The present application is based on PCT filing PCT/JP2017/027706, filed Jul. 31, 2017, which is incorporated herein by reference.
The present invention relates to an information processing apparatus and an information processing method for diagnosing time-series data using predetermined data.
A method of diagnosing diagnostic target data includes defining normal data as learning data in advance and diagnosing whether the diagnostic target data are normal on the basis of whether the learning data include a waveform similar to the waveform of the diagnostic target data. For example, sensor data acquired during normal operation of production equipment are used as learning data, and sensor data of the production equipment in operation are used as diagnostic target data, whereby an abnormality in the production equipment can be detected.
Whether the learning data include a waveform similar to the waveform of the diagnostic target data can be determined by using the dissimilarity between subsequences extracted from the learning data and the diagnostic target data. While sliding the range of extracting a subsequence from the learning data little by little, the dissimilarities between all the subsequences of the learning data and a subsequence extracted from the diagnostic target data are calculated, and the lowest dissimilarity is set as the dissimilarity of the subsequence extracted from the diagnostic target data. However, with this method, it is necessary to calculate dissimilarities for all the combinations of subsequences of the diagnostic target data and all the subsequences of the learning data, and thus it takes a long time to calculate dissimilarities due to the large calculation amount.
In contrast to the above method, the method described in Patent Literature 1 includes clustering the subsequences of learning data to generate a plurality of clusters in which the dissimilarities between subsequences are within a predetermined sampling error upper limit, and integrating the subsequences in each cluster to generate sample subsequences. By comparing the sample subsequences with the subsequences of the diagnostic target data, it is possible to reduce the calculation amount and shorten the time for dissimilarity calculation.
Patent Literature 1: PCT Patent Application Laid-open No. 2016/117086
However, Patent Literature 1 does not describe in detail a method of calculating a sampling error upper limit, which is the upper limit on the dissimilarity between subsequences to be integrated. If the sampling error upper limit is too high, the accuracy of diagnosis of diagnostic target data is degraded. If the sampling error upper limit is too low, processing takes a long time due to the large calculation amount. This causes difficulty in generating appropriate sample subsequences while keeping a balance between diagnostic accuracy and processing time.
The present invention has been made in view of the above, and an object thereof is to obtain an information processing apparatus capable of easily generating appropriate sample subsequences.
In order to solve the above-described problems and achieve the object, an aspect of the present invention includes: a data acquisition unit to acquire input data that is time-series data; a sampling error upper limit calculation unit to calculate a sampling error upper limit using data taken from the input data; and a sample subsequence generation unit to generate the sample subsequence from the learning data using the sampling error upper limit. When similar learning subsequences selected from among a plurality of learning subsequences extracted from learning data are integrated to generate a sample subsequence, the sampling error upper limit is an upper limit on dissimilarity between the learning subsequences to be integrated.
The information processing apparatus according to the present invention can achieve the effect of easily generating appropriate sample subsequences.
Hereinafter, an information processing apparatus and an information processing method according to embodiments of the present invention will be described in detail on the basis of the drawings. The present invention is not limited to the embodiments.
Embodiment
The information processing apparatus 10 has a function of diagnosing diagnostic target data D1 on the basis of whether learning data D2 (described later) include a waveform similar to the waveform of the diagnostic target data D1.
Typically, abnormal production equipment outputs sensor data including a waveform different from any waveform of sensor data acquired during normal operation of the production equipment. In this case, the sensor data acquired during normal operation of the production equipment are used as the learning data D2, and the sensor data of the production equipment in operation are used as the diagnostic target data D1, whereby the abnormality of the production equipment can be detected. By sequentially repeating the process of obtaining sensor data from the production equipment in operation and the diagnosis process of using the acquired sensor data as the diagnostic target data D1, the information processing apparatus 10 can detect an abnormality in the production equipment in real time.
The dissimilarity between the diagnostic target subsequence SS1 and the learning data D2 is indicated by the dissimilarity between the diagnostic target subsequence SS1 and the learning subsequence SS2 whose waveform is most similar to the waveform of the diagnostic target subsequence SS1 among a plurality of learning subsequences SS2 extracted from the learning data D2. In a case where the dissimilarity is indicated by the distance between subsequences, the distances between all the extracted learning subsequences SS2 and the diagnostic target subsequence SS1 are calculated, and the shortest distance is set as the dissimilarity of the diagnostic target subsequence SS1. For example, consider a case where three learning subsequences SS2 are extracted. If the distance between the diagnostic target subsequence SS1#01 and the learning subsequence SS2#01 is 30.1, the distance between the diagnostic target subsequence SS1#01 and the learning subsequence SS2#02 is 1.5, and the distance between the diagnostic target subsequence SS1#01 and the learning subsequence SS2#03 is 15.2, the dissimilarity of the diagnostic target subsequence SS1#01 is 1.5. If the dissimilarity of the diagnostic target subsequence SS1 is equal to or less than a threshold, it is determined that the learning data D2 include a waveform similar to the waveform of the diagnostic target subsequence SS1.
It takes time to calculate dissimilarities for the combinations of all the learning subsequences SS2 and all the diagnostic target subsequences SS1 due to the large calculation amount. Therefore, in the present embodiment, similar learning subsequences SS2 are integrated into a sample subsequence SS3 (described later), and the nearest neighbor search is performed using the sample subsequence SS3. Consequently, it is possible to reduce the calculation amount for calculating dissimilarities and to shorten the time required for calculating dissimilarities.
Referring again to
Referring again to
The sampling error upper limit calculation unit 102 can calculate the sampling error upper limit ε using these statistical values and a predetermined calculation formula. Assuming that reference character “k” is a positive real number, the predetermined calculation formula is mathematical expression (3) below.
ε=k(m_0+3σ_0) (3)
Mathematical expression (3) indicates that there is a linear correlation between the sampling error upper limit ε and the sum of the mean of dissimilarity m_0 and a real multiple of the standard deviation of dissimilarity σ_0, for example, three times the standard deviation of dissimilarity σ_0.
The sample subsequence generation unit 103 generates the sample subsequences SS3 using the input sampling error upper limit ε., the learning data D2, and the trial data D4. The sample subsequence SS3 is obtained by integrating similar learning subsequences SS2. In the learning data D2, the learning subsequences SS2 temporally close to each other are likely to be similar to each other, and similar subsequences are likely to appear repeatedly. Therefore, the sample subsequence generation unit 103 firstly performs the first integration process of extracting, from the learning data D2, the learning subsequences SS2 temporally close to each other and having dissimilarities equal to or less than a predetermined value, and placing the extracted learning subsequences SS2 in the same cluster CL. Then, the sample subsequence generation unit 103 performs the second integration process of integrating a plurality of clusters CL on the basis of the dissimilarity between the clusters CL.
The sample subsequence generation unit 103 sorts the list of sample subsequences SS3-1 by the mean of the sample subsequences SS3-1. Then, the sample subsequence generation unit 103 computes the distances d between subsequences using the list of rearranged sample subsequences SS3-1 in the same way as in the first integration process, and integrates the clusters CL whose sample subsequences SS3-1 are located at a distance d of ε/2 or less. The sample subsequence generation unit 103 generates the sample subsequence SS3 using the sample subsequences SS3-1 that belong to the integrated clusters CL. Specifically, the sample subsequence generation unit 103 computes, from the sample subsequences SS3-1, the mean of a plurality of values having the same index with respect to values included in sample subsequences SS3-1, and sets a subsequence including a series of means as the sample subsequence SS3. The sample subsequence generation unit 103 may compute the mean of values having the same index with respect to values included in the learning subsequences SS2 included in each cluster CL for which the sample subsequence SS3-1 has been generated, and set a subsequence including a series of means as the sample subsequence SS3. The sample subsequence generation unit 103 inputs the generated sample subsequences SS3 to the statistical value calculation unit 104, and stores them in the storage unit 105. The sample subsequence generation unit 103 may also compute the mean of the generated sample subsequences SS3, and store it in the storage unit 105 together with the sample subsequences SS3.
Referring again to
Using the mean of dissimilarity m and the standard deviation of dissimilarity 6 calculated by the statistical value calculation unit 104, the threshold calculation unit 106 calculates a threshold Th to be used by the diagnosis unit 107 to diagnose whether the learning data D2 include a waveform similar to the waveform of the diagnostic target data D1. The diagnosis unit 107 uses the threshold Th calculated by the threshold calculation unit 106 to diagnose whether the learning data D2 include a waveform similar to the waveform of the diagnostic target data D1. If the learning data D2 include a waveform similar to the waveform of the diagnostic target data D1, the diagnosis unit 107 determines that the diagnostic target data D1 are normal. If the learning data D2 do not include a waveform similar to the waveform of the diagnostic target data D1, the diagnosis unit 107 determines that the diagnostic target data D1 are abnormal.
The sample subsequence generation unit 103 generates the sample subsequences SS3 using the calculated sampling error upper limit ε and the learning data D2 (step S13). Details of the method of generating the sample subsequences SS3 will be described later. Using the generated sample subsequences SS3, the threshold calculation unit 106 calculates the threshold Th for use in diagnosis of the diagnostic target data D1 (step S14). Details of the method of calculating the threshold Th will be described later. The diagnosis unit 107 diagnoses the diagnostic target data D1 (step S15).
The series of processes illustrated in
The sampling error upper limit calculation unit 102 extracts, as the learning subsequence SS2, a piece of waveform data of the window size w from the learning data D2 of the length q (step S203). The sampling error upper limit calculation unit 102 calculates the distance d_ij between the trial subsequence SS4 and the learning subsequence SS2 (step S204). Assuming that the time series data of the trial subsequence SS4 are S[i:i+w−1](i=1, 2, 3, . . . , p−w+1) and the time-series data of the learning subsequence SS2 are T[j:j+w−1] (j=1, 2, 3, . . . , q−w+1), the distance d_ij can be computed using mathematical expression (4) below.
If the relationship d_ij<min_i is satisfied, the sampling error upper limit calculation unit 102 updates the value of the minimum distance min_i to the value of the distance d_ij (step S205). The sampling error upper limit calculation unit 102 repeats steps S203 to S205 until the evaluation of all the learning subsequences SS2 is completed while sliding the range of extracting the learning subsequence SS2 little by little in step S203.
Upon completion of the evaluation of all the learning subsequences SS2, the sampling error upper limit calculation unit 102 sets the minimum distance min_i as the dissimilarity of the current trial subsequence SS4 (step S206). The sampling error upper limit calculation unit 102 repeats steps S201 to S206 until the evaluation of all the trial subsequences SS4 is completed while sliding the range of extracting the trial subsequence SS4 little by little in step S201. Step S121 enables the sampling error upper limit calculation unit 102 to acquire the dissimilarity of each trial subsequence SS4.
Referring again to
If the distance exceeds ε/2 (step S303: No), the sample subsequence generation unit 103 fixes the cluster CL and adds it to the list of clusters CL. Further, the sample subsequence generation unit 103 places the j-th learning subsequence SS2 in a new cluster CL (step S305). The sample subsequence generation unit 103 sets i=j and j=j+1 (step S306). After performing step S304 or after performing step S306, the sample subsequence generation unit 103 determines whether the current learning subsequence SS2 is the last learning subsequence SS2 (step S307). If the current learning subsequence SS2 is not the last learning subsequence SS2 (step S307: No), the sample subsequence generation unit 103 returns to step S302 and repeats the subsequent steps. If the current learning subsequence SS2 is the last learning subsequence SS2 (step S307: Yes), the sample subsequence generation unit 103 ends the process. When the process illustrated in
The sample subsequence generation unit 103 calculates the distance d between the l-th sample subsequence SS3-1 and the m-th sample subsequence SS3-1 (step S314). The sample subsequence generation unit 103 determines whether the calculated distance d is equal to or less than ε/2 (step S315). If the distance d is equal to or less than ε/2 (step S315: Yes), the sample subsequence generation unit 103 integrates the clusters CL and deletes the m-th sample subsequence SS3-1 from the list (step S316) If the distance d exceeds ε/2 (step S315: No), the sample subsequence generation unit 103 fixes the cluster CL and generates the sample subsequence SS3 for the integrated clusters CL (step S317). The sample subsequence generation unit 103 deletes the l-th sample subsequence SS3-1 from the list and sets the minimum index in the list to l (step S318). Upon completion of step S316 or step S318, the sample subsequence generation unit 103 sets m=m+1 (step S319).
The sample subsequence generation unit 103 determines whether the current sample subsequence SS3-1 is the last sample subsequence SS3-1 (step S320). If the current sample subsequence SS3-1 is not the last sample subsequence SS3-1 (step S320: No), the sample subsequence generation unit 103 returns to step S314 and repeats the subsequent steps. If the current sample subsequence SS3-1 is the last sample subsequence SS3-1 (step S320: Yes), the sample subsequence generation unit 103 generates the sample subsequence SS3 for each of the integrated clusters CL (step S321). The sample subsequence generation unit 103 calculates the mean of the sample subsequences SS3 and sorts the sample subsequences SS3 by the mean (step S322). In this manner, the sample subsequences SS3 are generated.
The statistical value calculation unit 104 extracts the trial subsequence SS4 from the trial data D4 (step S401). The minimum distance min_i is set to infinity, the initial value (step S402). The statistical value calculation unit 104 selects one unevaluated sample subsequence SS3 from among the sample subsequences SS3 (step S403). The statistical value calculation unit 104 computes the average lower bound using the extracted trial subsequence SS4 and the selected sample subsequence SS3 (step S404). Assuming that the window size is “w” and the mean of time-series data T and the mean of time-series data S are represented by T and S with bars, respectively, the average lower bound can be expressed by mathematical expression (5) below.
[Formula 4]
√{square root over (w)}·|
The statistical value calculation unit 104 determines whether the computed average lower bound is larger than the minimum distance min_i (step S405). If the average lower bound is larger than the minimum distance min_i (step S405: Yes), the statistical value calculation unit 104 skips the subsequent steps and sets the minimum distance min_i as the dissimilarity (step S410). If the average lower bound is equal to or less than the minimum distance min_i (step S405: No), the statistical value calculation unit 104 computes the average deviation lower bound (step S406). Assuming that the standard deviations of time-series data T and S are Std(T) and Std(S), respectively, the average deviation lower bound can be expressed by mathematical expression (6) below.
[Formula 5]
√{square root over (w)}·√{square root over ((
The statistical value calculation unit 104 determines whether the computed average deviation lower bound is larger than the minimum distance min_i (step S407) If the average deviation lower bound is larger than the minimum distance min_i (step S407: Yes), the statistical value calculation unit 104 ends the process for the current sample subsequence SS3. If not all the sample subsequences SS3 have been evaluated, the statistical value calculation unit 104 returns to step S403. If the average deviation lower bound is equal to or less than the minimum distance min_i (step S407: No), the statistical value calculation unit 104 calculates the distance d_ij between the trial subsequence SS4 and the sample subsequence SS3 (step S408).
Assuming that the diagnostic target subsequence is “S” and the sample subsequence is “Tj”, the distance d_ij can be expressed by mathematical expression (7) below.
If the calculated distance d_ij is less than the minimum distance min_i, the statistical value calculation unit 104 updates the minimum distance min_i to the value of the distance d_ij (step S409). The statistical value calculation unit 104 repeats steps S403 to S409 until the evaluation of all the sample subsequences SS3 is completed. Upon completion of the evaluation of all the sample subsequences SS3, the statistical value calculation unit 104 sets the minimum distance min_i as the dissimilarity (step S410). The statistical value calculation unit 104 repeats steps S401 to S410 until the evaluation of all the trial subsequences SS4 is completed.
If it is possible to determine, by using the average lower bound and the average deviation lower bound, that the distance between subsequences is larger than the minimum distance min_i without calculating the distance between subsequences, the process of calculating the distance between subsequences can be skipped. The calculation amount for the process of calculating the average lower bound and the average deviation lower bound is smaller than that for the process of calculating the distance between subsequences, so that the nearest neighbor search process can be accelerated. It should be noted that the nearest neighbor search process illustrated in step S141 is not necessarily performed using the lower bound calculation as illustrated in
The learning data D2 may not include a waveform similar to the waveform of the diagnostic target data D1 that should be diagnosed as normal, and the diagnostic target data D1 may be diagnosed as abnormal by the information processing apparatus 10. In this case, it is desirable to add the diagnostic target data D1 diagnosed as abnormal to the learning data D2. Therefore, in response to accepting an instruction to add, to the learning data D2, dissimilar data that are the diagnostic target data D1 with respect to which the diagnosis unit 107 has determined that a waveform similar to its waveform is not included in the learning data D2, the data acquisition unit 101 adds the dissimilar data to the learning data D2.
In a case where the diagnostic target data D1 are sensor data for detecting the state of production equipment, the diagnostic target data D1 that should be diagnosed as normal are sensor data acquired when no detectable abnormality occurs in the production equipment. In this case, an instruction to add dissimilar data to the learning data D2 is a message indicating that no abnormality has occurred in the production equipment even though the diagnosis unit 107 has determined that an abnormality has occurred in the production equipment. For example, an instruction to add dissimilar data to the learning data D2 may be input to the information processing apparatus 10 through an input operation by a user of the information processing apparatus 10. Alternatively, an instruction to add dissimilar data to the learning data D2 may be generated by another system that diagnoses abnormality of the production equipment and input to the information processing apparatus 10.
After dissimilar data are added to the learning data D2, the sampling error upper limit calculation unit 102 calculates the sampling error upper limit ε using the learning data D2 including the dissimilar data. In addition, the sample subsequence generation unit 103 generates the sample subsequences SS3 by using the learning data D2 including the dissimilarity data and the sampling error upper limit ε calculated using the learning data D2 including the dissimilarity data. Further, the statistical value calculation unit 104 performs a nearest neighbor search by using the sample subsequences SS3 generated using the learning data D2 including the dissimilar data and the trial data D4 to calculate the dissimilarity between the learning data D2 and the trial data D4 and statistical values of dissimilarity. The threshold calculation unit 106 calculates the threshold Th by using the sample subsequences SS3 generated using the learning data D2 including the dissimilarity data. The diagnosis unit 107 performs the diagnosis process using the learning data D2 including the dissimilarity data. Therefore, after the diagnostic target data D1 that should be diagnosed as normal are diagnosed as abnormal, the diagnostic target data D1 are added as dissimilar data, and such data are diagnosed as normal in the next and subsequent diagnosis processes.
As described above, according to the embodiment of the present invention, when similar learning subsequences selected from among a plurality of learning subsequences SS2 extracted from the learning data D2 are integrated to generate the sample subsequence SS3, the sampling error upper limit ε is calculated using input data that are time-series data. The sampling error upper limit ε is an upper limit on the dissimilarity between the learning subsequences SS2 to be integrated. Then, using the calculated sampling error upper limit ε, the sample subsequences SS3 are generated from the learning data D2. Therefore, a user of the information processing apparatus 10 can easily set an appropriate sampling error upper limit ε that keeps a balance between diagnostic accuracy and processing time merely by inputting time-series data without trial and error, and can easily generate appropriate sample subsequences SS3. Generating appropriate sample subsequences SS3 enables high-speed diagnosis processing while maintaining diagnostic accuracy.
The configurations described in the above-mentioned embodiment indicates examples of an aspect of the present invention. The configurations can be combined with another well-known technique, and part of the configurations can be omitted or changed in a range not departing from the gist of the present invention.
10 information processing apparatus; 101 data acquisition unit; 102 sampling error upper limit calculation unit; 103 sample subsequence generation unit; 104 statistical value calculation unit; 105 storage unit; 106 threshold calculation unit; 107 diagnosis unit; D1 diagnostic target data; D2 learning data; D3 normal data; D4 trial data; SS1 diagnostic target subsequence; SS2 learning subsequence; SS3, SS3-1 sample subsequence; SS4 trial subsequence; CL cluster; ε sampling error upper limit; d distance; m, m_0 mean; σ, σ_0 standard deviation.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2017/027706 | 7/31/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/026134 | 2/7/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5301364 | Arens | Apr 1994 | A |
9779361 | Jones et al. | Oct 2017 | B2 |
10223069 | Nakamura et al. | Mar 2019 | B2 |
20160142898 | Poitau | May 2016 | A1 |
20160202164 | Trainer | Jul 2016 | A1 |
20170317701 | Demirtas | Nov 2017 | A1 |
Number | Date | Country |
---|---|---|
2007-72752 | Mar 2007 | JP |
2009-217555 | Sep 2009 | JP |
2011-192097 | Sep 2011 | JP |
5178471 | Apr 2013 | JP |
2015-230727 | Dec 2015 | JP |
2017-16522 | Jan 2017 | JP |
2011036809 | Mar 2011 | WO |
2016117086 | Jul 2016 | WO |
Entry |
---|
Wikipedia TDM page, retrieved from https://en.wikipedia.org/wiki/Time-division_multiplexing (Year: 2019). |
International Search Report dated Sep. 12, 2017 for PCT/JP2017/027706 filed on Jul. 31, 2017, 8 pages including English Translation of the International Search Report. |
Decision to Grant a Patent received for Japanese Patent Application No. 2018-508255, dated May 23, 2018, 5 pages including English Translation. |
Number | Date | Country | |
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20190310927 A1 | Oct 2019 | US |