Multivariate monitoring and diagnostics of process variable data
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G06F-017/18
G06F-019/00
출원번호
US-0688795
(2007-03-20)
등록번호
US-8489360
(2013-07-16)
발명자
/ 주소
Lundeberg, Marcus R.
Samardzija, Nikola
Miller, John P.
출원인 / 주소
Fisher-Rosemount Systems, Inc.
대리인 / 주소
Marshall, Gerstein & Borun LLP
인용정보
피인용 횟수 :
8인용 특허 :
178
초록▼
A system and method of monitoring and diagnosing on-line multivariate process variable. Multivariate process data includes multiple process variables each having a multiple observations. On-line process data is collected from a process control system when the process is on-line. The on-line process
A system and method of monitoring and diagnosing on-line multivariate process variable. Multivariate process data includes multiple process variables each having a multiple observations. On-line process data is collected from a process control system when the process is on-line. The on-line process data includes multiple observations of multiple process variables. A multivariate statistical analysis represents the operation of the process based on a set of the on-line process data. The representation a result. The representation and the set of on-line process data are stored. An output is generated based on a parameter of the representation. The parameter includes a result generated by the representation of the operation of the process, a process variable used to generate the representation of the operation of the process and/or the set of collected on-line process data.
대표청구항▼
1. A system for monitoring and diagnosing on-line multivariate process variable data in a process plant, wherein the multivariate process data comprises a plurality of process variables each having a plurality of observations, the system comprising: a data collection tool adapted to collect on-line
1. A system for monitoring and diagnosing on-line multivariate process variable data in a process plant, wherein the multivariate process data comprises a plurality of process variables each having a plurality of observations, the system comprising: a data collection tool adapted to collect on-line process data from a process control system within the process plant when the process is on-line, wherein the collected on-line process data comprises a plurality of observations of a plurality of process variables, and wherein the plurality of observations of a set of collected on-line process data comprises a first data space having a plurality of dimensions;an analysis tool comprising a multivariate statistical analysis engine adapted to represent the operation of the process within a second data space having fewer dimensions than the first data space based on a set of collected on-line process data comprising a measure of the operation of the process when the process is on-line, wherein the representation of the operation of the process is adapted to be executed to generate a result, and wherein the analysis tool is adapted to store the representation of the operation of the process and the set of collected on-line process data; anda monitoring tool adapted to generate an output based on a parameter of the representation of the operation of the process, wherein the parameter of the representation of the operation of the process comprises one or more of a result generated by the representation of the operation of the process, a process variable used to generate the representation of the operation of the process and the set of collected on-line process data. 2. The system of claim 1, wherein the monitoring tool comprises an execution tool adapted to execute the representation of the operation of the process to generate a score. 3. The system of claim 2, wherein the score comprises a representation of one or more observations in the second data space. 4. The system of claim 3, wherein the monitoring tool is adapted to project the observations from the set of collected data onto the second data space to generate one or more scores. 5. The system of claim 3, wherein the multivariate statistical analysis engine is adapted to represent the operation of the process as a plurality of principal components defining the second data space, wherein each principal component corresponds to an amount of variation in the set of collected process data. 6. The system of claim 2, wherein the monitoring tool is adapted to diagnose the process using the statistical output. 7. The system of claim 2, wherein the monitoring tool is adapted to determine the presence of an abnormal process condition if the score exceeds a threshold value. 8. The system of claim 7, wherein the analysis tool is adapted to determine the threshold value based upon one or more process variable limits of the plurality of process variables. 9. The system of claim 8, wherein the one or more process variable limits of the plurality of process variables comprises one or more of the group comprising: a statistical process variable limit and a physical process variable limit. 10. The system of claim 7, wherein the monitoring tool is adapted to generate an alarm based on the presence of an abnormal process condition. 11. The system of claim 1, wherein the monitoring tool is adapted to generate a normalized process variable based on a process variable used to generate the representation of the operation of the process. 12. The system of claim 11, wherein each process variable used to generate the representation of the operation of the process comprises a known process variable limit and a known target value, wherein the monitoring tool comprises a normalization tool adapted to normalize each process variable based on the known process variable limit and the known target. 13. The system of claim 12, wherein the known process variable limit comprises a known upper process variable limit and a known lower process variable limit. 14. The system of claim 11, wherein at least one of the process variables used to generate the representation of the operation of the process comprises an unknown process variable limit, wherein the monitoring tool comprises a normalization tool adapted to calculate the unknown process variable limit based on the maximum deviation of an observation from a mean of a set of collected process variable data, wherein the observation is within a set of collected process variable data comprising a measure of the at least one process variable when the process is on-line and operating normally, and normalize the at least one process variable based on the calculated unknown process variable limit and based on the mean of the set of collected process variable data to generate a process variable limit for the at least one process variable. 15. The system of claim 11, wherein at least one of the process variables used to generate the representation of the operation of the process comprises an unknown process variable limit, wherein the monitoring tool comprises a normalization tool adapted to normalize the at least one process variable based on a mean of a set of collected process variable data comprising a measure of the at least one process variable when the process is on-line and operating normally and based on a variance of the set of collected process variable data to generate a process variable limit for the at least one process variable. 16. The system of claim 15, wherein the normalization tool is adapted to determine a statistical control limit based on the variance of the set of collected process variable data and adapted to normalize the at least one process variable based on the statistical control limit. 17. The system of claim 11, wherein the monitoring tool is adapted to generate a common process variable limit for the plurality of process variables based on the normalized process variable, and adapted to monitor each process variable in relation to the common process variable limit. 18. The system of claim 11, wherein the monitoring tool is adapted to determine the presence of an abnormal process condition if the process variable exceeds the common process variable limit. 19. The system of claim 18, wherein the monitoring tool is adapted to generate an alarm based on the presence of an abnormal process condition. 20. The system of claim 18, wherein the monitoring tool is adapted to monitor the process variable in relation to the common process variable limit based upon a result generated by the representation of the operation of the process. 21. The system of claim 1, wherein the monitoring tool is adapted to generate a process variable index based on the set of collected on-line process data and based on a component of the second data space, wherein the process variable index indicates an amount of deviation of one or more of the plurality of process variables and adapted to verify the representation of the operation of the process based on the process variable index. 22. The system of claim 21, wherein the monitoring tool comprises an index tool adapted to determine the process variable index based on a trace of the set of collected process data in the first data space and a component of the second data space, wherein the component of the second data space comprises the component used to determine the representation of the operation of the process. 23. The system of claim 22, wherein the analysis tool is adapted to generate a plurality of principal components within the first data space that define the second data space, wherein each principal component corresponds to an amount of variation in the set of collected process data and wherein the component of the second data space comprises a principal component used to define the second data space. 24. The system of claim 21, wherein the multivariate statistical analysis engine is adapted to represent the operation of the process based on a first set of collected on-line process data comprising a first measure of the operation of the process when the process is on-line, and adapted to represent the operation of the process based on a second set of collected on-line process data comprising a second measure of the operation of the process when the process is on-line,wherein the monitoring tool is adapted to generate a first process variable index based on the first set of collected on-line process data and based on a component used to determine the first representation of the operation of the process and adapted to generate a second process variable index based on the second set of collected on-line process data and based on a component used to determine the first representation of the operation of the process, andwherein the monitoring tool comprises a verification tool adapted to compare the first and second process variables to determine whether the first and second process variables are on the same order if the first and second representations of the operation of the process represent the same operation of the process. 25. The system of claim 24, wherein the analysis tool comprises a first multivariate statistical analysis engine adapted to represent the operation of the process based on the first set of collected on-line process data comprising the first measure of the operation of the process when the process is on-line, and a second multivariate statistical analysis engine adapted to represent the operation of the process based on the set of collected on-line process data comprising the second measure of the operation of the process when the process is on-line. 26. The system of claim 21, wherein the monitoring tool is adapted to store the process variable index with the representation of the operation of the process and the set of collected on-line process data. 27. The system of claim 21, wherein the index tool is adapted to determine the process variable index as a calculation of: PVjrating=1trS∑i=1kσi2pi,j2wherein:PVjrating=the process variable index of a jth process variable,S=an n×n auto-scaled covariance matrix of the set of collected on-line process data,n=plurality of dimensions of the first data space,trS=a trace of S,k=the plurality of dimensions of the second data space,σi=a principal eigenvalue of S,pi=a principal eigenvector of S, andpi,j=the jth component of pi. 28. The system of claim 1, further comprising a display tool adapted to generate a visualization of the output generated by the monitoring tool. 29. The system of claim 28, wherein the display tool is adapted to generate a visualization of a score generated by the representation of the operation of the process in relation to a component used to define the second data space. 30. The system of claim 29, wherein the visualization of a score generated by the representation of the operation of the process in relation to a component used to define the second data space comprises a visualization of an on-line score generated by a representation of an on-line operation of the process when the process is operating on-line in relation to a component used to define the second data space. 31. The system of claim 29, wherein the visualization of a score generated by the representation of the operation of the process in relation to a component used to define the second data space further comprises a visualization of one or more of the plurality of process variables in relation to the component used to define the second data space. 32. The system of claim 28, wherein the visualization comprises a plot of a score generated by the representation of the operation of the process versus time. 33. The system of claim 28, wherein the visualization comprises a plot of a first score generated by the representation of the operation of the process versus a second score generated by the representation of the operation of the process. 34. The system of claim 28, wherein the display tool is adapted to generate a visualization of one or more of the plurality of process variables and a process variable index associated with each of the one or more plurality of process variables indicating an amount of deviation of the associated process variable. 35. The system of claim 28, wherein the display tool is adapted to generate a visualization of one or more of the plurality of process variables in relation to a process variable limit associated with each process variable. 36. The system of claim 1, wherein the monitoring tool is adapted to generate one or more outputs selected from the group consisting of: a statistical output, a normalized process variable, and a process variable rating, wherein the statistical output comprises representations of observations of on-line process data in the second data space based on on-line process data having the largest data variation,wherein the normalize process variable comprises a process variable normalized as a function of a data set collected for the process variable and used to train the representation of operation of the process when the process is operating normally, andwherein the process variable rating comprises a rating of a process variable according to the variability of the process variable. 37. A method of monitoring and diagnosing on-line multivariate process variable data in a process plant, wherein the multivariate process data comprises a plurality of process variables each having a plurality of observations, the method comprising: collecting on-line process data from a process control system within the process plant when the process is on-line, wherein the collected on-line process data comprises a plurality of observations of a plurality of process variables, and wherein the plurality of observations of a set of collected on-line process data comprises a first data space having a plurality of dimensions;performing a multivariate statistical analysis, by a multivariate statistical analysis engine, to represent the operation of the process within a second data space having fewer dimensions than the first data space based on a set of collected on-line process data comprising a measure of the operation of the process when the process is on-line, wherein the representation of the operation of the process is adapted to be executed to generate a result;storing the representation of the operation of the process and the set of collected on-line process data; andgenerating an output based on a parameter of the representation of the operation of the process, wherein the parameter of the representation of the operation of the process comprises one or more of a result generated by the representation of the operation of the process, a process variable used to generate the representation of the operation of the process and the set of collected on-line process data. 38. The method of claim 37, wherein generating an output based on a parameter of the representation of the operation of the process comprises executing the representation of the operation of the process to generate a score. 39. The method of claim 38, wherein the score comprises a representation of one or more observations in the second data space. 40. The method of claim 39, further comprising projecting the observations from the set of collected data onto the second data space to generate one or more scores. 41. The method of claim 39, wherein performing a multivariate statistical analysis to represent the operation of the process comprises generating a plurality of principal components within the first data space, wherein each principal component corresponds to an amount of variation in the set of collected process data, and wherein the principal components define the second data space. 42. The method of claim 38, further comprising diagnosing the process using the statistical output. 43. The method of claim 38, further comprising determining the presence of an abnormal process condition if the score exceeds a threshold value. 44. The method of claim 43, further comprising determining the threshold value based upon one or more process variable limits of the plurality of process variables. 45. The method of claim 44, wherein the one or more process variable limits of the plurality of process variables comprises one or more of the group comprising: a statistical process variable limit and a physical process variable limit. 46. The method of claim 13, further comprising generating an alarm based on the presence of an abnormal process condition. 47. The method of claim 37, wherein generating an output based on a parameter of the representation of the operation of the process comprises generating a normalized process variable based on a process variable used to generate the representation of the operation of the process. 48. The method of claim 47, wherein each process variable used to generate the representation of the operation of the process comprises a known process variable limit and a known target value, wherein generating a normalized process variable comprises normalizing each process variable based on the known process variable limit and the known target. 49. The method of claim 48, wherein the known process variable limit comprises a known upper process variable limit and a known lower process variable limit. 50. The method of claim 47, wherein at least one of the process variables used to generate the representation of the operation of the process comprises an unknown process variable limit, wherein generating a normalized process variable comprises: calculating the unknown process variable limit based on the maximum deviation of an observation from a mean of a set of collected process variable data, wherein the observation is within a set of collected process variable data comprising a measure of the at least one process variable when the process is on-line and operating normally; andnormalizing the at least one process variable based on the calculated unknown process variable limit and based on the mean of the set of collected process variable data to generate a process variable limit for the at least one process variable. 51. The method of claim 47, wherein at least one of the process variables used to generate the representation of the operation of the process comprises an unknown process variable limit, wherein generating a normalized process variable comprises: normalizing the at least one process variable based on a mean of a set of collected process variable data comprising a measure of the at least one process variable when the process is on-line and operating normally and based on a variance of the set of collected process variable data to generate a process variable limit for the at least one process variable. 52. The method of claim 51, wherein generating a normalized process variable comprises: determining a statistical control limit based on the variance of the set of collected process variable data; andnormalizing the at least one process variable based on the statistical control limit. 53. The method of claim 47, further comprising: generating a common process variable limit for the plurality of process variables based on the normalized process variable; andmonitoring each process variable in relation to the common process variable limit. 54. The method of claim 47, further comprising determining the presence of an abnormal process condition if the process variable exceeds the common process variable limit. 55. The method of claim 54, further comprising generating an alarm based on the presence of an abnormal process condition. 56. The method of claim 54, further comprising monitoring the process variable in relation to the common process variable limit based upon a result generated by the representation of the operation of the process. 57. The method of claim 37, wherein generating an output based on a parameter of the representation of the operation of the process comprises generating a process variable index based on the set of collected on-line process data and based on a component of the second data space, wherein the process variable index indicates an amount of deviation of one or more of the plurality of process variables. 58. The method of claim 57, further comprising determining the process variable index based on a trace of the set of collected process data in the first data space and a component of the second data space, wherein the component of the second data space comprises the component used to determine the representation of the operation of the process. 59. The method of claim 58, wherein a plurality of principal components within the first data space define the second data space, wherein each principal component corresponds to an amount of variation in the set of collected process data and wherein the component of the second data space comprises a principal component used to define the second data space. 60. The method of claim 57, wherein performing a multivariate statistical analysis comprises: representing the operation of the process based on a first set of collected on-line process data comprising a first measure of the operation of the process when the process is on-line; andrepresenting the operation of the process based on a second set of collected on-line process data comprising a second measure of the operation of the process when the process is on-line,and wherein generating a process variable index comprises:generating a first process variable index based on the first set of collected on-line process data and based on a component used to determine the first representation of the operation of the process; andgenerating a second process variable index based on the second set of collected on-line process data and based on a component used to determine the first representation of the operation of the process,the method further comprising comparing the first and second process variables to determine whether the first and second process variables are on the same order if the first and second representations of the operation of the process represent the same operation of the process. 61. The method of claim 60, wherein representing the operation of the process based on a first set of collected on-line process data comprises performing a first multivariate statistical analysis to represent the operation of the process based on the first set of collected on-line process data comprising the first measure of the operation of the process when the process is on-line, and wherein representing the operation of the process based on a second set of collected on-line process data comprises performing a second multivariate statistical analysis to represent the operation of the process based on the set of collected on-line process data comprising the second measure of the operation of the process when the process is on-line. 62. The method of claim 57, further comprising storing the process variable index with the representation of the operation of the process and the set of collected on-line process data. 63. The method of claim 1, further comprising generating a visualization of the output generated by the monitoring tool. 64. The method of claim 63, wherein generating a visualization comprises generating a visualization of a score generated by the representation of the operation of the process in relation to a component used to define the second data space. 65. The method of claim 64, wherein the visualization of a score generated by the representation of the operation of the process in relation to a component used to define the second data space comprises a visualization of an on-line score generated by a representation of an on-line operation of the process when the process is operating on-line in relation to a component used to define the second data space. 66. The method of claim 64, wherein the visualization of a score generated by the representation of the operation of the process in relation to a component used to define the second data space further comprises a visualization of one or more of the plurality of process variables in relation to the component used to define the second data space. 67. The method of claim 63, wherein the visualization comprises a plot of a score generated by the representation of the operation of the process versus time. 68. The method of claim 63, wherein the visualization comprises a plot of a first score generated by the representation of the operation of the process versus a second score generated by the representation of the operation of the process. 69. The method of claim 63, wherein generating a visualization comprises generating a visualization of one or more of the plurality of process variables and a process variable index associated with each of the one or more plurality of process variables indicating an amount of deviation of the associated process variable. 70. The method of claim 63, wherein generating a visualization comprises generating a visualization of one or more of the plurality of process variables in relation to a process variable limit associated with each process variable. 71. A system for monitoring and diagnosing on-line multivariate process variable data in a process plant, wherein the multivariate process data comprises a plurality of process variables each having a plurality of observations, the system comprising: a data collection tool adapted to collect on-line process data from a process control system within the process plant when the process is on-line, wherein the collected on-line process data comprises a plurality of observations of a plurality of process variables, and wherein the plurality of observations of a set of collected on-line process data comprises a first data space having a plurality of dimensions;an analysis tool comprising a multivariate statistical analysis engine adapted to represent the operation of the process within a second data space having fewer dimensions than the first data space based on a set of collected on-line process data comprising a measure of the operation of the process when the process is on-line, wherein the representation of the operation of the process is adapted to be executed to generate a result, and wherein the analysis tool is adapted to store the representation of the operation of the process and the set of collected on-line process data;a normalization tool adapted to normalize two or more of the plurality of process variables; anda monitoring tool adapted to determine a process variable limit based on the normalized process variables and to monitor one or more of the process variables in relation to the process variable limit. 72. The system of claim 71, wherein each process variable used to generate the representation of the operation of the process comprises a known process variable limit and a known target value, and wherein the normalization tool is adapted to normalize two or more of the plurality of process variables as a calculation of: PV*=100%×n×(PV-T)2CL2wherein:PV*=a normalized process variable,T=the known target value,CL=|UCL−T|=|LCL−T|,UCL=a known upper process variable limit,LCL=a known lower process variable limit, and0
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