CN114217240B - Uninterruptible power supply detection method and system - Google Patents
Uninterruptible power supply detection method and system Download PDFInfo
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- CN114217240B CN114217240B CN202111472262.4A CN202111472262A CN114217240B CN 114217240 B CN114217240 B CN 114217240B CN 202111472262 A CN202111472262 A CN 202111472262A CN 114217240 B CN114217240 B CN 114217240B
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- G01R31/40—Testing power supplies
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Abstract
According to the uninterruptible power supply detection method and system, the transmission track searching is carried out on the electric signal transmission data to be detected, so that the electric signal transmission direction of the electric signal transmission data to be detected is calculated, and the integrity of calculating the electric signal transmission direction is improved. Further, the power supply electrifying conditions corresponding to the signals of each transmission fluctuation list are calculated based on the electric signal transmission direction of the electric signal transmission data to be detected, the integrity of the calculated power supply electrifying conditions is improved, the electric signal electrifying conditions corresponding to the electric signal transmission data to be detected according to the movement mode are built, the integrity of the effective electric signal detection content selected under the optimized interference is improved, and the accuracy of determining the effective electric signal detection content is improved.
Description
Technical Field
The application relates to the technical field of data detection, in particular to an uninterruptible power supply detection method and system.
Background
Along with the continuous development of artificial intelligence, the uninterrupted detection of the power supply is realized, so that the working condition of the power supply can be timely and accurately known, the problem that related equipment fails due to sudden failure of the power supply is effectively avoided, and the problem that equipment is damaged can be prevented from being avoided as far as possible. However, in the process of power supply detection, there is a problem that the effective electric signal detection content is not accurately selected.
Disclosure of Invention
In view of this, the present application provides an uninterruptible power supply detection method and system.
In a first aspect, an uninterruptible power supply detection method is provided, including:
acquiring electric signal transmission data to be detected, carrying out transmission track searching on the electric signal transmission data to be detected, and calculating an electric signal transmission direction corresponding to the electric signal transmission data to be detected based on a transmission track searching result;
building an electric signal electrifying condition according to a movement mode, corresponding to the electric signal transmission data to be detected, according to the electric signal transmission direction;
and determining effective electric signal detection content in the electric signal transmission data to be detected based on the electric signal electrifying condition and the first electrifying object.
Further, after the acquiring the transmission data of the electrical signal to be detected, the method further includes:
and carrying out identification processing on the transmission data of the electric signal to be detected.
Further, the searching of the transmission track for the transmission data of the electric signal to be detected includes:
and carrying out type distinguishing and splicing processing on the electric signal transmission data to be detected, and carrying out transmission track searching on a processing result.
Further, the building the electric signal energizing condition according to the motion mode corresponding to the electric signal transmission data to be detected according to the electric signal transmission direction includes:
Determining the strength of the electric signal transmission data to be detected according to the electric signal transmission direction, constructing an importance degree electric signal strength vector based on the electric signal transmission direction and the strength of the electric signal, and analyzing the electric signal transmission direction by utilizing the importance degree electric signal strength vector;
and building the electric signal electrifying condition according to the movement mode, corresponding to the electric signal transmission data to be detected, by utilizing the electric signal transmission direction before analysis and the electric signal transmission direction after analysis.
Further, the determining the strength of the electrical signal transmission data to be detected according to the electrical signal transmission direction includes:
determining a fluctuation range corresponding to the intensity of the electric signal according to the key points searched by the transmission track and the preset intensity range of the electric signal;
checking the transmission direction of the electric signal by using a data configuration thread;
and determining a first fluctuation maximum interval in the fluctuation range in the verified electric signal transmission direction, and determining the range corresponding to the fluctuation maximum interval as the strength of the electric signal transmission data to be detected.
Further, the constructing an importance degree electric signal intensity vector based on the electric signal transmission direction and the electric signal intensity includes:
Constructing an overall error feature vector based on the strength of the electrical signal;
optimizing and searching the electric signal transmission direction to select electric signal standard data as an electric signal standard matrix;
and determining an importance degree electric signal intensity vector according to the integral error characteristic vector and the electric signal standard matrix.
Further, the building the electric signal energizing condition according to the movement mode corresponding to the electric signal transmission data to be detected by using the electric signal transmission direction before analysis and the electric signal transmission direction after analysis includes:
calculating the sum of the direction error angle allowable intervals corresponding to each transmission direction vector in each electric signal based on the analyzed electric signal transmission directions to serve as a first angle error calculation value;
calculating the sum of the direction error angle allowable intervals corresponding to each transmission direction vector in each electric signal based on the electric signal transmission direction before analysis to be used as a second angle error calculation value;
determining the importance degree of the first angle error calculated value and the second angle error calculated value as the power-on condition of each electric signal;
and combining the power-on conditions of the power supplies of each electric signal, and building the electric signal power-on conditions according to the movement mode, corresponding to the electric signal transmission data to be detected, according to the combination result of each electric signal.
Further, the determining effective electric signal detection content in the electric signal transmission data to be detected based on the electric signal power-on condition and the first power-on object includes:
determining effective electric signal detection content in the electric signal transmission data to be detected according to a preset configuration thread; wherein, the configuration thread set in advance comprises: determining the content of each electric signal, the power-on condition of which accords with the first power-on object, as first effective electric signal detection content to be processed;
if the time length of the interval time content between the first to-be-processed effective electric signal detection content is matched with the time length set in the first process, and the condition that the power supply is electrified does not exist in the interval time content and is matched with the content attribute of the second electrified object, connecting the first to-be-processed effective electric signal detection content and the interval time content to be matched into second to-be-processed effective electric signal detection content;
determining the first to-be-processed effective electric signal detection content and the second to-be-processed effective electric signal detection content, the content duration of which does not accord with the second preset duration, as the effective electric signal detection content; wherein the first powered object does not conform to the second powered object;
Wherein the determining, according to a preset configuration thread, effective electrical signal detection content in the electrical signal transmission data to be detected includes:
determining an original transmission fluctuation list of the electric signal transmission data to be detected as a sample transmission fluctuation list;
if the power supply electrifying condition corresponding to the sample transmission fluctuation list accords with the first electrifying object, judging whether fluctuation is expected or not according to the detection operation step;
if yes, setting an original transmission fluctuation set of the electric signal factors as the sample transmission fluctuation list, setting the detection operation step as a verification standard, and loading the sample transmission fluctuation list into a preset direction error angle permission interval;
if not, setting the number of the electric signal factors to zero, setting the detection operation step to a verification standard, and loading the sample transmission fluctuation list into a preset direction error angle permission interval;
wherein the determining, according to a preset configuration thread, effective electrical signal detection content in the electrical signal transmission data to be detected includes:
determining an original transmission fluctuation list of the electric signal transmission data to be detected as a sample transmission fluctuation list;
If the power supply electrifying condition corresponding to the sample transmission fluctuation list is smaller than the first electrifying object, judging whether the sample transmission fluctuation list is the same fluctuation node according to the detection operation step;
if yes, removing a preset direction error angle permission interval from the electric signal factor ending transmission fluctuation set, setting the detection operation step to be possibly the same fluctuation node, and loading the electric signal factor number into the preset direction error angle permission interval;
if not, the number of the electric signal factors is directly loaded into a preset direction error angle permission interval.
Further, after loading the number of the electric signal factors into a preset direction error angle permission interval, the method further comprises:
if the preset conditions are met, judging whether the distinction between the electric signal factor end transmission fluctuation set and the electric signal factor original transmission fluctuation set does not meet the second preset duration; the preset condition includes whether the detection operation step is a period which is possibly the same fluctuation node and the number of the electric signal factors does not accord with the first preset time, or whether the detection operation step is a period which is possibly the same fluctuation node and the power supply energizing condition corresponding to the sample transmission fluctuation list accords with the second energizing object;
If yes, determining the same fluctuation node between the original transmission fluctuation set of the electric signal factors and the transmission fluctuation set of the electric signal factors as effective electric signal detection content, setting the detection operation step as a non-same fluctuation node, and loading the sample transmission fluctuation list into a preset direction error angle permission interval;
if not, the detection operation step is directly set to be the same fluctuation node, and the sample transmission fluctuation list is loaded with a preset direction error angle permission interval.
In a second aspect, an uninterruptible power supply detection system is provided, comprising a processor and a memory in communication with each other, the processor being configured to read a computer program from the memory and execute the computer program to implement the method described above.
According to the uninterruptible power supply detection method and system, the transmission track searching is carried out on the electric signal transmission data to be detected, so that the electric signal transmission direction of the electric signal transmission data to be detected is calculated, and the integrity of calculating the electric signal transmission direction is improved. Further, the power supply electrifying conditions corresponding to the signals of each transmission fluctuation list are calculated based on the electric signal transmission direction of the electric signal transmission data to be detected, the integrity of the calculated power supply electrifying conditions is improved, the electric signal electrifying conditions corresponding to the electric signal transmission data to be detected according to the movement mode are built, the integrity of the effective electric signal detection content selected under the optimized interference is improved, and the accuracy of determining the effective electric signal detection content is improved.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered limiting the scope, and that other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.
Fig. 1 is a flowchart of an uninterruptible power supply detection method according to an embodiment of the present application.
Fig. 2 is a block diagram of an uninterruptible power supply detection device according to an embodiment of the present application.
Fig. 3 is a schematic diagram of an uninterruptible power supply detection system according to an embodiment of the present application.
Description of the embodiments
In order to better understand the technical solutions described above, the following detailed description of the technical solutions of the present application is provided through the accompanying drawings and specific embodiments, and it should be understood that the specific features of the embodiments and embodiments of the present application are detailed descriptions of the technical solutions of the present application, and not limit the technical solutions of the present application, and the technical features of the embodiments and embodiments of the present application may be combined with each other without conflict.
Referring to fig. 1, a method for detecting an uninterruptible power supply is shown, which may include the following steps 100-300.
Step 100, obtaining the transmission data of the electric signal to be detected, searching a transmission track of the transmission data of the electric signal to be detected, and calculating the transmission direction of the electric signal corresponding to the transmission data of the electric signal to be detected based on the transmission track searching result.
For example, the transmission track finding result is used for representing important transmission data which can be found in the transmission data of the electric signal to be detected.
Step 200, building the electric signal electrifying condition according to the movement mode corresponding to the electric signal transmission data to be detected according to the electric signal transmission direction.
And 300, determining effective electric signal detection content in the electric signal transmission data to be detected based on the electric signal electrifying condition and a first electrifying object.
Illustratively, the active electrical signal detection content is data characterizing the intelligent power control switch.
It can be appreciated that when the technical solutions described in the above steps 100 to 300 are executed, the integrity of calculating the transmission direction of the electrical signal is improved by performing the transmission track search on the transmission data of the electrical signal to be detected to calculate the transmission direction of the electrical signal to be detected. Further, the power supply electrifying conditions corresponding to the signals of each transmission fluctuation list are calculated based on the electric signal transmission direction of the electric signal transmission data to be detected, the integrity of the calculated power supply electrifying conditions is improved, the electric signal electrifying conditions corresponding to the electric signal transmission data to be detected according to the movement mode are built, the integrity of the effective electric signal detection content selected under the optimized interference is improved, and the accuracy of determining the effective electric signal detection content is improved.
Based on the above basis, after acquiring the transmission data of the electrical signal to be detected, the following technical scheme described in step q1 may be further included.
And q1, performing identification processing on the transmission data of the electric signal to be detected.
It can be appreciated that when the technical scheme described in the step q1 is executed, the recognition processing is performed on the transmission data of the electric signal to be detected, so that the complexity of the transmission data of the electric signal to be detected can be effectively reduced, and the workload of the subsequent steps is reduced.
In an alternative embodiment, the inventor finds that when the transmission track searching is performed on the to-be-detected electrical signal transmission data, there are multiple processing manners to cause the problem of searching errors, so that it is difficult to accurately perform the transmission track searching, and in order to improve the technical problem, the step of performing the transmission track searching on the to-be-detected electrical signal transmission data described in step 100 may specifically include a technical scheme described in the following step w 1.
And step w1, carrying out type distinguishing and splicing processing on the electric signal transmission data to be detected, and carrying out transmission track searching on a processing result.
It can be understood that when the technical scheme described in the above step w1 is executed, the problem of searching errors caused by multiple processing modes is improved when the transmission track searching is performed on the to-be-detected electrical signal transmission data, so that the transmission track searching can be accurately performed.
In an alternative embodiment, the inventor finds that when the electric signal power-on condition according to the motion mode corresponding to the electric signal transmission data to be detected is built according to the electric signal transmission direction, there is a problem that the electric signal strength vector of importance degree is inaccurate, so that it is difficult to accurately build the electric signal power-on condition, and in order to improve the technical problem, the step of building the electric signal power-on condition according to the motion mode corresponding to the electric signal transmission data to be detected described in step 200 may specifically include the following technical schemes described in step e1 and step e 2.
And e1, determining the strength of the electric signal transmission data to be detected according to the electric signal transmission direction, constructing an importance degree electric signal strength vector based on the electric signal transmission direction and the strength of the electric signal, and analyzing the electric signal transmission direction by utilizing the importance degree electric signal strength vector.
And e2, building an electric signal electrifying condition according to a movement mode, corresponding to the electric signal transmission data to be detected, by utilizing the electric signal transmission direction before analysis and the electric signal transmission direction after analysis.
It can be understood that when the technical schemes described in the steps e1 and e2 are executed, when the electric signal power-on condition according to the motion mode corresponding to the electric signal transmission data to be detected is built according to the electric signal transmission direction, the problem that the electric signal strength vector of the importance degree is inaccurate is avoided as far as possible, so that the electric signal power-on condition can be built accurately.
In an alternative embodiment, the inventor finds that, according to the electric signal transmission direction, there is a problem that the fluctuation range is inaccurate, so that it is difficult to accurately determine the strength of the electric signal transmission data to be detected, and in order to improve the technical problem, the step of determining the strength of the electric signal transmission data to be detected according to the electric signal transmission direction described in step e1 may specifically include the following technical schemes described in steps e 11-e 13.
And e11, determining a fluctuation range corresponding to the intensity of the electric signal according to the key points searched by the transmission track and the preset intensity range of the electric signal.
And e12, checking the transmission direction of the electric signal by using a data configuration thread.
And e13, determining a first fluctuation maximum interval in the fluctuation range in the verified electric signal transmission direction, and determining the range corresponding to the fluctuation maximum interval as the strength of the electric signal transmission data to be detected.
It can be appreciated that when the technical schemes described in the steps e11 to e13 are executed, the problem of inaccurate fluctuation range is avoided according to the transmission direction of the electric signal, so that the strength of the electric signal of the transmission data of the electric signal to be detected can be accurately determined.
In an alternative embodiment, the inventor finds that when constructing the importance level electric signal intensity vector based on the electric signal transmission direction and the strength of the electric signal, there is a problem that the overall error feature vector is inaccurate, so that it is difficult to accurately construct the importance level electric signal intensity vector, and in order to improve the technical problem, the step of constructing the importance level electric signal intensity vector based on the electric signal transmission direction and the strength of the electric signal described in step e1 may specifically include the following technical schemes described in steps r1 to r 3.
And r1, constructing an integral error feature vector based on the intensity of the electric signal.
And r2, optimizing and searching the transmission direction of the electric signal to select electric signal standard data as an electric signal standard matrix.
And r3, determining an importance degree electric signal intensity vector according to the integral error characteristic vector and the electric signal standard matrix.
It can be understood that when the technical scheme described in the steps r1 to r3 is executed, the problem of inaccuracy of the overall error feature vector is solved when the importance degree electric signal intensity vector is constructed based on the electric signal transmission direction and the strength of the electric signal, so that the importance degree electric signal intensity vector can be accurately constructed.
In an alternative embodiment, the inventor finds that when the direction of the electric signal transmission before analysis and the direction of the electric signal transmission after analysis are used, there is a problem that the allowable range of the direction error angle is inaccurate, so that it is difficult to accurately construct the electric signal power-on condition according to the movement mode corresponding to the electric signal transmission data to be detected, and in order to improve the technical problem, the step of constructing the electric signal power-on condition according to the movement mode corresponding to the electric signal transmission data to be detected, described in the step e2, using the direction of the electric signal transmission before analysis and the direction of the electric signal transmission after analysis, specifically may include the following technical scheme described in the following step e 21-step e 24.
And e21, calculating the sum of the direction error angle allowable intervals corresponding to each transmission direction vector in each electric signal based on the analyzed electric signal transmission directions to be used as a first angle error calculated value.
And e22, calculating the sum of the direction error angle allowable intervals corresponding to each transmission direction vector in each electric signal based on the transmission direction of the electric signal before analysis as a second angle error calculated value.
And e23, determining the importance degree of the first angle error calculated value and the second angle error calculated value as the power-on condition of each electric signal.
And e24, carrying out combination processing on the power supply electrifying conditions of each electric signal, and building the electric signal electrifying conditions according to the movement mode, corresponding to the electric signal transmission data to be detected, according to the combination result of each electric signal.
It can be understood that when the technical schemes described in the steps e21 to e24 are executed, the problem of inaccurate permission interval of the direction error angle is solved by utilizing the electric signal transmission direction before analysis and the electric signal transmission direction after analysis, so that the electric signal power-on condition according to the movement mode corresponding to the electric signal transmission data to be detected can be accurately built.
In an alternative embodiment, the inventor finds that when determining the effective electrical signal detection content in the electrical signal transmission data to be detected based on the electrical signal energization situation and the first energization object, there is a problem that the configuration thread set in advance is inaccurate in calculation, so that it is difficult to accurately determine the effective electrical signal detection content, and in order to improve the technical problem, the step of determining the effective electrical signal detection content in the electrical signal transmission data to be detected based on the electrical signal energization situation and the first energization object described in step 300 may specifically include a technical scheme described in the following step t 1.
And step t1, determining effective electric signal detection content in the electric signal transmission data to be detected according to a preset configuration thread.
It can be appreciated that when the technical scheme described in the above step t1 is executed, the problem of inaccurate calculation of the configuration thread set in advance is improved based on the electrical signal power-on condition and when the effective electrical signal detection content is determined in the electrical signal transmission data to be detected by the first power-on object, so that the effective electrical signal detection content can be accurately determined.
In an alternative embodiment, the specific calculation step of the configuration thread set in advance may include the following technical solutions described in step t11 to step t 13.
And step t11, determining the content of each electric signal, the power supply condition of which accords with the first power supply object, as the first effective electric signal detection content to be processed.
And step t12, if the duration of the interval time content between the first effective electric signal detection content to be processed is consistent with the duration set in advance, and the condition that no power supply is electrified in the interval time content is consistent with the content attribute of the second electrified object, connecting the first effective electric signal detection content to be processed and the interval time content to be processed into second effective electric signal detection content to be processed.
And step t13, determining the first effective electric signal detection content to be processed and the second effective electric signal detection content to be processed, of which the content duration does not accord with the second preset duration, as the effective electric signal detection content.
For example, the first powered object does not conform to the second powered object.
It can be appreciated that when the technical scheme described in the steps t11 to t13 is executed, the power-on condition of the power supply is continuously processed, so that the accuracy of detecting the content of the effective electric signal is improved.
In an alternative embodiment, the inventor finds that when determining the effective electrical signal detection content in the electrical signal transmission data to be detected according to the preset configuration thread, there are a plurality of problems that the judgment is disordered due to a plurality of judgment modes, so that it is difficult to accurately determine the effective power supply, and in order to improve the technical problem, the step of determining the effective electrical signal detection content in the electrical signal transmission data to be detected according to the preset configuration thread described in the step t1 may specifically include the following technical schemes described in the step y 1-the step y 4.
And step y1, determining the original transmission fluctuation list of the electric signal transmission data to be detected as a sample transmission fluctuation list.
And step y2, if the power supply electrifying condition corresponding to the sample transmission fluctuation list accords with the first electrifying object, judging whether the fluctuation is expected or not according to the detection operation step.
And step y3, if yes, setting an original transmission fluctuation set of the electric signal factors as the sample transmission fluctuation list, setting the detection operation step as a verification standard, and loading the sample transmission fluctuation list into a preset direction error angle permission interval.
Step y4, if not, setting the number of the electric signal factors to zero, setting the detection operation step to a calibration standard, and loading the sample transmission fluctuation list into a preset direction error angle permission interval
It can be understood that when the technical schemes described in the steps y1 to y4 are executed, when the effective electrical signal detection content is determined in the electrical signal transmission data to be detected according to the configuration thread set in advance, the problem that the judgment is disordered due to multiple judgment modes is solved, so that the effective power supply can be accurately determined.
In an alternative embodiment, the inventor finds that when determining the effective electrical signal detection content in the electrical signal transmission data to be detected according to the preset configuration thread, there is a problem that the sample transmission fluctuation list is inaccurate, so that it is difficult to accurately determine the effective electrical signal detection content, and in order to improve the technical problem, the step of determining the effective electrical signal detection content in the electrical signal transmission data to be detected according to the preset configuration thread described in the step t1 may specifically include the technical scheme described in the following step u 1-step u 4.
And step u1, determining the original transmission fluctuation list of the electric signal transmission data to be detected as a sample transmission fluctuation list.
And step u2, if the power supply electrifying condition corresponding to the sample transmission fluctuation list is smaller than that of the first electrifying object, judging whether the sample transmission fluctuation list is the same fluctuation node according to the detection operation step.
And step u3, if yes, removing the transmission fluctuation set of the end of the electric signal factors from the preset direction error angle allowable interval, setting the detection operation step to be possibly the same fluctuation node, and loading the number of the electric signal factors into the preset direction error angle allowable interval.
And step u4, if not, directly loading the number of the electric signal factors into a preset direction error angle permission interval.
It can be understood that when the technical solutions described in the above steps u1 to u4 are executed, when determining the effective electrical signal detection content in the electrical signal transmission data to be detected according to the configuration thread set in advance, the problem that the sample transmission fluctuation list is inaccurate is solved, so that the effective electrical signal detection content can be accurately determined.
Based on the above basis, after the number of the electric signal factors is loaded into the preset direction error angle permission interval, the technical scheme described in the following steps o 1-o 3 can be further included.
And step o1, if the preset condition is met, judging whether the distinction between the electric signal factor ending transmission fluctuation set and the electric signal factor original transmission fluctuation set does not meet the second preset duration.
For example, the preset condition includes whether the detection operation step is a period which may be the same fluctuation node and the number of the electrical signal factors does not conform to the first preset period, or whether the detection operation step is a period which may be the same fluctuation node and the power supply condition corresponding to the sample transmission fluctuation list conforms to the second power-on object.
And step o2, if so, determining the same fluctuation node between the original transmission fluctuation set of the electric signal factors and the transmission fluctuation set of the electric signal factors as effective electric signal detection content, setting the detection operation step as non-same fluctuation node, and loading the sample transmission fluctuation list into a preset direction error angle permission interval.
And step o3, if not, directly setting the detection operation step as a non-identical fluctuation node, and loading the sample transmission fluctuation list into a preset direction error angle permission interval.
It can be appreciated that in executing the technical solutions described in the above steps o 1-o 3, the accuracy of the sample transmission fluctuation list is improved by continuously judging the discrimination.
Based on the above basis, after loading the number of the electric signal factors into the preset direction error angle allowable interval, the technical scheme described in the following step a1 can be further included.
And a step a1, if the preset condition is not met, directly loading the sample transmission fluctuation list into a preset direction error angle permission interval.
For example, the preset condition includes whether the detection operation step is likely to be the same fluctuation node and the number of the electrical signal factors does not conform to the duration set by the first event, or whether the detection operation step is likely to be the same fluctuation node and the power-on condition corresponding to the sample transmission fluctuation list conforms to the second power-on object.
It can be understood that, when the technical solution described in the above step a1 is executed, the direction error angle allowable interval is adjusted when the preset condition is not met, so as to improve the accuracy of the number of the electrical signal factors.
Based on the above, the technical scheme described in the following step s 1-step s3 can be further included.
Step s1, if the added sample transmission fluctuation list does not conform to the end transmission fluctuation list of the electric signal transmission data to be detected, judging whether the detection operation step is a verification standard, whether the electric signal factor end transmission fluctuation set is smaller than the electric signal factor original transmission fluctuation set, and whether the distinction between the end transmission fluctuation list of the electric signal transmission data to be detected and the electric signal factor original transmission fluctuation set does not conform to the second preset time length.
And step s2, if yes, determining the same fluctuation node between the original transmission fluctuation set of the electric signal factors and the transmission fluctuation list of the electric signal transmission data to be detected as effective electric signal detection content.
Step s3, otherwise, determining the original transmission fluctuation list of the electric signal transmission data to be detected as a sample transmission fluctuation list again.
It will be appreciated that in executing the technical solution described in the above steps s1 to s3, the accuracy of the second preset time period is improved by judging the sample transmission fluctuation list.
Based on the above, the technical solution described in the following step d1 may also be included.
Step d1, if the added sample transmission fluctuation list accords with the ending transmission fluctuation list of the electric signal transmission data to be detected, determining the original transmission fluctuation list of the electric signal transmission data to be detected as a step behind the sample transmission fluctuation list again.
It will be appreciated that, when the technical solution described in the above step d1 is executed, the accuracy of determining the original transmission fluctuation list of the electrical signal transmission data to be detected as the sample transmission fluctuation list again is improved by ending the transmission fluctuation list.
On the basis of the above, please refer to fig. 2 in combination, there is provided an uninterruptible power supply detection apparatus 200, applied to a data processing terminal, the apparatus comprising:
the content calculation module 210 is configured to obtain electrical signal transmission data to be detected, perform transmission track searching on the electrical signal transmission data to be detected, and calculate an electrical signal transmission direction corresponding to the electrical signal transmission data to be detected based on a transmission track searching result;
the motion building module 220 is configured to build an electrical signal power-on condition according to a motion mode, where the electrical signal power-on condition corresponds to the electrical signal transmission data to be detected according to the electrical signal transmission direction;
the content determining module 230 is configured to determine, based on the electrical signal power-on condition and the first power-on object, valid electrical signal detection content in the electrical signal transmission data to be detected.
On the basis of the above, please refer to fig. 3 in combination, an uninterruptible power supply detection system 300 is shown, which includes a processor 310 and a memory 320 in communication with each other, wherein the processor 310 is configured to read and execute a computer program from the memory 320 to implement the above-mentioned method.
On the basis of the above, there is also provided a computer readable storage medium on which a computer program stored which, when run, implements the above method.
In summary, based on the above scheme, the transmission track search is performed on the electric signal transmission data to be detected, so as to calculate the electric signal transmission direction of the electric signal transmission data to be detected, and the integrity of calculating the electric signal transmission direction is improved. Further, the power supply electrifying conditions corresponding to the signals of each transmission fluctuation list are calculated based on the electric signal transmission direction of the electric signal transmission data to be detected, the integrity of the calculated power supply electrifying conditions is improved, the electric signal electrifying conditions corresponding to the electric signal transmission data to be detected according to the movement mode are built, the integrity of the effective electric signal detection content selected under the optimized interference is improved, and the accuracy of determining the effective electric signal detection content is improved.
It should be appreciated that the systems and modules thereof shown above may be implemented in a variety of ways. For example, in some embodiments, the system and its modules may be implemented in hardware, software, or a combination of software and hardware. Wherein the hardware portion may be implemented using dedicated logic; the software portions may then be stored in a memory and executed by a suitable instruction execution system, such as a microprocessor or special purpose design hardware. Those skilled in the art will appreciate that the methods and systems described above may be implemented using computer executable instructions and/or embodied in processor control code, such as provided on a carrier medium such as a magnetic disk, CD or DVD-ROM, a programmable memory such as read only memory (firmware), or a data carrier such as an optical or electronic signal carrier. The system and its modules of the present application may be implemented not only with hardware circuitry, such as very large scale integrated circuits or gate arrays, semiconductors such as logic chips, transistors, etc., or programmable hardware devices such as field programmable gate arrays, programmable logic devices, etc., but also with software, such as executed by various types of processors, and with a combination of the above hardware circuitry and software (e.g., firmware).
It should be noted that, the advantages that may be generated by different embodiments may be different, and in different embodiments, the advantages that may be generated may be any one or a combination of several of the above, or any other possible advantages that may be obtained.
While the basic concepts have been described above, it will be apparent to those skilled in the art that the foregoing detailed disclosure is by way of example only and is not intended to be limiting. Although not explicitly described herein, various modifications, improvements, and adaptations of the present application may occur to one skilled in the art. Such modifications, improvements, and modifications are intended to be suggested within this application, and are therefore within the spirit and scope of the exemplary embodiments of this application.
Meanwhile, the present application uses specific words to describe embodiments of the present application. Reference to "one embodiment," "an embodiment," and/or "some embodiments" means that a particular feature, structure, or characteristic is associated with at least one embodiment of the present application. Thus, it should be emphasized and should be appreciated that two or more references to "an embodiment" or "one embodiment" or "an alternative embodiment" in various positions in this specification are not necessarily referring to the same embodiment. Furthermore, certain features, structures, or characteristics of one or more embodiments of the present application may be combined as suitable.
Furthermore, those skilled in the art will appreciate that the various aspects of the invention are illustrated and described in the context of a number of patentable categories or circumstances, including any novel and useful procedures, machines, products, or materials, or any novel and useful modifications thereof. Accordingly, aspects of the present application may be performed entirely by hardware, entirely by software (including firmware, resident software, micro-code, etc.) or by a combination of hardware and software. The above hardware or software may be referred to as a "data block," module, "" engine, "" unit, "" component, "or" system. Furthermore, aspects of the present application may take the form of a computer product, comprising computer-readable program code, embodied in one or more computer-readable media.
The computer storage medium may contain a propagated data signal with the computer program code embodied therein, for example, on a baseband or as part of a carrier wave. The propagated signal may take on a variety of forms, including electro-magnetic, optical, etc., or any suitable combination thereof. A computer storage medium may be any computer readable medium that can communicate, propagate, or transport a program for use by or in connection with an instruction execution system, apparatus, or device. Program code located on a computer storage medium may be propagated through any suitable medium, including radio, cable, fiber optic cable, RF, or the like, or a combination of any of the foregoing.
The computer program code necessary for operation of portions of the present application may be written in any one or more programming languages, including an object oriented programming language such as Java, scala, smalltalk, eiffel, JADE, emerald, C ++, c#, vb net, python, etc., a conventional programming language such as C language, visual Basic, fortran 2003, perl, COBOL 2002, PHP, ABAP, dynamic programming languages such as Python, ruby and Groovy, or other programming languages, etc. The program code may execute entirely on the user's computer or as a stand-alone software package, partly on the user's computer and partly on a remote computer or entirely on the remote computer or server. In the latter scenario, the remote computer may be connected to the user's computer through any form of network, such as a Local Area Network (LAN) or a Wide Area Network (WAN), or the connection may be made to an external computer (for example, through the Internet), or the use of services such as software as a service (SaaS) in a cloud computing environment.
Furthermore, the order in which the elements and sequences are presented, the use of numerical letters, or other designations are used in the application and are not intended to limit the order in which the processes and methods of the application are performed unless explicitly recited in the claims. While certain presently useful inventive embodiments have been discussed in the foregoing disclosure, by way of various examples, it is to be understood that such details are merely illustrative and that the appended claims are not limited to the disclosed embodiments, but, on the contrary, are intended to cover all modifications and equivalent arrangements included within the spirit and scope of the embodiments of the present application. For example, while the system components described above may be implemented by hardware devices, they may also be implemented solely by software solutions, such as installing the described system on an existing server or mobile device.
Likewise, it should be noted that in order to simplify the presentation disclosed herein and thereby aid in understanding one or more inventive embodiments, various features are sometimes grouped together in a single embodiment, figure, or description thereof. This method of disclosure, however, is not intended to imply that more features than are presented in the claims are required for the subject application. Indeed, less than all of the features of a single embodiment disclosed above.
In some embodiments, numbers describing the components, number of attributes are used, it being understood that such numbers being used in the description of embodiments are modified in some examples by the modifier "about," approximately, "or" substantially. Unless otherwise indicated, "about," "approximately," or "substantially" indicate that the numbers allow for adaptive variation. Accordingly, in some embodiments, numerical parameters set forth in the specification and claims are approximations that may vary depending upon the desired properties sought to be obtained by the individual embodiments. In some embodiments, the numerical parameters should take into account the specified significant digits and employ a method for preserving the general number of digits. Although the numerical ranges and parameters set forth herein are approximations that may be employed in some embodiments to confirm the breadth of the range, in particular embodiments, the setting of such numerical values is as precise as possible.
Each patent, patent application publication, and other material, such as articles, books, specifications, publications, documents, etc., cited in this application is hereby incorporated by reference in its entirety. Except for application history documents that are inconsistent or conflicting with the present application, documents that are currently or later attached to this application for which the broadest scope of the claims to the present application is limited. It is noted that the descriptions, definitions, and/or terms used in the subject matter of this application are subject to such descriptions, definitions, and/or terms if they are inconsistent or conflicting with such descriptions, definitions, and/or terms.
Finally, it should be understood that the embodiments described herein are merely illustrative of the principles of the embodiments of the present application. Other variations are also possible within the scope of this application. Thus, by way of example, and not limitation, alternative configurations of embodiments of the present application may be considered in keeping with the teachings of the present application. Accordingly, embodiments of the present application are not limited to only the embodiments explicitly described and depicted herein.
The foregoing is merely exemplary of the present application and is not intended to limit the present application. Various modifications and changes may be made to the present application by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc. which are within the spirit and principles of the present application are intended to be included within the scope of the claims of the present application.
Claims (6)
1. An uninterruptible power supply detection method, comprising:
acquiring electric signal transmission data to be detected, carrying out transmission track searching on the electric signal transmission data to be detected, and calculating an electric signal transmission direction corresponding to the electric signal transmission data to be detected based on a transmission track searching result;
building an electric signal electrifying condition according to a movement mode, corresponding to the electric signal transmission data to be detected, according to the electric signal transmission direction;
determining effective electric signal detection content in the electric signal transmission data to be detected based on the electric signal electrifying condition and a first electrifying object;
the method for searching the transmission track of the transmission data of the electric signal to be detected comprises the following steps:
performing category distinction and splicing processing on the electric signal transmission data to be detected, and performing transmission track searching on a processing result;
the step of establishing the electric signal energizing condition according to the motion mode corresponding to the electric signal transmission data to be detected according to the electric signal transmission direction comprises the following steps:
determining the strength of the electric signal transmission data to be detected according to the electric signal transmission direction, constructing an importance degree electric signal strength vector based on the electric signal transmission direction and the strength of the electric signal, and analyzing the electric signal transmission direction by utilizing the importance degree electric signal strength vector;
Building an electric signal electrifying condition according to a movement mode, corresponding to the electric signal transmission data to be detected, by utilizing the electric signal transmission direction before analysis and the electric signal transmission direction after analysis;
the method for establishing the electric signal energizing condition according to the movement mode corresponding to the electric signal transmission data to be detected by utilizing the electric signal transmission direction before analysis and the electric signal transmission direction after analysis comprises the following steps:
calculating the sum of the direction error angle allowable intervals corresponding to each transmission direction vector in each electric signal based on the analyzed electric signal transmission directions to serve as a first angle error calculation value;
calculating the sum of the direction error angle allowable intervals corresponding to each transmission direction vector in each electric signal based on the electric signal transmission direction before analysis to be used as a second angle error calculation value;
determining the importance degree of the first angle error calculated value and the second angle error calculated value as the power-on condition of each electric signal;
combining the power-on conditions of the power supplies of each electric signal, and building the electric signal power-on conditions according to the movement mode, corresponding to the electric signal transmission data to be detected, according to the combination result of each electric signal;
The determining effective electric signal detection content in the electric signal transmission data to be detected based on the electric signal electrifying condition and the first electrifying object comprises the following steps:
determining effective electric signal detection content in the electric signal transmission data to be detected according to a preset configuration thread;
wherein, the configuration thread set in advance comprises:
determining the content of each electric signal, the power-on condition of which accords with the first power-on object, as first effective electric signal detection content to be processed;
if the time length of the interval time content between the first to-be-processed effective electric signal detection content is matched with the time length set in the first process, and the condition that the power supply is electrified does not exist in the interval time content and is matched with the content attribute of the second electrified object, connecting the first to-be-processed effective electric signal detection content and the interval time content to be matched into second to-be-processed effective electric signal detection content;
determining the first to-be-processed effective electric signal detection content and the second to-be-processed effective electric signal detection content, the content duration of which does not accord with the second preset duration, as the effective electric signal detection content; wherein the first powered object does not conform to the second powered object;
Wherein the determining, according to a preset configuration thread, effective electrical signal detection content in the electrical signal transmission data to be detected includes:
determining an original transmission fluctuation list of the electric signal transmission data to be detected as a sample transmission fluctuation list;
if the power supply electrifying condition corresponding to the sample transmission fluctuation list accords with the first electrifying object, judging whether fluctuation is expected or not according to the detection operation step;
if yes, setting an original transmission fluctuation set of the electric signal factors as the sample transmission fluctuation list, setting the detection operation step as a verification standard, and loading the sample transmission fluctuation list into a preset direction error angle permission interval;
if not, setting the number of the electric signal factors to zero, setting the detection operation step to a verification standard, and loading the sample transmission fluctuation list into a preset direction error angle permission interval;
wherein the determining, according to a preset configuration thread, effective electrical signal detection content in the electrical signal transmission data to be detected includes:
determining an original transmission fluctuation list of the electric signal transmission data to be detected as a sample transmission fluctuation list;
If the power supply electrifying condition corresponding to the sample transmission fluctuation list is smaller than the first electrifying object, judging whether the sample transmission fluctuation list is the same fluctuation node according to the detection operation step;
if yes, removing a preset direction error angle permission interval from the electric signal factor ending transmission fluctuation set, setting the detection operation step to be possibly the same fluctuation node, and loading the electric signal factor number into the preset direction error angle permission interval;
if not, the number of the electric signal factors is directly loaded into a preset direction error angle permission interval.
2. The method of claim 1, further comprising, after the acquiring the transmission data of the electrical signal to be detected:
and carrying out identification processing on the transmission data of the electric signal to be detected.
3. The method according to claim 1, wherein determining the strength of the electrical signal transmission data to be detected according to the electrical signal transmission direction includes:
determining a fluctuation range corresponding to the intensity of the electric signal according to the key points searched by the transmission track and the preset intensity range of the electric signal;
checking the transmission direction of the electric signal by using a data configuration thread;
And determining a first fluctuation maximum interval in the fluctuation range in the verified electric signal transmission direction, and determining the range corresponding to the fluctuation maximum interval as the strength of the electric signal transmission data to be detected.
4. The method of claim 1, wherein the constructing a importance level electrical signal strength vector based on the electrical signal transmission direction and the strength of the electrical signal comprises:
constructing an overall error feature vector based on the strength of the electrical signal;
optimizing and searching the electric signal transmission direction to select electric signal standard data as an electric signal standard matrix;
and determining an importance degree electric signal intensity vector according to the integral error characteristic vector and the electric signal standard matrix.
5. The method according to claim 1, wherein after loading the number of electrical signal factors into a previously set direction error angle allowance interval, further comprising:
if the preset conditions are met, judging whether the distinction between the electric signal factor end transmission fluctuation set and the electric signal factor original transmission fluctuation set does not meet the second preset duration; the preset condition includes whether the detection operation step is a period which is possibly the same fluctuation node and the number of the electric signal factors does not accord with the first preset time, or whether the detection operation step is a period which is possibly the same fluctuation node and the power supply energizing condition corresponding to the sample transmission fluctuation list accords with the second energizing object;
If yes, determining the same fluctuation node between the original transmission fluctuation set of the electric signal factors and the transmission fluctuation set of the electric signal factors as effective electric signal detection content, setting the detection operation step as a non-same fluctuation node, and loading the sample transmission fluctuation list into a preset direction error angle permission interval;
if not, the detection operation step is directly set to be the same fluctuation node, and the sample transmission fluctuation list is loaded with a preset direction error angle permission interval.
6. An uninterruptible power supply detection system comprising a processor and a memory in communication with each other, the processor being configured to read a computer program from the memory and execute the computer program to implement the method of any of claims 1-5.
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