy monitoring device to correspond to the real-time operation data, and obtaining a real-time operation data hysteresis verification result includes:
s2-1-1, utilizing the acquisition time of the real-time operation data corresponding to the operation data of the energy monitoring device of the Internet of things as a verification standard time t;
s2-1-2, respectively acquiring real-time operation data at the time t-1 and the time t+1 as pre-verification data and post-verification data;
S2-1-3, establishing a check mapping by utilizing the pre-check data and the post-check data;
s2-1-4, judging whether the real-time operation data at the verification standard time t have the same historical real-time operation data, if so, executing S2-1-5, otherwise, directly executing S2-1-6;
s2-1-5, judging whether the mapping trend of the verification mapping corresponding to the historical real-time operation data is consistent with the mapping trend of the verification mapping corresponding to the verification standard time t, if so, using the verification mapping corresponding to the verification standard time t as a real-time operation data hysteresis verification result, otherwise, executing S2-1-6;
S2-1-6, judging whether the mapping trend of the split mapping at the verification standard time t is consistent with the mapping trend of the corresponding historical split mapping, if so, using the split mapping at the verification standard time t as a real-time running data hysteresis verification result, otherwise, returning to S1-1;
the mapping trend is a relative trend of two data values in the mapping, the split mapping comprises a pre-mapping and a post-mapping, the pre-mapping is a mapping of pre-verification data and real-time operation data of verification standard time t, and the post-mapping is a mapping of real-time operation data of verification standard time t and post-verification data.
Further, performing data communication integrity verification by using the real-time operation data hardware auxiliary tag corresponding to the operation data of the internet of things energy monitoring device and the real-time operation data communication auxiliary tag to obtain a data communication integrity verification result includes:
S2-2-1, judging whether the real-time operation data hardware auxiliary label corresponding to the operation data of the Internet of things energy monitoring device corresponds to the real-time operation data communication auxiliary label, if yes, executing S2-2-2, otherwise, returning to S1-1;
s2-2-2, judging whether the real-time operation data hardware auxiliary tag and the real-time operation data communication auxiliary tag are corresponding to a data gateway of the Internet of things energy monitoring device, if yes, executing S2-2-3, otherwise, returning to S1-2;
S2-2-3, judging whether the data gateway corresponding communication protocols of the Internet of things energy monitoring device are corresponding to the real-time operation data hardware auxiliary tag and the real-time operation data communication auxiliary tag, if so, using the operation data corresponding data gateway of the Internet of things energy monitoring device as a data communication integrity verification result, otherwise, giving up processing;
The data gateway is a data gateway of an internet of things protocol corresponding to the internet of things energy monitoring device.
Further, performing data rationality verification by using the operation data characteristics of the internet of things energy monitoring device to obtain an operation data characteristic rationality verification result includes:
S2-3-1, judging whether the number of the operation data features of the Internet of things energy monitoring device is 1, if so, establishing an operation data feature time sequence set by using the operation data features of the Internet of things energy monitoring device, and executing S2-3-2, otherwise, arranging according to the time sequence corresponding to the operation data features of the Internet of things energy monitoring device to obtain the operation data feature time sequence set, and executing S2-3-2;
S2-3-2, judging whether the operation data characteristics of the energy monitoring device of the Internet of things are completely consistent with the corresponding communication histories of the data gateway, if so, using the operation data characteristic time sequence set as an operation data characteristic rationality verification result, otherwise, returning to S1-1.
Further, performing hardware overall cooperativity verification according to the operation data integrity verification result by using the operation data of the internet of things energy monitoring device to obtain a hardware overall cooperativity verification result of the internet of things energy monitoring device comprises:
S3-1, establishing a receiving verification node, a transmission verification node and an integral verification node by using a real-time operation data hysteresis verification result of the operation data integrity verification result, the real-time operation data hysteresis verification result and an operation data characteristic rationality verification result;
S3-2, judging whether the transmission consistency of the receiving verification node and the transmission verification node corresponds or not, if so, executing S3-3, otherwise, returning to S1-1;
S3-3, judging whether the data consistency of the transmission verification node and the overall verification node corresponds or not, if so, executing S3-4, otherwise, performing the staged restoration processing;
S3-4, judging whether the circulation time sequences of the real-time operation data corresponding to the receiving verification node, the transmission verification node and the integral verification node are normal or not, if yes, using the receiving verification node, the transmission verification node and the integral verification node as a hardware integral cooperativity verification result, otherwise, returning to S2-1;
The transmission consistency is the consistency and correspondence between the real-time operation data corresponding to the receiving verification node and the transmission history corresponding to the transmission verification node, the data consistency is the time sequence correspondence between the real-time operation data corresponding to the transmission verification node and the characteristic time sequence set of the operation data corresponding to the integral verification node, and the streaming time sequence is normal when the data corresponding to the receiving verification node, the transmission verification node and the integral verification node are streaming.
Further, the step of performing the periodic recovery processing includes:
S3-3-1, acquiring the energy type corresponding to the real-time operation data of the energy monitoring device of the Internet of things as a staged label;
s3-3-2, judging whether the number of the phase labels corresponding to the real-time operation data is 1, if so, the recovery dimension of the real-time operation data is 1, and executing S3-3-3, otherwise, using the phase labels as the recovery dimension of the real-time operation data, and executing S3-3-3;
S3-3-3, performing data tracing processing according to the recovery dimension by using the receiving verification node, the transmitting verification node, the integral verification node and the corresponding real-time operation data to obtain reverse recovery data of the energy monitoring device of the Internet of things;
S3-3-4, judging whether the reverse recovery data corresponds to the energy monitoring device of the Internet of things, if so, executing S3-3-5, otherwise, returning to S1-1;
S3-3-5, judging whether the reverse recovery data corresponds to the data flow direction of the real-time operation data of the energy monitoring device of the Internet of things, if so, executing S3-4, otherwise, returning to S1-1;
and the data tracing processing carries out data return processing on the real-time operation data according to the recovery dimension on the receiving verification node, the transmission verification node and the integral verification node.
Further, performing systematic integration processing according to the hardware overall cooperativity verification result and the corresponding operation data characteristics to obtain a data efficient processing result comprises:
Utilizing the hardware aggregate cooperativity verification result as a data system integrated reference node;
Acquiring the corresponding time of the data systematic integral reference node as the data systematic integral reference time;
judging whether the data systematic integration reference time corresponds to the energy monitoring device of the Internet of things and the real-time operation data thereof step by step, if so, outputting the current real-time operation data as a data efficient processing result, otherwise, returning to S1-1;
the step-by-step correspondence is the current data systematic integration reference moment, and the real-time operation data corresponding to the energy monitoring device of the Internet of things corresponds to the operation data integrity verification result and each item of data of the hardware overall collaborative verification result.
Compared with the closest prior art, the invention has the following beneficial effects:
In the common internet of things energy monitoring distribution, a high-efficiency data output method based on data and data characteristics is provided, in the soft and hard combination, the internet of things energy monitoring device and corresponding data output are mutually verified, the accuracy of output data is improved, meanwhile, the processing steps are refined, in the actual operation, the processing can be quickly returned according to the corresponding steps of the problems, the scheme self-circulation logic is realized, the open-circulation implementation processing can be carried out, and the internet of things energy monitoring index and the data output efficiency of a large-scale or large-scale factory area are greatly improved.
Drawings
Fig. 1 is a flowchart of a data efficient processing method for an internet of things energy monitoring device.
Detailed Description
The following describes the embodiments of the present invention in further detail with reference to the drawings.
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 some embodiments of the present invention, but not all embodiments of the present invention. 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.
Example 1: the invention provides a data efficient processing method for an energy monitoring device of the Internet of things, which is shown in fig. 1 and comprises the following steps:
s1, acquiring operation data and corresponding operation data characteristics of an energy monitoring device of the Internet of things;
s2, acquiring and verifying the integrity by utilizing the operation data of the energy monitoring device of the Internet of things to obtain an operation data integrity verification result;
S3, performing hardware overall cooperativity verification according to the operation data integrity verification result by using the operation data of the Internet of things energy monitoring device to obtain a hardware overall cooperativity verification result of the Internet of things energy monitoring device;
And S4, performing systematic integrated processing according to the hardware overall cooperativity verification result and the corresponding operation data characteristics to obtain a data efficient processing result.
In this embodiment, a data efficient processing method for an energy monitoring device of the internet of things considers the wireless coverage problem of intelligent service of the scene of the internet of things, and as the number of target object devices in the scene of the surrounding environment increases, if the perceived service capability of the edge domain for the target object device with low power consumption is completely or excessively dependent on a dedicated service node or base station device (such as an internet of things host, a router, a gateway/relay, a positioning base station, etc.), the wireless coverage of the perceived service capability and the insufficient computing power or higher resource cost consumption will be caused.
S1 specifically comprises:
s1-1, collecting real-time operation data of an energy monitoring device of the Internet of things;
s1-2, acquiring a hardware interface address of the energy monitoring device of the Internet of things as a real-time operation data hardware auxiliary tag;
s1-3, acquiring a communication link of the Internet of things energy monitoring device as a real-time operation data communication auxiliary tag;
s1-4, utilizing the real-time operation data, the real-time operation data hardware auxiliary tag and the real-time operation data communication auxiliary tag as operation data;
s1-5, taking the corresponding data type of the real-time operation data as the corresponding operation data characteristic of the real-time operation data.
In this embodiment, the data type is an essential type of real-time operation data, for example, in the form of a table, a collection, a sequence, etc., and is used for the data efficient processing method of the internet of things energy monitoring device.
S2 specifically comprises:
S2-1, performing data hysteresis verification by using the operation data of the Internet of things energy monitoring device to correspond to real-time operation data to obtain a real-time operation data hysteresis verification result;
S2-2, performing data communication integrity verification by utilizing the real-time operation data hardware auxiliary tag corresponding to the operation data of the Internet of things energy monitoring device and the real-time operation data communication auxiliary tag to obtain a data communication integrity verification result;
s2-3, performing data rationality verification by using the operation data characteristics of the energy monitoring device of the Internet of things to obtain an operation data characteristic rationality verification result;
s2-4, using the real-time operation data hysteresis verification result, the data communication integrity verification result and the operation data feature rationality verification result as operation data integrity verification results.
S2-1 specifically comprises:
s2-1-1, utilizing the acquisition time of the real-time operation data corresponding to the operation data of the energy monitoring device of the Internet of things as a verification standard time t;
s2-1-2, respectively acquiring real-time operation data at the time t-1 and the time t+1 as pre-verification data and post-verification data;
S2-1-3, establishing a check mapping by utilizing the pre-check data and the post-check data;
s2-1-4, judging whether the real-time operation data at the verification standard time t have the same historical real-time operation data, if so, executing S2-1-5, otherwise, directly executing S2-1-6;
s2-1-5, judging whether the mapping trend of the verification mapping corresponding to the historical real-time operation data is consistent with the mapping trend of the verification mapping corresponding to the verification standard time t, if so, using the verification mapping corresponding to the verification standard time t as a real-time operation data hysteresis verification result, otherwise, executing S2-1-6;
S2-1-6, judging whether the mapping trend of the split mapping at the verification standard time t is consistent with the mapping trend of the corresponding historical split mapping, if so, using the split mapping at the verification standard time t as a real-time running data hysteresis verification result, otherwise, returning to S1-1;
the mapping trend is a relative trend of two data values in the mapping, the split mapping comprises a pre-mapping and a post-mapping, the pre-mapping is a mapping of pre-verification data and real-time operation data of verification standard time t, and the post-mapping is a mapping of real-time operation data of verification standard time t and post-verification data.
S2-2 specifically comprises:
S2-2-1, judging whether the real-time operation data hardware auxiliary label corresponding to the operation data of the Internet of things energy monitoring device corresponds to the real-time operation data communication auxiliary label, if yes, executing S2-2-2, otherwise, returning to S1-1;
s2-2-2, judging whether the real-time operation data hardware auxiliary tag and the real-time operation data communication auxiliary tag are corresponding to a data gateway of the Internet of things energy monitoring device, if yes, executing S2-2-3, otherwise, returning to S1-2;
S2-2-3, judging whether the data gateway corresponding communication protocols of the Internet of things energy monitoring device are corresponding to the real-time operation data hardware auxiliary tag and the real-time operation data communication auxiliary tag, if so, using the operation data corresponding data gateway of the Internet of things energy monitoring device as a data communication integrity verification result, otherwise, giving up processing;
The data gateway is a data gateway of an internet of things protocol corresponding to the internet of things energy monitoring device.
In this embodiment, in the data efficient processing method for the internet of things energy monitoring device, the negative direction corresponding processing is the discarding processing in S2-2-3, the corresponding situation of the step is that the communication line is normal and the communication protocol is normal, and the tracing reason cannot guarantee the accuracy of the result, so that the discarding processing is performed, and in practical application, the internet of things energy monitoring device should be reset and the scheme is operated again.
S2-3 specifically comprises:
S2-3-1, judging whether the number of the operation data features of the Internet of things energy monitoring device is 1, if so, establishing an operation data feature time sequence set by using the operation data features of the Internet of things energy monitoring device, and executing S2-3-2, otherwise, arranging according to the time sequence corresponding to the operation data features of the Internet of things energy monitoring device to obtain the operation data feature time sequence set, and executing S2-3-2;
S2-3-2, judging whether the operation data characteristics of the energy monitoring device of the Internet of things are completely consistent with the corresponding communication histories of the data gateway, if so, using the operation data characteristic time sequence set as an operation data characteristic rationality verification result, otherwise, returning to S1-1.
S3 specifically comprises:
S3-1, establishing a receiving verification node, a transmission verification node and an integral verification node by using a real-time operation data hysteresis verification result of the operation data integrity verification result, the real-time operation data hysteresis verification result and an operation data characteristic rationality verification result;
S3-2, judging whether the transmission consistency of the receiving verification node and the transmission verification node corresponds or not, if so, executing S3-3, otherwise, returning to S1-1;
S3-3, judging whether the data consistency of the transmission verification node and the overall verification node corresponds or not, if so, executing S3-4, otherwise, performing the staged restoration processing;
S3-4, judging whether the circulation time sequences of the real-time operation data corresponding to the receiving verification node, the transmission verification node and the integral verification node are normal or not, if yes, using the receiving verification node, the transmission verification node and the integral verification node as a hardware integral cooperativity verification result, otherwise, returning to S2-1;
The transmission consistency is the consistency and correspondence between the real-time operation data corresponding to the receiving verification node and the transmission history corresponding to the transmission verification node, the data consistency is the time sequence correspondence between the real-time operation data corresponding to the transmission verification node and the characteristic time sequence set of the operation data corresponding to the integral verification node, and the streaming time sequence is normal when the data corresponding to the receiving verification node, the transmission verification node and the integral verification node are streaming.
In this embodiment, a data efficient processing method for an energy monitoring device of the internet of things creatively proposes a receiving verification node, a transmitting verification node and an overall verification node as abstract intermediate nodes of processing steps in a procedural scheme.
S3-3 specifically comprises:
S3-3-1, acquiring the energy type corresponding to the real-time operation data of the energy monitoring device of the Internet of things as a staged label;
s3-3-2, judging whether the number of the phase labels corresponding to the real-time operation data is 1, if so, the recovery dimension of the real-time operation data is 1, and executing S3-3-3, otherwise, using the phase labels as the recovery dimension of the real-time operation data, and executing S3-3-3;
S3-3-3, performing data tracing processing according to the recovery dimension by using the receiving verification node, the transmitting verification node, the integral verification node and the corresponding real-time operation data to obtain reverse recovery data of the energy monitoring device of the Internet of things;
S3-3-4, judging whether the reverse recovery data corresponds to the energy monitoring device of the Internet of things, if so, executing S3-3-5, otherwise, returning to S1-1;
S3-3-5, judging whether the reverse recovery data corresponds to the data flow direction of the real-time operation data of the energy monitoring device of the Internet of things, if so, executing S3-4, otherwise, returning to S1-1;
and the data tracing processing carries out data return processing on the real-time operation data according to the recovery dimension on the receiving verification node, the transmission verification node and the integral verification node.
In this embodiment, the data efficient processing method for the internet of things energy monitoring device, S3-3-4, involves reverse recovery data, and can be understood as obtaining the current data content, type and source through data tracing, and performing reverse deduction based on the above conditions to obtain tracing data, in the general internet of things energy monitoring hardware scheme, mostly adopts a layered distributed structure, and mainly comprises three parts of a sensing layer (terminal acquisition device), a network layer (communication management terminal) and a platform layer (energy internet of things cloud platform), so that the reverse tracing processing realizes data and time verification, and meanwhile verifies the distributed architecture, namely, a step realizes a multi-level target.
S4 specifically comprises the following steps:
S4-1, using the hardware overall cooperativity verification result as a data system integrated reference node;
s4-2, acquiring the corresponding time of the data systematic integral reference node as the data systematic integral reference time;
S4-3, judging whether the data systematic integration reference time corresponds to the real-time operation data of the Internet of things energy monitoring device or not, if so, outputting the current real-time operation data as a data efficient processing result, otherwise, returning to S1-1;
the step-by-step correspondence is the current data systematic integration reference moment, and the real-time operation data corresponding to the energy monitoring device of the Internet of things corresponds to the operation data integrity verification result and each item of data of the hardware overall collaborative verification result.
It will be appreciated by those skilled in the art that embodiments of the present invention may be provided as a method, system, or computer program product. Accordingly, the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present invention may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.
The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems) and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flowchart illustrations and/or block diagrams, and combinations of flows and/or blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.
These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.
These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.
Finally, it should be noted that: the above embodiments are only for illustrating the technical aspects of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the above embodiments, it should be understood by those of ordinary skill in the art that: modifications and equivalents may be made to the specific embodiments of the invention without departing from the spirit and scope of the invention, which is intended to be covered by the claims.
Claims (1)
1. The data efficient processing method for the internet of things energy monitoring device is characterized by comprising the following steps of:
s1, acquiring operation data and corresponding operation data characteristics of an energy monitoring device of the Internet of things;
s1-1, collecting real-time operation data of an energy monitoring device of the Internet of things;
s1-2, acquiring a hardware interface address of the energy monitoring device of the Internet of things as a real-time operation data hardware auxiliary tag;
s1-3, acquiring a communication link of the Internet of things energy monitoring device as a real-time operation data communication auxiliary tag;
s1-4, utilizing the real-time operation data, the real-time operation data hardware auxiliary tag and the real-time operation data communication auxiliary tag as operation data;
s1-5, taking the corresponding data type of the real-time operation data as the corresponding operation data characteristic of the real-time operation data;
s2, acquiring and verifying the integrity by utilizing the operation data of the energy monitoring device of the Internet of things to obtain an operation data integrity verification result;
S2-1, performing data hysteresis verification by using the operation data of the Internet of things energy monitoring device to correspond to real-time operation data to obtain a real-time operation data hysteresis verification result;
s2-1-1, utilizing the acquisition time of the real-time operation data corresponding to the operation data of the energy monitoring device of the Internet of things as a verification standard time t;
s2-1-2, respectively acquiring real-time operation data at the time t-1 and the time t+1 as pre-verification data and post-verification data;
S2-1-3, establishing a check mapping by utilizing the pre-check data and the post-check data;
s2-1-4, judging whether the real-time operation data at the verification standard time t have the same historical real-time operation data, if so, executing S2-1-5, otherwise, directly executing S2-1-6;
s2-1-5, judging whether the mapping trend of the verification mapping corresponding to the historical real-time operation data is consistent with the mapping trend of the verification mapping corresponding to the verification standard time t, if so, using the verification mapping corresponding to the verification standard time t as a real-time operation data hysteresis verification result, otherwise, executing S2-1-6;
S2-1-6, judging whether the mapping trend of the split mapping at the verification standard time t is consistent with the mapping trend of the corresponding historical split mapping, if so, using the split mapping at the verification standard time t as a real-time running data hysteresis verification result, otherwise, returning to S1-1;
The mapping trend is the relative trend of two data values in the mapping, the split mapping comprises a pre-mapping and a post-mapping, the pre-mapping is the mapping of the pre-verification data and the real-time operation data of the verification standard time t, and the post-mapping is the mapping of the real-time operation data of the verification standard time t and the post-verification data;
S2-2, performing data communication integrity verification by utilizing the real-time operation data hardware auxiliary tag corresponding to the operation data of the Internet of things energy monitoring device and the real-time operation data communication auxiliary tag to obtain a data communication integrity verification result;
S2-2-1, judging whether the real-time operation data hardware auxiliary label corresponding to the operation data of the Internet of things energy monitoring device corresponds to the real-time operation data communication auxiliary label, if yes, executing S2-2-2, otherwise, returning to S1-1;
s2-2-2, judging whether the real-time operation data hardware auxiliary tag and the real-time operation data communication auxiliary tag are corresponding to a data gateway of the Internet of things energy monitoring device, if yes, executing S2-2-3, otherwise, returning to S1-2;
S2-2-3, judging whether the data gateway corresponding communication protocols of the Internet of things energy monitoring device are corresponding to the real-time operation data hardware auxiliary tag and the real-time operation data communication auxiliary tag, if so, using the operation data corresponding data gateway of the Internet of things energy monitoring device as a data communication integrity verification result, otherwise, giving up processing;
the data gateway is a data gateway of an internet of things protocol corresponding to the internet of things energy monitoring device;
s2-3, performing data rationality verification by using the operation data characteristics of the energy monitoring device of the Internet of things to obtain an operation data characteristic rationality verification result;
S2-3-1, judging whether the number of the operation data features of the Internet of things energy monitoring device is 1, if so, establishing an operation data feature time sequence set by using the operation data features of the Internet of things energy monitoring device, and executing S2-3-2, otherwise, arranging according to the time sequence corresponding to the operation data features of the Internet of things energy monitoring device to obtain the operation data feature time sequence set, and executing S2-3-2;
S2-3-2, judging whether the operation data characteristics of the energy monitoring device of the Internet of things are completely consistent with the corresponding communication histories of the data gateway, if so, using the operation data characteristic time sequence set as an operation data characteristic rationality verification result, otherwise, returning to S1-1;
S2-4, using the real-time operation data hysteresis verification result, the data communication integrity verification result and the operation data feature rationality verification result as operation data integrity verification results;
S3, performing hardware overall cooperativity verification according to the operation data integrity verification result by using the operation data of the Internet of things energy monitoring device to obtain a hardware overall cooperativity verification result of the Internet of things energy monitoring device;
S3-1, establishing a receiving verification node, a transmission verification node and an integral verification node by using a real-time operation data hysteresis verification result of the operation data integrity verification result, the real-time operation data hysteresis verification result and an operation data characteristic rationality verification result;
S3-2, judging whether the transmission consistency of the receiving verification node and the transmission verification node corresponds or not, if so, executing S3-3, otherwise, returning to S1-1;
S3-3, judging whether the data consistency of the transmission verification node and the overall verification node corresponds or not, if so, executing S3-4, otherwise, performing the staged restoration processing;
S3-3-1, acquiring the energy type corresponding to the real-time operation data of the energy monitoring device of the Internet of things as a staged label;
s3-3-2, judging whether the number of the phase labels corresponding to the real-time operation data is 1, if so, the recovery dimension of the real-time operation data is 1, and executing S3-3-3, otherwise, using the phase labels as the recovery dimension of the real-time operation data, and executing S3-3-3;
S3-3-3, performing data tracing processing according to the recovery dimension by using the receiving verification node, the transmitting verification node, the integral verification node and the corresponding real-time operation data to obtain reverse recovery data of the energy monitoring device of the Internet of things;
S3-3-4, judging whether the reverse recovery data corresponds to the energy monitoring device of the Internet of things, if so, executing S3-3-5, otherwise, returning to S1-1;
S3-3-5, judging whether the reverse recovery data corresponds to the data flow direction of the real-time operation data of the energy monitoring device of the Internet of things, if so, executing S3-4, otherwise, returning to S1-1;
The data tracing processing carries out data return processing on the real-time operation data according to the recovery dimension on the receiving verification node, the transmission verification node and the integral verification node;
S3-4, judging whether the circulation time sequences of the real-time operation data corresponding to the receiving verification node, the transmission verification node and the integral verification node are normal or not, if yes, using the receiving verification node, the transmission verification node and the integral verification node as a hardware integral cooperativity verification result, otherwise, returning to S2-1;
The transmission consistency is the consistency and correspondence between the real-time operation data corresponding to the receiving verification node and the transmission history corresponding to the transmission verification node, the data consistency is the time sequence correspondence between the real-time operation data corresponding to the transmission verification node and the characteristic time sequence set of the operation data corresponding to the integral verification node, and the streaming time sequence is normal when the data corresponding to the receiving verification node, the transmission verification node and the integral verification node are streaming;
s4, performing systematic integrated processing according to the hardware overall cooperativity verification result and the corresponding operation data characteristics to obtain a data efficient processing result;
S4-1, using the hardware overall cooperativity verification result as a data system integrated reference node;
s4-2, acquiring the corresponding time of the data systematic integral reference node as the data systematic integral reference time;
S4-3, judging whether the data systematic integration reference time corresponds to the real-time operation data of the Internet of things energy monitoring device or not, if so, outputting the current real-time operation data as a data efficient processing result, otherwise, returning to S1-1;
the step-by-step correspondence is the current data systematic integration reference moment, and the real-time operation data corresponding to the energy monitoring device of the Internet of things corresponds to the operation data integrity verification result and each item of data of the hardware overall collaborative verification result.
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