OPTIMIZATION OF PARAMETERS OF GENERALIZED DISPERSION ALGORITHM AT STATISTICAL PROCESS CONTROL

When monitoring a real production process using statistical methods, the question of early detection of violations arises. In most cases, several indicators are monitored simultaneously in the production process, and a change in the values of some indicators leads to a change in others. If there is a dependence of indicators for their monitoring, multivariate statistical control tools are used, in particular generalized variance chart. By varying the parameters of the chart, its efficiency can be significantly increased, this allows minimizing the time the process is in an unstable state.Applying the approach of A. Duncan, which he developed for Shewhart charts, a formula for the expectation of the duration of an unstable state of a process was obtained and a Python program was developed to minimize it. To test the set optimization problem, the calculation of the data of two process indicators is given and the optimal parameters of the generalized variance chart are obtained, at which the duration of the process in an unstable state is minimal.

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SELECTION OF THE PARAMETERS OF THE GENERALIZED DISPERSION ALGORITHM FOR MULTIVARIATE STATISTICAL CONTROL OF THE PROCESS SCATTERING

Izvestiya of Samara Scientific Center of the Russian Academy of Sciences ◽

10.37313/1990-5378-2021-23-1-79-83 ◽

2021 ◽

Vol 23 (1) ◽

pp. 79-83

Author(s):

A.V. Alekseeva ◽

◽

V.N. Klyachkin ◽

Keyword(s):

Performance Indicators ◽

Optimization Problem ◽

Unstable State ◽

Statistical Control ◽

Multivariate Statistical ◽

Generalized Variance ◽

Process Indicators ◽

The Stability ◽

Process Disturbances ◽

Selection Of

To control the stability of the functioning of aviation equipment units based on the results of monitoring a group of indicators, methods of statistical processes control can be used. In the presence of significant correlations between performance indicators, multivariate methods are used. In this case, the control of the average level of the process is carried out on the basis of the Hotelling algorithm, the control of multivariate scattering is carried out using the generalized variance algorithm. If, according to the conditions of the process, it is necessary to ensure the fastest detection of a violation, then the optimization problem of finding such values of the sample size, sampling frequency and position of the control boundaries is solved that minimizes the average time of the unstable state of the process. The initial data are the number of process indicators monitored, the target value of the generalized variance (estimated from experimental data), the characteristic of the permissible increase in scattering, the intensity of process disturbances (parameter of the Poisson distribution); time to search for a violation after its detection and time to calculate the sample element.

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IMPROVING THE EFFICIENCY OF STATISTICAL CONTROL OF HYDRO-UNIT VIBRATIONS

Автоматизация процессов управления ◽

10.35752/1991-2927-2020-3-61-101-107 ◽

2020 ◽

Vol 61 (3) ◽

pp. 101-107

Author(s):

Anastasiia V. Alekseeva ◽

Keyword(s):

Special Kind ◽

Fixed Time ◽

Hydroelectric Power Station ◽

Hydroelectric Power ◽

Statistical Control ◽

Statistical Process ◽

Hydraulic Unit ◽

Generalized Variance ◽

Vibration Data ◽

Process Failure

Some techniques of statistical process control can be applied in investigating an object for likely defects. In this regard, the multidimensional scattering is monitored with the use of a generalized variance algorithm. At fixed time intervals samples of observations are recorded, according to which the values of the determinant of covariance matrix (the generalized variance) are calculated. The corresponding point, falling outside the borders of control chart, indicates the process failure. The test results based on vibration data obtained from the hydraulic unit at the Krasnopolianskaia Hydroelectric Power Station showed that the algorithm of the generalized variance has an insufficient quick response relating to both gradual and spasmodic changes in the scattering level. To make the monitoring process more efficient, the following techniques have been suggested. The first one detects defects by analyzing special kind structures on the generalized variance chart. The second technique applies the warning borders on the chart and the third one implies an algorithm of exponentially weighted moving averages for generalized variance. All the tests revealed that the search for nonrandom structures on the generalized variance chart is most effective for the early detection of changes in the scattering process.

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An integrated approach for multivariate statistical process control using Mahalanobis-Taguchi System and Andrews function

International Journal of Quality & Reliability Management ◽

10.1108/ijqrm-11-2015-0163 ◽

2017 ◽

Vol 34 (8) ◽

pp. 1186-1208 ◽

Cited By ~ 5

Author(s):

Sagar Sikder ◽

Subhash Chandra Panja ◽

Indrajit Mukherjee

Keyword(s):

Process Control ◽

Case Studies ◽

Control Point ◽

The State ◽

Statistical Control ◽

Multivariate Statistical ◽

Statistical Process ◽

Content Type ◽

Influential Variable ◽

Control State

Purpose The purpose of this paper is to develop a new easy-to-implement distribution-free integrated multivariate statistical process control (MSPC) approach with an ability to recognize out-of-control points, identify the key influential variable for the out-of-control state, and determine necessary changes to achieve the state of statistical control. Design/methodology/approach The proposed approach integrates the control chart technique, the Mahalanobis-Taguchi System concept, the Andrews function plot, and nonlinear optimization for multivariate process control. Mahalanobis distance, Taguchi’s orthogonal array, and the main effect plot concept are used to identify the key influential variable responsible for the out-of-control situation. The Andrews function plot and nonlinear optimization help to identify direction and necessary correction to regain the state of statistical control. Finally, two different real life case studies illustrate the suitability of the approach. Findings The case studies illustrate the potential of the proposed integrated multivariate process control approach for easy implementation in varied manufacturing and process industries. In addition, the case studies also reveal that the multivariate out-of-control state is primarily contributed by a single influential variable. Research limitations/implications The approach is limited to the situation in which a single influential variable contributes to out-of-control situation. The number and type of cases used are also limited and thus generalization may not be debated. Further research is necessary with varied case situations to refine the approach and prove its extensive applicability. Practical implications The proposed approach does not require multivariate normality assumption and thus provides greater flexibility for the industry practitioners. The approach is also easy to implement and requires minimal programming effort. A simple application Microsoft Excel is suitable for online implementation of this approach. Originality/value The key steps of the MSPC approach are identifying the out-of-control point, diagnosing the out-of-control point, identifying the “influential” variable responsible for the out-of-control state, and determining the necessary direction and the amount of adjustment required to achieve the state of control. Most of the approaches reported in open literature are focused only until identifying influencing variable, with many restrictive assumptions. This paper addresses all key steps in a single integrated distribution-free approach, which is easy to implement in real time.

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Research on Nonlinear Process Monitoring and Fault Diagnosis Based on Kernel Principal Component Analysis

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.413-414.583 ◽

2009 ◽

Vol 413-414 ◽

pp. 583-590 ◽

Cited By ~ 1

Author(s):

Fei He ◽

Min Li ◽

Jian Hong Yang ◽

Jin Wu Xu

Keyword(s):

Principal Component Analysis ◽

Production Process ◽

Statistical Process Control ◽

Process Monitoring ◽

Principal Component ◽

Component Analysis ◽

Kernel Principal Component Analysis ◽

Multivariate Statistical Process Control ◽

Multivariate Statistical ◽

Statistical Process

In order to monitor nonlinear production process effectively, multivariate statistical process control based on kernel principal component analysis is applied to process monitoring and diagnosis. Squared prediction error (SPE) statistic of the kernel principal component analysis (KPCA) model is used for process monitoring, and the fault causes of the production process could be tracked by the methods of data reconstruction and the optimal neighbor selection strategy. Simulation data and Tennessee Eastman process data are used for model validation, as a result the proposed method has better performance on abnormality detecting, compared with multivariate statistical process control based on linear principal component analysis. What is more, the causes of the faults are tracked effectively, thus the production process can be adjusted to prevent substandard products.

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Monitoring of Flotation Systems by Use of Multivariate Froth Image Analysis

Minerals ◽

10.3390/min11070683 ◽

2021 ◽

Vol 11 (7) ◽

pp. 683

Author(s):

Chris Aldrich ◽

Xiu Liu

Keyword(s):

Image Analysis ◽

Process Monitoring ◽

Chemical Species ◽

Platinum Metal ◽

Local Binary Patterns ◽

Monitoring Methods ◽

Multivariate Statistical ◽

Statistical Process ◽

Froth Stability ◽

Froth Image

Froth image analysis has been considered widely in the identification of operational regimes in flotation circuits, the characterisation of froths in terms of bubble size distributions, froth stability and local froth velocity patterns, or as a basis for the development of inferential online sensors for chemical species in the froth. Relatively few studies have considered flotation froth image analysis in unsupervised process monitoring applications. In this study, it is shown that froth image analysis can be combined with traditional multivariate statistical process monitoring methods for reliable monitoring of industrial platinum metal group flotation plants. This can be accomplished with well-established methods of multivariate image analysis, such as the Haralick feature set derived from grey level co-occurrence matrices and local binary patterns that were considered in this investigation.

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Oversizing Thread Diagnosis in Tapping Operation

Metals ◽

10.3390/met11040537 ◽

2021 ◽

Vol 11 (4) ◽

pp. 537

Author(s):

Alain Gil Del Val ◽

Fernando Veiga ◽

Mariluz Penalva ◽

Miguel Arizmendi

Keyword(s):

Control Chart ◽

Manufacturing Systems ◽

Spindle Motor ◽

Multivariate Statistical ◽

Statistical Process ◽

Knowing That ◽

On Line ◽

High Level ◽

Screw Threads ◽

Multivariate Control

Automotive, railway and aerospace sectors require a high level of quality on the thread profiles in their manufacturing systems knowing that the tapping process is a complex manufacturing process and the last operation in a manufacturing cell. Therefore, a multivariate statistical process control chart, for each tap, is presented based on the principal components of the torque signal directly measured from spindle motor drive to diagnosis the thread profile quality. This on-line multivariate control chart has implemented an alarm to avoid defected screw threads (oversized). Therefore, it could work automatically without any operator intervention assessing the thread quality and the safety is guaranteed during the tapping process.

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