JP6365144B2 - Time series data analysis method and time series data abnormality monitoring apparatus - Google Patents

Description

  The present invention relates to a time-series data analysis method and time-series data abnormality monitoring apparatus for analyzing time-series data using a chaos analysis technique.

  In order to detect anomalies and signs of monitoring, obtain time-series data from monitoring objects, and analyze this time-series data using the Trajectory Parallel Measure Method (TPM method) based on chaos theory. Devices have been proposed (for example, Patent Documents 1 and 2 and Non-Patent Document 1). The trajectory parallel measure method is useful as a means for detecting a stochastic process factor mixed in time series data based on determinism. For example, in Patent Document 1, the trajectory parallel measure (TPM) of time series data is sequentially determined. To detect stochastic factors in time-series data.

JP2013-211002A Japanese Patent Laid-Open No. 10-134034

Yasunari Fujimoto, Tadashi Izumi Hata, Takayoshi Tanimura, “Orbital Parallel Measure Method for Measuring Deterministic Properties of Observed Time Series Data”, Journal of Japan Fuzzy Society, 1997, Vol. 9, no. 4, pp580-588

  However, in actual time-series data, deterministic dynamical parameters in time-series data change slowly due to long-term trends such as seasonal fluctuations, and the difference between the current data and old data is embedded. If the trajectories in space intersect, there is a risk of being erroneously determined to be abnormal.

  In view of the above circumstances, an object of the present invention is to improve detection accuracy of time series data by the orbit parallel measure method.

  The time series data analysis method of the present invention that achieves the above object is a time series data analysis method for analyzing time series data by an orbital parallel measure method, wherein time series data is embedded in an n-dimensional state space, and the n One data vector is selected as a selection vector from data vectors that are time-series data embedded in the dimensional state space, the data vector in the n-dimensional state space is limited based on a logical operation, and the limited data vector A data vector embedded in the vicinity of the selection vector is selected as a neighborhood vector from the range, and the parallelism between the tangent direction of the trajectory of the data vector in the selection vector and the tangent direction of the trajectory of the data vector in the neighborhood vector is selected. And calculating the time-series data based on the calculated parallelism. .

  In addition, the time series data abnormality monitoring apparatus of the present invention that achieves the above object includes an acquisition unit that acquires time series data from an evaluation target, and an embedding unit that embeds the acquired time series data in an n-dimensional state space. Data vector selection means for selecting one data vector as a selection vector from data vectors that are time-series data embedded in the n-dimensional state space, and restricting the data vector in the n-dimensional state space based on a logical operation And a neighborhood vector selection means for selecting a data vector embedded in the vicinity of the selection vector as a neighborhood vector from the limited range of the data vector, and a tangential direction of the trajectory of the data vector in the selection vector and the neighborhood vector Tangential direction calculation means for calculating tangential direction of the trajectory in the selected vector Parallelism calculating means for calculating parallelism with the tangential direction of the trajectory in the neighborhood vector, and time-series data evaluating means for evaluating the time-series data based on the parallelism calculated by the parallelism calculating means; It is characterized by having prepared.

  According to the above invention, the detection accuracy of time series data by the orbit parallel measure method is improved.

It is the schematic of the abnormality monitoring apparatus which concerns on embodiment of this invention. It is a figure explaining the detail of the data determination process part of the abnormality monitoring apparatus which concerns on embodiment of this invention.

  A time series data analysis method, time series data abnormality monitoring apparatus, and a program for causing a computer to function as each means of the abnormality monitoring apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.

  As shown in FIG. 1, the abnormality monitoring apparatus 1 according to the embodiment of the present invention acquires time-series data from a monitoring / control target 2 and monitors and controls the monitoring / control target 2. In addition, the output device 3 is connected to the abnormality monitoring device 1, and the determination result of the monitoring / control target 2 is output to the output device 3.

  The abnormality monitoring device 1 includes a data collection unit 4, a data storage unit 5, and a data determination processing unit 6. The data collection unit 4 detects time-series data from the monitoring / control target 2 and captures the detected time-series data. The data storage unit 5 stores the time series data captured by the data collection unit 4. The data determination processing unit 6 determines whether an abnormality has occurred in the time series data stored in the data storage unit 5.

  The monitoring / control target 2 is, for example, a rotating shaft of a rotating machine system, an electric power demand amount, or a water demand amount (water distribution amount). The abnormality monitoring device 1 is transmitted with time series data such as shaft vibration sound data and vibration data, power demand time series data or water demand time series data.

  The output device 3 is, for example, a display or a printer, and outputs the analysis result of the time series data in the abnormality monitoring device 1.

  FIG. 2 is a diagram illustrating details of the data determination processing unit 6 of the abnormality monitoring apparatus 1. With reference to FIG. 2, the function of each processing unit of the data determination processing unit 6 will be described in detail.

  The data acquisition unit 7 acquires the time series data stored in the data storage unit 5 as time series data to be determined.

The embedding processing unit 8 performs embedding processing on the time-series data acquired by the data acquiring unit 7 in an n-dimensional state space (n is a positive integer). That is, from the time series data y (t) acquired by the data acquisition unit 7, the vector X _t = (y (t), y (t−τ),..., Y (t− (n−1) τ). ) (Τ is the delay time). This vector represents one point in the n-dimensional reconstruction state space R ⁿ . The dimension n and the delay time τ are values set in advance according to the target system.

The data vector selection unit 9 selects the most advanced data vector X _i representing the current time point of the data series at each time from the time series data embedded by the embedding processing unit 8. Note that the data vector selection unit 9 is not limited to selecting the most advanced data vector representing the current time point of the data series at each time described above, but one, two, before,. A data vector immediately before (n is a positive integer) may be selected.

The neighborhood vector detector 10 detects the neighborhood vector X _j in the neighborhood of the data vector X _i selected by the data vector selector 9. At this time, the neighborhood vector detection unit 10 excludes the data vector from the data vector embedded by the embedding processing unit 8 under a certain condition, and the range of the data vector from which the data vector is excluded under the certain condition (hereinafter referred to as a search). The neighborhood vector X _j is detected from the object). The restriction by a certain condition can be performed using, for example, logic calculation (logical operation) or a map.

  For example, if the set of embedded data vectors is X (t) and the selection vector selected by the data vector selection unit 9 is X (c), the search target U (c) in the sequential orbit parallel measure method is It is represented by (1).

  That is, a data vector having as its element time-series data before time c as a result of the calculation in equation (1), a data vector not on the same trajectory as X (c) is a search target U (c) for the neighborhood vector. Will be set as

The neighborhood vector detection unit 10 further creates a subset of the search target U (c), designates a new search target U ′ (c), and generates a neighborhood vector X _j from the new search target U ′ (c). Detection is performed. The new search target U ′ (c) is, for example, a function j (c, t) that determines whether X (t) is included in the search target of X (c) with respect to time c and time t. Is determined from the equation (2).

  That is, by specifying the function j (c, t), it is possible to set the search target U ′ (c) that satisfies a certain condition. Specifically, as the function j (c, t), a function whose time difference remainder is within a certain range, a function related to classification information parallel to time series data to be analyzed, or the like is used. Further, by combining these functions, more complicated condition setting can be performed.

The tangential direction calculation unit 11 calculates unit tangent vectors (tangential directions) T _i and T _j with respect to the trajectory of the selected data vector X _i and neighborhood vector X _j .

Parallelism evaluation unit 12, each data vector X _i calculated by the tangential calculation unit 11, the unit tangent vector T _i in X _j, parallelism based on T _j gamma _i (the unit tangent vector T _i and T _j Parallelism) is calculated. In the actual analysis, the average value of the parallelism is obtained in order to reduce the statistical error. Hereinafter, the calculated parallelism (or average value of parallelism) is referred to as a trajectory parallel measure (TPM).

  The parallelism determination unit 13 detects an abnormality in the time series data based on the change in the TPM calculated by the parallelism evaluation unit 12.

The current time point update unit 14 updates the current time point as a reference for selecting the data vector X _i each time the parallelism determination unit 13 evaluates the time series data in the data vector at a certain time. Do.

  The accumulated data update unit 15 deletes data with low contribution to abnormality detection from the data accumulation unit 5 (excludes it from the analysis target) in order to maintain the accumulated data in the data accumulation unit 5 at an appropriate amount. For example, the accumulated data updating unit 15 deletes data from the data accumulating unit 5 that has passed a set period. This is because old data in time series data has a low contribution to abnormality detection.

[Time-series data analysis method]
Next, a processing procedure of time series data by the abnormality monitoring apparatus 1 will be described.
<Step S1> The data collection unit 4 captures time series data. In the abnormality monitoring device 1, the data collection unit 4 detects time-series data from the monitoring / control target 2 and captures the detected time-series data.
<Step S <b>2> The data storage unit 5 stores the time series data captured by the data collection unit 4.
<Step S3> The data acquisition unit 7 acquires time series data stored in the data storage unit 5.
<Step S4> The embedding processing unit 8 performs embedding processing on the time-series data acquired by the data acquiring unit 7 in the n-dimensional state space.
<Step S5> The data vector selection unit 9 selects the most advanced data vector representing the current time point of the data series at each time from the time series data embedded by the embedding processing unit 8.
<Step S6> The neighborhood vector detection unit 10 detects a neighborhood vector in the data vector neighborhood space selected by the data vector selection unit 9. The neighborhood vector detection unit 10 sets a search target U ′ (c) in which the data vector embedded by the embedding processing unit 8 is restricted under a certain condition, and the neighborhood vector is determined from the set search target U ′ (c). Detection is performed.
<Step S7> The tangent direction of the trajectory of the time-series data after being embedded in the data vector selected by the data vector selection unit 9 and the neighborhood vector detected by the neighborhood vector detection unit 10 Is calculated. For the tangent direction of the selected data vector, for example, three consecutive data vectors such as the selected data vector and a data vector adjacent to the selected data vector are selected, and these three data vectors are identified as points. Thus, a circle passing through the three data vectors is calculated as a tangent in the selected data vector.
<Step S8> The parallelism evaluation unit 12 calculates a trajectory parallel measure (TPM) between the tangent direction of the trajectory in the data vector selected by the data vector selection unit 9 and the tangential direction of the trajectory in the neighborhood vector. The TPM becomes 0 as the tangential direction is aligned.
<Step S9> The parallelism determination unit 13 evaluates the time series data based on the time series data of the TPM calculated by the parallelism evaluation unit 12. The parallelism determination unit 13 may also perform a conventional time series data evaluation method. For example, a threshold value is set for the TPM, and the abnormality of the time series data is determined by comparing the TPM with the threshold value.
<Step S10> Each time the current time point update unit 14 evaluates the time series data in the data vector at a certain time by the parallelism determination unit 13, the current time point of the time series data embedded by the embedding processing unit 8 Update.
<Step S <b>11> The accumulated data update unit 15 deletes data that has passed a set period from the time-series data accumulated in the data accumulation unit 5.

  In the processing operations of the current time point update unit 14 and the accumulated data update unit 15, in addition to the processing in step S10 and step S11, acquisition of new time series data, definition of a time series data range to be referred to, and time series data Is embedded.

[Example 1]
The time-series data analysis method and time-series data abnormality monitoring apparatus 1 according to the embodiment of the present invention will be described in more detail with specific examples. In the description of the embodiment, a method for setting the search target U ′ (c) in the neighborhood vector detection unit 10 will be described in detail, but the analysis of the time series data is performed based on the above steps S1 to S11. (Other examples are also the same).

Example 1 neighborhood vector neighborhood vector detector 10, only the data vector in the remainder a range of time difference search target U ₁ from 'designated as (c), the specified search target U _1' (c) Is detected.

The search target U ₁ ′ (c) is set by a periodic constant m and a range constant a (0 ≦ a <m / 2) based on Expression (3). As the periodic constant m, for example, in the time series data to be analyzed, a basic period obtained by autocorrelation or an integer multiple of this basic period can be set. As the range constant a, a value less than ½ of the periodic constant m is appropriately set according to the analysis target.

That is, the data vector for each period m from the selection vector and the data vector in the range a before and after this data vector are set as the search target U ₁ ′ (c). The neighborhood vector detector 10 detects the neighborhood vector from the search target U ₁ '(c).

For example, when analyzing time-series data sampled every hour, if the periodic constant m = 24 and the range constant a = 1 are set, the search target U ₁ ′ (c) has the same time on a different day from the selected vector. And a data vector limited by one hour before and after the same time on the same day as the selected vector.

When analyzing time-series data sampled every hour, if the periodic constant m = 24 × 365.25 = 8766 and the range constant a = 24 × 30 = 720, the search target U ₁ ′ (c) is The data set is limited to the data vector of the same day in a year different from the selection vector, and the data vector of about one month before and after the same day in the year different from the selection vector.

  According to the time-series data analysis method of the first embodiment, when detecting the neighborhood vector embedded in the neighborhood of the selected vector, the search target is set to a periodic data vector (the same time zone every day, the same season every year, etc.). Can be limited.

[Example 2]
In the second embodiment, the neighborhood vector detection unit 10 searches the search target U ₂ ′ (c) only when the value of the time series data w (t) given in parallel to the time series data to be analyzed is close to the selected vector. ) And a neighborhood vector is detected from the specified search target U ₂ ′ (c).

The search target U ₂ ′ (c) is based on the equation (4), the time series data w (t) parallel to the data vector X (t) to be analyzed, the range constant a (a ≧ 0 real number), and , Is set.

That is, a data vector that is equal to the time-series data w (c) corresponding to the selected vector and a data vector in the range a before and after this data vector are set as the search target U ₂ ′ (c). Then, the neighborhood vector detection unit 10 detects a neighborhood vector from the search target U ₂ ′ (c).

For example, when analyzing time-series data sampled every hour, the time-series data w (t) given in parallel to the time-series data is temperature data (° C.), and the range constant a = 3. Then, the search target U ₂ ′ (c) is a set restricted to data vectors within the same temperature ± 3 ° C. as the selected vector.

  According to the time-series data analysis method of the second embodiment, using the time-series data (for example, temperature) given to the selection vector, the search target of the neighborhood vector is set to a condition (for example, temperature) that is close to the selection vector. Can be limited to data vectors of

[Example 3]
In the third embodiment, the neighborhood vector detection unit 10 designates only the classification information I (t) given in parallel to the time-series data to be analyzed that is close to the selected vector as the search target U ₃ ′ (c). Then, a neighborhood vector is detected from the designated search target U ₃ ′ (c).

The search target U ₃ ′ (c) is set by the classification information I (t) parallel to the analysis target data vector X (t) based on the equation (5).

That is, a data vector having classification information I (t) equal to the classification information I (c) corresponding to the selected vector is set as the search target U ₃ ′ (c). Then, the neighborhood vector detection unit 10 detects a neighborhood vector from the search target U ₃ ′ (c).

For example, when analyzing time-series data sampled every hour, by specifying classification information I (t) such as holidays = 0, weekdays = 1, and when the selection vector is a holiday, When the data vector is set as the search target U ₃ ′ (c) and the selection vector is a weekday, the weekday data vector is set as the search target U ₃ ′ (c).

  As the classification information I (t), not only predetermined information can be set in advance, but also time series data can be clustered by machine learning or the like and set according to the result of clustering.

  According to the time-series data analysis method of the third embodiment, for example, facility power demand data and the like can be combined with weekday / holiday classification information I (t) to evaluate only on weekdays and only on holidays. it can. Further, based on the result of clustering the target time-series data, it is possible to perform evaluation by limiting only to data vectors belonging to the same cluster.

[Example 4]
In the fourth embodiment, the neighborhood vector detection unit 10 searches the data vector in which the remainder of the time series data w (t) given in parallel to the time series data to be analyzed is within a certain range as the search target U ₄ ′ (c ) And a neighborhood vector is detected from the designated search target U ₄ ′ (c).

The search target U ₄ ′ (c) is based on the equation (6), the time series data w (t) parallel to the data vector X (t) to be analyzed, the periodic constant m, and the range constant a (0 ≦ 0). a <m / 2).

That is, the time-series data w (c) corresponding to the selected data vector X (c) and the time-series data w (t) corresponding to the data vector X (t) match or fall within the range of a before and after a. The data vector X (t) is set as the search target U ₄ ′ (c). The neighborhood vector detector 10 detects a neighborhood vector from the search target U ₄ '(c).

For example, when analyzing time-series data sampled every hour, if classification information such as holiday = 0 and weekdays = 1 is specified, the classification is suddenly changed at the transition between weekdays and holidays. There is a risk that a false detection occurs at the boundary between a holiday and a holiday. Therefore, as time series data w (t), weekdays before holidays 19: 00 = 1, 20: 00 = 2, 21: 00 = 3, 22: 00 = 4, 23: 00 = 5, holidays = 6, weekdays after holidays Set time series data w (t) such as 0 o'clock = 7, 1 o'clock = 8, 2 o'clock = 9, 3 o'clock = 10, 4 o'clock = 11, and other weekdays = 0, and a periodic constant m = 12, By setting the range constant a = 3, the search target U ₄ ′ (c), which is a set in which the boundary between holidays and weekdays is relaxed, is set.

According to the data vector analysis method of the fourth embodiment, when a data vector is restricted by a periodically changing classification, such as a change of a weekday / weekday to a holiday / a change of a holiday / holiday to a weekday, an adjacent item It is possible to perform the evaluation up to the search target U ₄ ′ (c).

  According to the time-series data analysis method and the time-series data analysis apparatus of the present invention as described above, the time-series data can be obtained by excluding the data vector from the selection range under a certain condition when searching for neighboring vectors in the embedded space. It is possible to improve the detection accuracy of the stochastic process factors mixed in the.

  In other words, in the detection of the neighborhood vector, by limiting the data vector to be searched, the data vector embedded in the neighborhood of the selected vector due to an external factor can be excluded. As a result, the factor that the TPM based on the stochastic process factor rises erroneously is reduced, and the detection accuracy of the TPM based on the stochastic process factor is improved.

  Note that the abnormality monitoring device 1 and the data determination processing unit 6 of the abnormality monitoring device according to the embodiment of the present invention configured as described above have a predetermined program on a computer including, for example, a ROM, a RAM, and a CPU. It is realized by being read and the CPU executing the program. Each means may be configured by executing a predetermined program on a computer, or at least a part of these processing contents may be realized by hardware.

  When the processing means in the device and the processing unit is realized by a computer, the processing contents of the functions that the device and the processing unit should have are described by a program. Then, by executing this program on the computer, the processing means in the apparatus and the processing unit is realized on the computer.

  The program describing the processing contents can be recorded on a computer-readable recording medium. Examples of the computer-readable recording medium include a recording medium such as a magnetic recording device, an optical disk, a magneto-optical recording medium, and a semiconductor memory. Specifically, for example, a magnetic recording device such as a hard disk device, a flexible disk, a magnetic tape, a DVD (Digital Versatile Disc), a DVD-RAM (Random Access Memory), a CD-ROM (Compact Disc Read Only Memory), a CD An optical disk such as -R (Recordable) / RW (ReWritable), a magneto-optical recording medium such as MO (Magneto Optical disc), or a semiconductor memory such as a flash memory can be used.

  This program is distributed by, for example, distributing portable recording media such as DVDs and CD-ROMs on which the program is recorded. Furthermore, it is good also as a structure which distribute | circulates this program by transferring this program from a server computer to another computer via a network.

  The time-series data analysis method and time-series data abnormality monitoring apparatus of the present invention are not limited to the uses described in the embodiments, and can be used for analysis of various time-series data. For example, in addition to power demand and water demand, it can be used for analysis of time-series data on the amount of power generated by a solar power generation device, time-series data on production equipment and rotating equipment in a power system, and the like.

  In the embodiment, the time series data is analyzed by the sequential orbit parallel measure method. However, the time series data analysis method of the present invention is applied to the analysis of the orbit parallel measure method described in Non-Patent Document 1. You can also.

  In the time series data abnormality monitoring apparatus of the present invention, a threshold can be set for an increase in TPM that captures the transition of the dynamic system, and a warning is output when the threshold is exceeded.

DESCRIPTION OF SYMBOLS 1 ... Abnormality monitoring apparatus 2 ... Monitoring / control object 3 ... Output apparatus 4 ... Data collection part 5 ... Data storage part 6 ... Data determination processing part 7 ... Data acquisition part (acquisition means)
8 ... Embedding processing unit (embedding means)
9: Data vector selection section (data vector selection means)
10: Neighborhood vector detection unit (neighboring vector selection means)
11 ... Tangent direction calculation unit (tangential direction calculation means)
12 ... Parallelism evaluation unit (parallelism calculation means)
13 ... Parallelism determination unit (time-series data evaluation means)
14 ... Current time point update unit 15 ... Accumulated data update unit

Claims (9)

A time series data analysis method for analyzing time series data executed by a computer by an orbital parallel measure method,
The computer is
And write non-step embedded in the n-dimensional state space time series data,
Selecting one of the data vector as a selected vector from the data vectors are time series data that is embedded in the n-dimensional state space,
By a logical operation, the data vector of the n-dimensional state space is adjacent to the data vector separated from the selected vector by an integral multiple of the basic period of the time-series data to be analyzed within a predetermined range before or after the data vector. a step of limiting the data vector, the range of the limited data vector, selects a data vector that is embedded in the vicinity of the selected vector as a neighborhood vector fit,
Calculating a tangential trajectory data vector in the selected vector, the parallelism between the tangent of the trajectory of the data vectors in the neighborhood vector,
A step of analyzing the time-series data based on the calculated parallelism, and a method of analyzing the time-series data. A time series data analysis method for analyzing time series data executed by a computer by an orbital parallel measure method,
The computer is
And write non-step embedded in the n-dimensional state space time series data,
Selecting one of the data vector as a selected vector from the data vectors are time series data that is embedded in the n-dimensional state space,
The data vector of the n-dimensional state space is limited based on time series data given in parallel to the data vector by a logical operation, and is embedded in the vicinity of the selection vector from the range of the limited data vector. selecting as a neighboring vector data vector,
Calculating a tangential trajectory data vector in the selected vector, the parallelism between the tangent of the trajectory of the data vectors in the neighborhood vector,
A step of analyzing the time-series data based on the calculated parallelism, and a method of analyzing the time-series data. A time series data analysis method for analyzing time series data executed by a computer by an orbital parallel measure method,
The computer is
And write non-step embedded in the n-dimensional state space time series data,
Selecting one of the data vector as a selected vector from the data vectors are time series data that is embedded in the n-dimensional state space,
The data vector of the n-dimensional state space is limited based on classification information given in parallel to the data vector by a logical operation, and is embedded in the vicinity of the selected vector from the range of the limited data vector. selecting a neighborhood vector data vector,
Calculating a tangential trajectory data vector in the selected vector, the parallelism between the tangent of the trajectory of the data vectors in the neighborhood vector,
A step of analyzing the time-series data based on the calculated parallelism, and a method of analyzing the time-series data. A time series data analysis method for analyzing time series data executed by a computer by an orbital parallel measure method,
The computer is
And write non-step embedded in the n-dimensional state space time series data,
Selecting one of the data vector as a selected vector from the data vectors are time series data that is embedded in the n-dimensional state space,
The time-series data given in parallel to the data vector by the logical operation of the data vector of the n-dimensional state space corresponds to the data vector corresponding to the time-series data corresponding to the selection vector or the selection vector limit from the time series data to the data vector is within a predetermined range, the steps of the range of the limited data vector, selects a data vector that is embedded in the vicinity of the selected vector as a neighborhood vector,
Calculating a tangential trajectory data vector in the selected vector, the parallelism between the tangent of the trajectory of the data vectors in the neighborhood vector,
A step of analyzing the time-series data based on the calculated parallelism, and a method of analyzing the time-series data. An acquisition means for acquiring time-series data from an evaluation target;
Embedding means for embedding the acquired time series data in the n-dimensional state space;
Data vector selection means for selecting one data vector as a selection vector from data vectors that are time-series data embedded in the n-dimensional state space;
By a logical operation, the data vector of the n-dimensional state space is adjacent to the data vector separated from the selected vector by an integral multiple of the basic period of the time-series data to be analyzed within a predetermined range before or after the data vector. A neighborhood vector selection means for restricting to a matching data vector, and selecting a data vector embedded in the vicinity of the selection vector as a neighborhood vector from the range of the restricted data vector;
Tangential direction calculation means for calculating the tangential direction of the trajectory of the data vector in the selection vector and the neighborhood vector;
Parallelism calculating means for calculating parallelism between the tangential direction of the trajectory in the selected vector and the tangential direction of the trajectory in the neighboring vector;
An abnormality monitoring device for time-series data, comprising: time-series data evaluation means for evaluating the time-series data based on the parallelism calculated by the parallelism calculation means. An acquisition means for acquiring time-series data from an evaluation target;
Embedding means for embedding the acquired time series data in the n-dimensional state space;
Data vector selection means for selecting one data vector as a selection vector from data vectors that are time-series data embedded in the n-dimensional state space;
The data vector of the n-dimensional state space is limited based on time series data given in parallel to the data vector by a logical operation, and is embedded in the vicinity of the selection vector from the range of the limited data vector. A neighborhood vector selection means for selecting the selected data vector as a neighborhood vector;
Tangential direction calculation means for calculating the tangential direction of the trajectory of the data vector in the selection vector and the neighborhood vector;
Parallelism calculating means for calculating parallelism between the tangential direction of the trajectory in the selected vector and the tangential direction of the trajectory in the neighboring vector;
An abnormality monitoring device for time-series data, comprising: time-series data evaluation means for evaluating the time-series data based on the parallelism calculated by the parallelism calculation means. An acquisition means for acquiring time-series data from an evaluation target;
Embedding means for embedding the acquired time series data in the n-dimensional state space;
Data vector selection means for selecting one data vector as a selection vector from data vectors that are time-series data embedded in the n-dimensional state space;
The data vector of the n-dimensional state space is limited based on classification information given in parallel to the data vector by a logical operation, and is embedded in the vicinity of the selected vector from the range of the limited data vector. Neighborhood vector selection means for selecting a data vector as a neighborhood vector;
Tangential direction calculation means for calculating the tangential direction of the trajectory of the data vector in the selection vector and the neighborhood vector;
Parallelism calculating means for calculating parallelism between the tangential direction of the trajectory in the selected vector and the tangential direction of the trajectory in the neighboring vector;
An abnormality monitoring device for time-series data, comprising: time-series data evaluation means for evaluating the time-series data based on the parallelism calculated by the parallelism calculation means. An acquisition means for acquiring time-series data from an evaluation target;
Embedding means for embedding the acquired time series data in the n-dimensional state space;
Data vector selection means for selecting one data vector as a selection vector from data vectors that are time-series data embedded in the n-dimensional state space;
The time-series data given in parallel to the data vector by the logical operation of the data vector of the n-dimensional state space corresponds to the data vector corresponding to the time-series data corresponding to the selection vector or the selection vector Neighborhood vector selection means for restricting to a data vector within a predetermined range from time series data, and selecting a data vector embedded in the vicinity of the selection vector as a neighborhood vector from the range of the restricted data vector;
Tangential direction calculation means for calculating the tangential direction of the trajectory of the data vector in the selection vector and the neighborhood vector;
Parallelism calculating means for calculating parallelism between the tangential direction of the trajectory in the selected vector and the tangential direction of the trajectory in the neighboring vector;
An abnormality monitoring device for time-series data, comprising: time-series data evaluation means for evaluating the time-series data based on the parallelism calculated by the parallelism calculation means.   The program for functioning a computer as each means of the abnormality monitoring apparatus of the time series data of any one of Claims 5-8.

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