WO1997014105A1 - An expert system for testing industrial processes and determining sensor status - Google Patents
An expert system for testing industrial processes and determining sensor status Download PDFInfo
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- WO1997014105A1 WO1997014105A1 PCT/US1996/016092 US9616092W WO9714105A1 WO 1997014105 A1 WO1997014105 A1 WO 1997014105A1 US 9616092 W US9616092 W US 9616092W WO 9714105 A1 WO9714105 A1 WO 9714105A1
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
- G05B19/418—Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS], computer integrated manufacturing [CIM]
- G05B19/4184—Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS], computer integrated manufacturing [CIM] characterised by fault tolerance, reliability of production system
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B2219/00—Program-control systems
- G05B2219/30—Nc systems
- G05B2219/34—Director, elements to supervisory
- G05B2219/34048—Fourier transformation, analysis, fft
-
- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B2219/00—Program-control systems
- G05B2219/30—Nc systems
- G05B2219/37—Measurements
- G05B2219/37325—Multisensor integration, fusion, redundant
-
- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B2219/00—Program-control systems
- G05B2219/30—Nc systems
- G05B2219/37—Measurements
- G05B2219/37326—Automatic configuration of multisensor, adaptive, active sensing
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P90/00—Enabling technologies with a potential contribution to greenhouse gas [GHG] emissions mitigation
- Y02P90/02—Total factory control, e.g. smart factories, flexible manufacturing systems [FMS] or integrated manufacturing systems [IMS]
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S706/00—Data processing: artificial intelligence
- Y10S706/902—Application using ai with detail of the ai system
- Y10S706/903—Control
- Y10S706/906—Process plant
Definitions
- the present invention is concerned generally with an expert system and method for reliably monitoring industrial processes using a set of sensors. More particularly, the invention is concerned with an expert system and method for establishing a network of industrial sensors for parallel monitoring of industrial devices.
- the expert system includes a network of highly sensitive pattern recognition modules for automated parameter surveillance using a sequential probability ratio test.
- SPRT Sequential Probability Ratio Test
- Two features of the SPRT technique make it attractive for parameter surveillance and fault detection: (1) early annunciation ofthe onset of a disturbance in noisy process variables, and (2) the SPRT technique has user-specifiable false-alarm and missed-alarm probabilities.
- One important drawback of the SPRT technique that has limited its adaptation to a broader range of applications is the fact that its mathematical formalism is founded upon an assumption that the signals it is monitoring are purely Gaussian, independent (white noise) random variables. It is therefore an object ofthe invention to provide an improved method and system for continuous evaluation and/or modification of industrial processes and/or sensors monitoring the processes.
- An expert system has been developed that continuously monitors digitized signals from a set of sensors which are measuring a variety of physical variables (e.g.. temperature, pressure, radiation level, vibration level, etc.).
- the expert system employs a sensitive pattern-recognition technique, the sequential probability ratio test ("SPRT") technique for early annunciation of sensor operability degradation.
- SPRT sequential probability ratio test
- a SPRT module can monitor output from two identical sensors and deterrnine if the statistical quality ofthe noise associated with either signal begins to change.
- SPRT module applied to pairs of sensors monitoring the same physical process on the respective devices will provide sensitive annunciation of any physical disturbance affecting one of the devices.
- each industrial device is equipped with multiple, redundant sensors
- the expert system provides not only early annunciation of the onset of a disturbance, but also can distinguish between equipment degradation and degradation of its sensors.
- the expert system determines that the cause of the discrepant signals is due to a degraded sensor, it can identify the specific sensor that has failed.
- the expert system In a simple generic application involving a single industrial device equipped with triply-redundant sensors for measurement of two physical variables, the expert system first identifies the minimum unique set of signal pairs that will be needed for the network of interacting SPRT modules. Further, the system can operate using two industrial devices working in parallel (e.g., jet engines, propeller drive motors on a ship, turbomachinery in an industrial plant, etc.). Again the expert system identifies the pair-wise sensor combinations that it uses subsequently in building the conditional branching hierarchy for the SPRT-module configuration.
- FIGURE 1 illustrates the specified output of a pump's power output over time
- FIGURE 2 shows a Fourier composite curve generated using the pump spectral output of FIG. 1;
- FIGURE 3 illustrates a residual function characteristic ofthe difference between FIGS. 1 and 2;
- FIGURE 4A shows a periodogram ofthe spectral data of FIG. 1 and FIG. 4B shows a periodogram of the residual function of FIG. 3;
- FIGURE 5 A illustrates a noise histogram for the pump power output of FIG. 1 and FIG. 5B illustrates a noise histogram for the residual function of FIG. 3;
- FIGURE 6A shows an unmodified delayed neutron detector signal from a first sensor and FIG. 6B is for a second neutron sensor;
- FIG. 6C shows a difference function characteristic ofthe difference between data in FIG. 6A and 6B and
- FIG. 6D shows the data output from a SPRT analysis with alarm conditions indicated by the diamond symbols;
- FIGURE 7A illustrates an unmodified delayed neutron detector signal from a first sensor and FIG. 7B is for a second neutron sensor;
- FIG. 7C shows a difference function for the difference between the data of FIG. 7A and 7B and
- FIG. 7D shows the result of using the instant invention to modify the difference function to provide data free of serially correlated noise to the SPRT analysis to generate alarm information and with alarm conditions indicated by the diamond signals;
- FIGURE 8 A and B illustrate a schematic functional flow diagram of the invention with FIG. 8 A showing a first phase of the method of the invention and FIG. 8B shows the application of the method ofthe invention;
- FIGURE 9 illustrates a plurality of sensors monitoring two physical variables of a single industrial device
- FIGURE 10 illustrates triply-redundant sensors monitoring two physical variables for two industrial devices
- FIGURE 11 illustrates an overall system structure employing the sensor array of FIG. 10;
- FIGURE 12 illustrates triply-redundant sensors monitoring one physical variable for three industrial devices
- FIGURE 13 illustrates a logic diagram and conditional branching structure for an equipment surveillance module
- FIGURE 14 illustrates a system of industrial devices and development of SPRT modules for monitoring the system.
- signals from industrial process sensors can be used to annunciate, modify or terminate degrading or anomalous processes.
- the sensor signals are manipulated to provide input data to a statistical analysis technique, such as a process entitled Sequential Probability Ratio Test ("SPRT").
- SPRT Sequential Probability Ratio Test
- a dual transformation method is performed, insofar as it entails both a frequency-domain transformation ofthe original time-series data and a subsequent time-domain transformation ofthe resultant data.
- the data stream that passes through the dual frequency-domain, time-domain transformation is then processed with the SPRT procedure, which uses a log-likelihood ratio test.
- a computer software package, Appendix A is also attached hereto covering the SPRT procedure and its implementation in the context of, and modified by, the instant invention.
- successive data observations are performed on a discrete process Y, which represents a comparison of the stochastic components of physical processes monitored by a sensor, and most preferably pairs of sensors.
- the Y function is obtained by simply differencing the digitized signals from two respective sensors. Let y k represent a sample from the process Y at time t k During normal operation with an undegraded physical system and with sensors that are functioning within specifications the y k should be normally distributed with mean of zero. Note that if the two signals being compared do not have the same nominal mean values (due, for example, to differences in calibration), then the input signals will be pre-normalized to the same nominal mean values during initial operation.
- the system's purpose is to declare a first system, a second system, etc., degraded if the drift in Y is sufficiently large that the sequence of observations appears to be distributed about a mean +M or -M, where M is our pre-assigned system-disturbance magnitude.
- H H
- Y is drawn from a Gaussian probability distribution function (“PDF") with mean
- H 2 Y is drawn from a Gaussian PDF with mean 0 and variance ⁇ 2 .
- ⁇ probability 1 - ⁇
- ⁇ represent the error (misidentification) probabilities.
- H) is the distribution ofthe random variable y.
- Wald's theory operates as follows: Continue sampling as long as A ⁇ l n ⁇ B. Stop sampling and decide H j as soon as 1 manually ⁇ B, and stop sampling and decide H 2 as soon as ⁇ A.
- the acceptance thresholds are related to the error (misidentification) probabilities by the following expressions:
- the (user specified) value of ⁇ is the probability of accepting H, when H 2 is true (false alarm probability), ⁇ is the probability of accepting H 2 when H, is true (missed alarm probability). If we can assume that the random variable y k is normally distributed, then the likelihood that H, is true (i.e.. mean M, variance ⁇ 2 ) is given by:
- Auto-correlated noise is a known form of noise wherein pairs of correlation coefficients describe the time series correlation of various data signal values along the time series of data. That is, the data V ⁇ , U2, . . ., U n have correlation coefficients (Uj, U2), (U2, U3), . . ., (U n _ 1, U n ) and likewise have correlation coefficients (Ui, U3) (U2, U4), etc. If these data are auto-correlated, at least some of the coefficients are non-zero.
- Markov dependent noise is a very special form of correlation between past and future data signals.
- serially- correlated data signals from an industrial process can be rendered amenable to the SPRT testing methodology described hereinbefore. This is preferably done by performing a frequency-domain transformation ofthe original difference function Y. A particularly preferred method of such a frequency transformation is accomplished by generating a Fourier series using a set of highest "1" number of modes. Other procedures for rendering the data amenable to SPRT methods includes, for example, auto regressive techniques, which can accomplish substantially similar results described herein for Fourier analysis. In the preferred approach of Fourier analysis to determine the "1" highest modes (see FIG. 8A):
- ⁇ « 7 + ⁇ m»l & ⁇ cos ⁇ - l + b - sin ⁇ * (12)
- a/2 is the mean value of the series
- 2 ⁇ and b m are the Fourier coefficients corresponding to the Fourier frequency ⁇ m
- N is the total number of observations.
- the reconstruction of X uses the general form of Eqn. (12), where the coefficients and frequencies employed are those associated with the eight highest PSD values. This yields a Fourier composite curve (see end of flowchart in FIG. 8 A) with essentially the same correlation structure and the same mean as Y t . Finally, we generate a discrete residual function R, by differencing corresponding values of Y, and X,. This residual function, which is substantially devoid of serially correlated contamination, is then processed with the SPRT technique described hereinbefore.
- EBR-II reactor coolant pumps (RCPs) and delayed neutron (DN) monitoring systems were tested continuously to demonstrate the power and utility ofthe invention. All data used in this investigation were recorded during full-power, steady state operation at EBR-II. The data have been digitized at a 2-per-second sampling rate using 2 14 (16,384) observations for each signal of interest.
- FIGS. 1-3 illustrate data associated with the preferred spectral filtering approach as applied to the EBR-II primary pump power signal, which measures the power (in kW) needed to operate the pump.
- FIG. 8 The basic procedure of FIG. 8 was then followed in the analysis.
- FIG. 1 shows 136 minutes of the original signal as it was digitized at the 2-Hz sampling rate.
- FIG. 2 shows a Fourier composite constructed from the eight most prominent harmonics identified in the original signal.
- the residual function obtained by subtracting the Fourier composite curve from the raw data, is shown in FIG. 3.
- Periodograms of the raw signal and the residual function have been computed and are plotted in FIG. 4. Note the presence of eight depressions in the periodogram ofthe residual function in FIG. 4B, corresponding to the most prominent periodicities in the original, unfiltered data.
- Histograms computed from the raw signal and the residual function are plotted in FIG. 5. For each histogram shown we have superimposed a Gaussian curve (solid line) computed from a purely Gaussian distribution having the same mean and variance. Comparison of FIG. 5 A and 5B provide a clear demonstration ofthe effectiveness ofthe spectral filtering in reducing asymmetry in the histogram. Quantitatively, this decreased asymmetry is reflected in a decrease in the skewness (or third moment ofthe noise) from 0.15 (raw signal) to 0.10 (residual function).
- l( ⁇ k ) is the PSD function (see Eq. 14) at discrete frequencies ⁇ k , and 1(L) signifies the largest PSD ordinate identified in the stationary time series.
- the Kappa statistic is the ratio of the largest PSD ordinate for the signal to the average ordinate for a PSD computed from a signal contaminated with pure white noise.
- the power signal for the pump used in the present example has a K of 1940 and 68.7 for the raw signal and the residual function, respectively.
- the spectral filtering procedure has reduced the degree of nonwhiteness in the signal by a factor of 28.
- the residual function is still not a pure white noise process.
- the 95% critical value for Kappa for a time series with 2 14 observations is 12.6. This means that only for computed Kappa statistics lower than 12.6 could we accept the null hypothesis that the signal is contaminated by pure white noise.
- the complete SPRT technique integrates the spectral decomposition and filtering process steps described hereinbefore with the known SPRT binary hypothesis procedure.
- the process can be illustratively demonstrated by application of the SPRT technique to two redundant delayed neutron detectors (designated DND A and DND B) whose signals were archived during long-term normal (i.e.. undegraded) operation with a steady DN source in EBR-II.
- DND A and DND B two redundant delayed neutron detectors
- ⁇ false alarm rate
- ⁇ provides an upper bound to the probability (per observation interval) of obtaining a false alarm--i.e., obtaining a "data disturbance” annunciation when, in fact, the signals under surveillance are undegraded.
- FIGS. 6 and 7 illustrate sequences of SPRT results for raw DND signals and for spectrally-whitened DND signals, respectively.
- FIGS. 6A and 6B, and 7A and 7B, respectively are shown the DN signals from detectors DND- A and DND-B.
- the steady-state values ofthe signals have been normalized to zero.
- FIGS. 6C and 7C in each figure show pointwise differences of signals DND-A and DND-B. It is this difference function that is input to the SPRT technique. Output from the SPRT method is shown for a 250-second segment in FIGS. 6D and 7D.
- FIGS. 6D and 7D Interpretation of the SPRT output in FIGS. 6D and 7D is as follows: When the SPRT index reaches a lower threshold, A, one can conclude with a 99% confidence factor that there is no degradation in the sensors. For this demonstration A is equal to 4.60, which corresponds to false-alarm and missed-alarm probabilities of 0.01. As FIGS. 6D and 7D illustrate, each time the SPRT output data reaches A, it is reset to zero and the surveillance continues.
- any triggers of the positive threshold are signified with diamond symbols in FIGS. 6D and 7D. In this case, since we can certify that the sensors were functioning properly during the time period our signals were being archived, any triggers of the positive threshold are false alarms.
- the data output shown in FIG. 7D employs the complete SPRT technique shown schematically in FIG. 8.
- we obtain an asymptotic cumulative false-alarm frequency of 0.009142 with a variance of 0.000036. This is less than (i.e.. more conservative than) the design value of ⁇ .01, as desired.
- each single sensor can provide a real signal characteristic of an ongoing process and a record artificial signal can be generated to allow formation of a difference function.
- Techniques such as an auto regressive moving average (ARMA) methodology can be used to provide the appropriate signal, such as a DC level signal, a cyclic signal or other predictable signal.
- ARMA auto regressive moving average
- Such an ARMA method is a well-known procedure for generating artificial signal values, and this method can even be used to learn the particular cyclic nature of a process being monitored enabling construction ofthe artificial signal.
- the two signals one a real sensor signal and the other an artificial signal, can thus be used in the same manner as described hereinbefore for two (paired) real sensor signals.
- the difference function Y is then formed, transformations performed and a residual function is determined which is free of serially correlated noise.
- filtration of serial correlation can be accomplished by using the ARMA method.
- This ARMA technique estimates the specific correlation structure existing between sensor points of an industrial process and utilizes this correlation estimate to effectively filter the data sample being evaluated.
- a technique has therefore been devised which integrates frequency-domain filtering with sequential testing methodology to provide a solution to a problem that is endemic to industrial signal surveillance.
- the subject invention particularly allows sensing slow degradation that evolves over a long time period (gradual decalibration bias in a sensor, appearance of a new radiation source in the presence of a noisy background signal, wear out or buildup of a radial rub in rotating machinery, etc.).
- the system thus can alert the operator of the incipience or onset of the disturbance long before it would be apparent to visual inspection of strip chart or CRT signal traces, and well before conventional threshold limit checks would be tripped. This permits the operator to terminate, modify or avoid events that might otherwise challenge technical specification guidelines or availability goals.
- the operator can schedule corrective actions (sensor replacement or recalibration; component adjustment, alignment, or rebalancing; etc.) to be performed during a scheduled system outage.
- the invention makes it possible to apply formal reliability analysis methods to an overall system comprising a network of interacting SPRT modules that are simultaneously monitoring a variety of plan variables.
- This amenability to formal reliability analysis methodology will, for example, greatly enhance the process of granting approval for nuclear-plant applications of the invention, a system that can potentially save a utility millions of dollars per year per reactor.
- an artificial-intelligence based expert system 100 (see FIG. 12) has been developed for automatically configuring a set of sensors A, B, C and D to perform signal validation and sensor-operability surveillance in industrial applications that require high reliability, high sensitivity annunciation of degraded sensors, discrepant signals, or the onset of process anomalies.
- This expert system 100 comprises an interconnected network of high sensitivity pattern-recognition modules 102 (see FIGS. 9-11).
- the modules 102 embody the SPRT methodology described hereinbefore for automated parameter surveillance.
- the SPRT method examines the noise characteristics of signals from identical pairs of sensors 104 deployed for redundant readings of continuous physical processes from a particular industrial device 106.
- the comparative analysis ofthe noise characteristics of a pair of signals, as opposed to their mean values, permits an early identification of a disturbance prior to significant (grossly observable) changes in the operating state of the process.
- the SPRT method provides a superior surveillance tool because it is sensitive not only to disturbances in signal mean, but also to very subtle changes in the skewness, bias, or variance ofthe stochastic noise patterns associated with monitored signals.
- the use of two or more identical ones of the sensors 104 also permits the validation of these sensors 104, le ⁇ determines if the indicated disturbance is due to a change in the physical process or to a fault in either of the sensors 104.
- the SPRT module 102 For sudden, gross failures of one ofthe sensors 104 or components of the system 100, the SPRT module 102 would annunciate the disturbance as fast as a conventional threshold limit check. However, for slow degradation that evolves over a long time period (gradual decalibration bias in a sensor, wearout or buildup of a radial rub in rotating machinery, etc.), the SPRT module 102 provides the earliest possible annunciation of the onset of anomalous patterns in physical process variables. The SPRT-based expert system 100 can alert the operator to the incipience ofthe disturbance long before it would be apparent to visual inspection of strip chart or CRT signal traces, and well before conventional threshold limit checks would be tripped.
- the expert system 100 embodies the logic rules that convey to the operator the status of the sensors 104 and the industrial devices 106 connected to a SPRT network 108 (see FIG. 12).
- the expert system 100 determines which ofthe sensors 104 and/or the devices 106 are affected.
- the expert system 100 is designed to work with any network of the SPRT modules 102, encompassing any number ofthe industrial devices 106, process variables, and redundant ones ofthe sensors 104.
- the expert system 100 is operated using computer software written in the well known "LISP" language (see Appendix B attached hereto).
- the expert system 100 is divided into two segments which act as pre- and post-processors for the SPRT module computer code.
- the pre-processor section is used to set up operation of the SPRT network 108 and forge connections between the sensor data stream and the SPRT modules 102.
- the post-processor section contains the logic rules which interpret the output of the SPRT modules 102.
- the logic for the expert system 100 depends upon the grouping ofthe SPRT modules 102.
- Each of the SPRT modules 102 monitors two identical sensors 104 which measure a physical process variable.
- the two sensors can either be redundant sensors 104 on one ofthe industrial devices 106 or separate sensors 104 on two identical ones ofthe industrial devices 106 that are operated in parallel.
- a group ofthe modules 102 entails all of the connections between the identical sensors 104 for a given physical variable on a group of the industrial devices 106.
- the number ofthe modules 102 in a group depends upon the number of identical devices 106 that are operated in parallel and the number of redundant sensors 104 on each device 106 which observe the response of a physical variable.
- the expert system 100 is to be applied to an industrial system which contains three identical coolant pumps (not shown). Furthermore, suppose each coolant pump contains two redundant pressure transducers and one thermocouple (not shown). This system 100 would be modeled by two groups ofthe modules 102. The first group of the modules 102 would connect the six total pressure transducers which measure pump pressure. The second group of the modules 102 would connect the three total thermocouples which measure coolant temperature. For a given group of related sensors 104, the data from each ofthe sensors 104 are fed into the modules 102.
- the module 102 Since the module 102 performs a comparison test between the two sensors 104, the tripping of both ofthe modules 102 connected to the sensor 104 (in the absence of other tripped modules 102 in the same group) is a necessary and sufficient condition to conclude that the sensor 104 has failed. Therefore, for a group of related sensors 104, the minimum number of modules 102 needed to enable sensor detection is the same as the number ofthe sensors 104 in the group. For the example discussed above, the number ofthe modules 102 in the first group would be six, and the number ofthe modules 102 in the second group would be three.
- the module 102 applied to pairs of the sensors 104 monitoring the same physical process on the respective devices 106 will provide sensitive annunciation of any physical disturbance affecting one ofthe devices 106. If each of the devices 106 has only one of the sensors 104 though, it would not be possible for the expert system 100 to distinguish between device degradation and sensor degradation. In this case, the primary benefit of the method would derive from its very early annunciation of a disturbance. For cases in which each ofthe industrial devices 106 is equipped with multiple, redundant sensors 104, the modules 102 can be applied to pairs ofthe sensors 104 on each of the industrial devices 106 for sensor-operability verification.
- the expert system 100 not only provides early annunciation of a disturbance, but can also distinguish between device degradation and sensor degradation. Moreover, when the expert system 100 determines that the cause ofthe discrepant signals is due to a degraded one ofthe sensors 104, it can identify the specific sensor 104 that has failed.
- FIG. 9 illustrates the first stage ofthe expert system 100 processing for a simple generic application involving a single one ofthe industrial devices 106 that is equipped with triply-redundant sensors 104 for measurement of two physical variables.
- the expert system 100 first identifies the minimum unique set of signal pairs that will be needed for the network of interacting modules 102.
- FIG. 10 illustrates a generic application involving two of the industrial devices 106 that are operated in parallel. For this example, it is also assumed that triply-redundant sensors 104 are available for measuring each of two separate physical variables. Once again, the expert system 100 identifies the pair-wise sensor combinations that it uses in building the conditional branching hierarchy for the module configuration.
- FIG. 11 illustrates a generic application involving three industrial devices 106 that are operated in parallel.
- Triply-redundant sensors 104 for measuring one physical variable are assumed.
- the figure shows the pair-wise sensor combinations identified by the expert system 100 for building the conditional branching hierarchy.
- These figures also depict the three main branches for the logic rules contained in the expert system 100: a grouping ofthe modules 102 based on a single one ofthe industrial devices 106, two identical devices 106 operated in parallel or multiple (three or more) devices 106 operated in parallel.
- the expert system 100 however is not limited to only one of the three cases at a time.
- the industrial system 100 modeled can contain any number of independent single devices 106, doubly-redundant devices 106 and multiply-redundant devices 106.
- Each device group may contain any number of redundant sensors 104 and any number of physical variables.
- the expert system 100 is implemented using a stand-alone computer program set forth in the previously referenced Appendix B.
- the computer program prompts the user for the name of a data file that simulates the real-time behavior ofthe SPRT network 108 connected to the system 100 including the industrial devices 106.
- the SPRT data file contains space- delimited data values that represent the status of a corresponding module 102.
- the module 102 has two states: a 0 (non-tripped) state indicates that the signals from the sensors 104 monitored by the module 102 have not diverged from each other, while a 1 (tripped) state indicates that the signals from the sensors 104 monitored by the module 102 have diverged from each other enough to be detected by the SPRT algorithm.
- Each line of data in the file represents the status of a group of related modules 102 at a given time.
- Each line contains a list of O's and l's that correspond to the state of all the modules 102 in the group.
- the number of groups in the network 108 depends upon the number of groups of identical devices 106 and the number of process variables monitored on each group of devices 106. If the network 108 contains more than one group of related modules 102, the data file will contain a corresponding number of lines to represent the status of all the modules 102 in the network 108 at a given time. For instance, if a system of the industrial devices 106 is modeled by four SPRT groups, the output file will contain four lines of SPRT data for each timestep in the simulation.
- Execution of the program of Appendix B includes two procedures.
- the first procedure (SPRT Expert) provides the instructions for the control of program execution and corresponds to the pre-processor section in an integrated SPRT expert system/SPRT module code.
- SPRT Expert provides the instructions for the control of program execution and corresponds to the pre-processor section in an integrated SPRT expert system/SPRT module code.
- the procedure first prompts the user to specify the number of device groups in the application.
- a device group is a group of identical industrial devices 106 (one pr more) that are operated in parallel and are equipped with redundant ones of the sensors 104.
- a device group can contain one or more physical variables.
- the program then prompts the user for the following information for each ofthe device groups:
- the program After the program has collected the required data to set up the system, it prompts the user for the name of the SPRT data file. Execution ofthe program consists of reading the SPRT status values from the data file and evaluating the status ofthe devices 106 and sensors 104 in the application, as inferred from the SPRT data. Program execution is controlled by a "do" loop. For each pass through the loop, the program reads the data which model the state of each of the SPRT modules 102 in the network at a given time. The SPRT data are then passed to the Analyze procedure.
- SPRT value 1
- the Analyze procedure determines which device(s) 106 and/or sensor(s) 104) are affected and reports their status. Looping continues until the end ofthe data file is reached, upon which the program terminates.
- the Analyze procedure contains the logic rules for the expert system 100. It corresponds to the post-processor section in an integrated SPRT expert system/SPRT module code. It is passed lists of O's and l's that represent the status of the SPRT modules 102 at any given timestep of the SPRT program. The number of lists passed to Analyze equals the number of SPRT groups. For each SPRT group, the procedure converts the SPRT data into a list of tripped SPRT modules 102. From the list of tripped SPRT modules 102, the status of the devices 106, and the sensors 104 modeled by the SPRT group are evaluated.
- the expert system 100 can determine which of the device(s) 106 and/or the sensors(s) 104 have failed. In some cases (e.g.. if the number of the tripped modules 102 is one, or if the number of redundant sensors 104 in a group is one), the expert system 100 cannot conclude that the device 106 or the sensor 104 has failed, but can only signal that device or sensor failure is possible.
- the logic rules are encapsulated by three procedures: SingleDevice, for a SPRT group applied to a single one ofthe industrial devices 106, DualDevice, for a SPRT group applied to two parallely-operated industrial devices 106; and MultipleDevice, for a SPRT group applied to a group of three or more parallely-operated industrial devices 106.
- a diagram ofthe system 110 is shown in FIG. 14 and contains two groups ofthe industrial devices 106.
- a first group 1 12 (identified as turbine devices) contains three ofthe identical devices 106.
- Each turbine is equipped with the sensors 104 to measure the steam temperature and steam pressure physical variables.
- a second device group 114 consists of two coolant pumps.
- One physical variable, coolant flowrate, is gauged on each coolant pump by a group of four redundant sensors 104.
- the corresponding network of SPRT modules 102 for the system 110 is shown. Three groups of the SPRT modules 102 are required; with six ofthe modules 102 in a first module group for the steam temperature sensors on the turbines, three modules 102 in the second module group for the steam pressure sensors 104 on the turbines, and eight of the modules 102 in the third group of the modules 102 for the coolant flowrate sensors 104 on the coolant pumps.
- the program For each device group in the network, the program requests that the user supply the name of the devices in the group, the number of identical devices, the number of physical variables in the device group, and the names and numbers of redundant sensors for each physical variable.
- the input entered for device group #1 is: DEVICE NAME:
- the program displays a summary ofthe SPRT network, by identifying the SPRT groups in the network.
- the number of SPRT Groups in the simulation is 3 SPRT Group #1 contains 3 TURBINE industrial devices with 2 STEAM TEMPERATURE redundant sensors.
- SPRT Group #2 contains 3 TURBINE industrial devices with 1 STEAM PRESSURE redundant sensor.
- SPRT Group #3 contains 2 COOLANT PUMP industrial devices with 4 COOLANT FLOWRATE redundant sensors
- the final input item required is the name ofthe data file containing the status values for the SPRT modules in the network. Enter filename for SPRT data -> TEST.DAT
- the analysis of the SPRT data is controlled by a do loop. For each pass through the loop, the program retrieves a line of data for each SPRT group in the network. Each block of data retrieved from the file represents the status of all SPRT modules in the network at a moment in time. The program analyzes each block of data to determine whether the SPRT status values imply device and or sensor failures.
- the first block of data retrieved from the TEST.DAT file is: oooooo
- the program can conclude only that some device and/or sensor failures may have occurred.
- the program identifies which modules have tripped and which devices or sensors are affected.
- the SPRT modules have a finite false alarm probability) which would mean that the earlier conclusion still holds, the code conservatively concludes that none of the trips are spurious and decides that a device failure has occurred.
- the code assumes that no module trip is spurious, which causes the code to consistently pick the most conservative conclusion when more than one conclusion can be deduced from the data.
- the fifth and last set of data in the file contains additional module trips. 1 1 1 1 1 0 0 1 1 1
- SPRT group #1 The additional trips in SPRT group #1 cause the code to conclude that more than one device in the group is affected.
- SPRT group #2 all three modules in the group have tripped. Whenever all SPRT modules in a group trip, the code concludes that all devices in the group have failed.
- SPRT group #3 the additional module trip does not change the conclusion, since the worst-case conclusion (i.e., one or both of the devices in the group have failed) for the group has already been reached. Analyzing SPRT data set number 5 SPRT Group #1
- the code concludes that devices A and B have failed, but for device C it concludes that only one of its sensors has failed.
- the code applies its logic rules to each of the devices independently. Since for devices A and B both of their sensors are involved, the code concludes that the devices have failed. For device C only the first sensor is involved, thus the code concludes that only the first sensor on the device has failed. The code reaches the end ofthe file after analyzing the fifth block of data, causing the code to te ⁇ ninate.
- SPRT group #3 a failure of one or both of the devices is indicated, although the pattern of tripped modules can also be interpreted as a simultaneous failure of sensors B2 and B4. The code indicates a device failure because concurrent failures of two or more sensors in a group is deemed to be highly improbable.
- the title to be changed is on the 6ch line cf code.
- Che mean of the day ran previously, comment cue Che 7-3th lines or code. This will cause the means of the data to he read from a file created at the las- n - this uav ycu car. compare the whole month by using the mean oi the first day.
- O ruc is directed to the file ' spr p.1st' .
- the signal pairs are cl-c2, c2-c4, cf-cS, c7-c3, c9-cil, and cl0-cl2.
- the S?RT1 and SP5.T2 values at each data point are also given (to remove this " feature * ccmme ⁇ t out the 'proc print' procedure on the last line of the macro) .
- the rererence name 'dset' •/ croc means data-datiib.Sdsat var noprint; /"* Get the variance of the */ var noise; /* residual function »/ output out-tvor var ⁇ sigmas ⁇ ; data datlib.tdsec; i-1; set datlib.sdaet; set tucr p ⁇ int-i; /"Generate the rzn ⁇ om data »/ recsns - sigmasc--Q .5 *ranncr(2) t* power: /"and add to 'power »/ keep st r, trawd.it power nciae rscor.s; croc means daca-citiib. ics ⁇ c sei ⁇ var skewness l r sis ir-i mac; hcie ta addran;
- I is Chi s viirs with 2 degre-as c ⁇ f eader. -I cata _r.uli_; file print; erge skew kurt; ks ⁇ r - xscrbi - ⁇ scr 2: alpha - probchi (kscr, 2, 11 ; cut '0 Ag ⁇ stino Pearson rasuits for ' "ix"// ' 'Skew - ' ik///
- the input dataset should come from the library uith » / f iibrer - 'diclib', ana the datasec name should be assier.sc */
- % include macros; -Met dset*-reconsl4; %lec rawdat»cli; -ilet specssec— psd!4;
- %noracat ir-ncise, proc means data-data .
- tdset mean noprint; var Srawdat; ou out out-twork me n-mu; /* Get the residuals needed •/ data; /" for the 'sign' macro - / set data.&dset; i-L; set fw ⁇ r point » i: r» srawdat - mu; res-noise; keep r rsa; outpu ; %runs(r-r) irons (r»ces)
- Chars-Co-List Procedure This internal procedure recursively converts a list of characters chat contain embedded 0 and 1 characters into a list of o a and l s. Any other character Chan a 0 or 1 is ignored, (define Chars-to-Liac (lambda (Chars)
- Eof-List? Procedure This internal procedure searches a list element by element for che eof character. IC returns true if che end-of-file char ⁇ acter is found, or false if che list does not contain the eof character, (define Eof-Lisc? (lambda (Lac)
- LiscTrippedSPRTs Procedure - This internal procedure processes che lisc of SPRT daca for a pass through che main do loop. Each element of che lisc contains che SPRT daca for an independent group of SPRTs. Each element of the lisc is processed by the internal FindSPRTs procedure, which returns a list of numbers where each number reprsencs che SPRTs chat have tripped [i.e., equal co ll . Thus if che following lisc of ; ; SPRTs is passed Co FindSPRTs: [0 1 0 0 0 1 0 1], ic would return che following list: [2 6 8] . (de ine ListTrippedSPRTs -
- This procedure analyzes the list of tripped SPRTs. Each element in the list consists of a list of tripped SPRTs. There are NSPRT_Groups elemencs in che lisc - one for each corresponding group of independent SPRTs. (Analyze GroupData SPRT_Daca 1)
- AnalyzeGroup procedure This internal procedure controls the flow of SPRT * data analysis. It is passed the input data and the list of tripped SPRTs for a group of independent SPRTs. Depending upon the number of devices in the group, AnalyzeGroup calls a procedure which performs the actual analysis of the data, (define AnalyzeGroup
- display All (display NSPRTs) (display SPRTs have tripped ) ) (begin ; or, write chis message. ( display These ) (display NSPRTs) (display of the )
- display NSensors display SPRTs have tri D ped -
- Firsc write ; message showing current device and physical variable, (display For the ) (display VName)
- a do loop is used Co seep through che lisc of names of tripped SPRTs. For each device, we can decermine if che device has failed, may be failing, or if one of ics sensors has or may be failing. The do lisc s eps from device 1 Co NDevices.
- Firsc I reset he temporary variables which concain che lisc of cripped SPRTs for che currenc and nexc devices. (set! CurrencDevice (car SubLisc))
- Chen current device is number NDevices and the next device is the first device [i.e., device number A] . (if (null? (cdr SubList) )
- NameTripoedSPRTs procedure This incemal procedure cakes a lisc of cripped SPRTs and convercs each number of che cripped SPRT inco che SP R T name (e.g., A 1 B 1, is Che corresponding SPRT name for Cripped S P RT 1] .
- the oucpuc is a lisc of NDevs elemencs.
- Each of Che elements concains che name of cripped SPRTs for che corresponding device number (e.g., che 3rd element contains che names of the tripped SPRTs for device C] . If none of the SPRTs for a device have tripped, then the corresponding ele ⁇ menc is null. This procedure is applied only co device groups that contain 3 or more devices. (define NameTrippedSPRTs (lambda (NDevs SPRT_Lisc)
- a do loop is used Co seep chrough each of Che devices, from device A Co device NDevs.
- the loop variable, IDev is Che currenc device number, (do ( (IDev 1 (+ IDev 1) ) )
- DisplaySPRTs Procedure This incemal procedure outputs the names of the tripped SPRTs in Lst. For each cripped SPRT listed in Lsc, the pro ⁇ cedure determines che name [e.g., A1-A2, or Al-Bl] of che S PRT and writes ic co che screen, (define DisplaySPRTs
- che lasc SPRT [AN-A1] has Cripoed.
- display A (display NSens) (display -Al ) ;; Display criped SPRTs in che remainder of che list.
- the SPRT number is NX-AX, where N is the number of devices, and X is the sensor number, (begin
- the Analyze procedure is passed input data and cripped SPRT data super lists. Each element of these lists contains Che inpuc daca and lisc of cripped SPRTs for a corresponding group of independene SPRTs. This por- cion of che procedure is a concrol roucine which each elemenc of Che super liscs Co Che AnalyzeGroup procedure. f (null? SPRT List) Quit if end of list is reached. trt
Abstract
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AU73955/96A AU707304B2 (en) | 1995-10-10 | 1996-10-08 | An expert system for testing industrial processes and determining sensor status |
EP96936263A EP0855061B1 (en) | 1995-10-10 | 1996-10-08 | An expert system for testing industrial processes and determining sensor status |
DE69631594T DE69631594D1 (en) | 1995-10-10 | 1996-10-08 | EXPERT SYSTEM FOR TESTING INDUSTRIAL PROCESSES AND DETERMINING THE SENSOR STATUS |
CA002234452A CA2234452C (en) | 1995-10-10 | 1996-10-08 | An expert system for testing industrial processes and determining sensor status |
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US08/541,602 | 1995-10-10 |
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AU (1) | AU707304B2 (en) |
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- 1995-10-10 US US08/541,602 patent/US5761090A/en not_active Expired - Lifetime
-
1996
- 1996-10-08 WO PCT/US1996/016092 patent/WO1997014105A1/en active IP Right Grant
- 1996-10-08 EP EP96936263A patent/EP0855061B1/en not_active Expired - Lifetime
- 1996-10-08 AU AU73955/96A patent/AU707304B2/en not_active Ceased
- 1996-10-08 DE DE69631594T patent/DE69631594D1/en not_active Expired - Lifetime
- 1996-10-08 CA CA002234452A patent/CA2234452C/en not_active Expired - Fee Related
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Cited By (16)
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EP1055239A1 (en) * | 1998-01-14 | 2000-11-29 | Arch Development Corporation | Ultrasensitive surveillance of sensors and processes |
EP1055239A4 (en) * | 1998-01-14 | 2002-06-19 | Arch Dev Corp | Ultrasensitive surveillance of sensors and processes |
US7136716B2 (en) | 2000-03-10 | 2006-11-14 | Smiths Detection Inc. | Method for providing control to an industrial process using one or more multidimensional variables |
US7313447B2 (en) | 2000-03-10 | 2007-12-25 | Smiths Detection Inc. | Temporary expanding integrated monitoring network |
US6895338B2 (en) | 2000-03-10 | 2005-05-17 | Smiths Detection - Pasadena, Inc. | Measuring and analyzing multi-dimensional sensory information for identification purposes |
US6917845B2 (en) | 2000-03-10 | 2005-07-12 | Smiths Detection-Pasadena, Inc. | Method for monitoring environmental condition using a mathematical model |
US6985779B2 (en) | 2000-03-10 | 2006-01-10 | Smiths Detection, Inc. | Monitoring system for an industrial process using one or more multidimensional variables |
US7031778B2 (en) | 2000-03-10 | 2006-04-18 | Smiths Detection Inc. | Temporary expanding integrated monitoring network |
US6853920B2 (en) | 2000-03-10 | 2005-02-08 | Smiths Detection-Pasadena, Inc. | Control for an industrial process using one or more multidimensional variables |
US6865509B1 (en) | 2000-03-10 | 2005-03-08 | Smiths Detection - Pasadena, Inc. | System for providing control to an industrial process using one or more multidimensional variables |
US8352049B2 (en) | 2000-03-10 | 2013-01-08 | Smiths Detection Inc. | Temporary expanding integrated monitoring network |
US7840359B2 (en) | 2000-03-10 | 2010-11-23 | Smiths Detection Inc. | Measuring and analyzing multi-dimensional sensory information for identification purposes |
US7912561B2 (en) | 2000-03-10 | 2011-03-22 | Smiths Detection Inc. | Temporary expanding integrated monitoring network |
FR2910689A1 (en) * | 2006-12-22 | 2008-06-27 | Commissariat Energie Atomique | Noisy temporal neutron flow representing signal processing method for nuclear power plant, involves filtering Gaussian transformed signal by kalman filter, and performing inverse transformation for filtered signal |
WO2019077422A1 (en) * | 2017-10-16 | 2019-04-25 | Abb Schweiz Ag | Remote verification of field devices in industrial plants |
WO2023232360A1 (en) * | 2022-05-31 | 2023-12-07 | Asml Netherlands B.V. | Method for determining a failure event on a lithography system and associated failure detection module |
Also Published As
Publication number | Publication date |
---|---|
EP0855061A4 (en) | 1999-01-13 |
CA2234452C (en) | 2004-02-24 |
EP0855061A1 (en) | 1998-07-29 |
US5761090A (en) | 1998-06-02 |
CA2234452A1 (en) | 1997-04-17 |
AU7395596A (en) | 1997-04-30 |
AU707304B2 (en) | 1999-07-08 |
EP0855061B1 (en) | 2004-02-18 |
DE69631594D1 (en) | 2004-03-25 |
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