XV-102-D4-57TVR-10 Intelligent operation control system

3.2 Machine learningAs the functionality of distributed computing tools such as Spark MLLib (http://spark.apache.org/mllib) and SparkR (http://spark.apache.org/docs/latest/index.html) increases, it becomes It is easier to implement distributed and online machine learning models, such as support vector machines, gradient boosting trees and decision trees for large amounts of data. Test the impact of different machine parameters and process measurements on overall product quality, from correlation analysis to analysis of variance and chi-square hypothesis testing to help determine the impact of individual measurements on product quality. This design trains some classification and regression models that can distinguish parts that pass quality control from parts that do not. The trained models can be used to infer decision rules. According to the highest purity rule, purity is defined as Nb/N, where N is the number of products that satisfy the rule and Nb is the total number of defective or bad parts that satisfy the rule.Although these models can identify linear and nonlinear relationships between variables, they do not represent causal relationships. Causality is critical to determining the true root cause, using Bayesian causal models to infer causality across all data.3.3 VisualizationA visualization platform for collecting big data is crucial. The main challenge faced by engineers is not having a clear and comprehensive overview of the complete manufacturing process. Such an overview will help them make decisions and assess their status before any adverse events occur. Descriptive analytics uses tools such as Tableau (www.tableau.com) and Microsoft BI (https://powerbi.microsoft.com/en-us) to help achieve this. Descriptive analysis includes many views such as histograms, bivariate plots, and correlation plots. In addition to visual statistical descriptions, a clear visual interface should be provided for all predictive models. All measurements affecting specific quality parameters can be visualized and the data on the backend can be filtered by time.

XN-GWBR-PBDP Intelligent operation control system
XV-102-B5-35TQR-10 Capacitive touch screen and resistive touch screen
XN-KO/8 Capacitive touch screen and resistive touch screen
XV-102-B0-35MQR-10-PLC Capacitive touch screen and resistive touch screen
mc2-440-12tsb-1-1k Capacitive touch screen and resistive touch screen
XN-KO/4 Intelligent operation control system
XV-230-57MPN-1-10-PLC-SET Eaton human-machine touch screen
XV-102-D6-57TVRC-1K Intelligent operation control system
XN-S4S-SBBS-CJ EATON HMI Human Machine Interface
XVS-460-57MPI-1-1E Eaton human-machine touch screen
XV-442-57CQB-1-1R-4 Capacitive touch screen and resistive touch screen
XV-252-57MPN-1-10VAR01 Intelligent operation control system
xv-102-b5-35-tqr-10-plc Intelligent operation control system
XN-ANBZ-SW Capacitive touch screen and resistive touch screen
XV-152-D6-10TVRC-10 EATON HMI Human Machine Interface
XV-102-A5-35MQR-10 Intelligent operation control system
MK2-230-57CNN-1-10 Eaton human-machine touch screen
XVS-440-12MPI-1-10 Eaton human-machine touch screen
MC2-440-10TVB-1-2I Intelligent operation control system
XV-102-B3-35MQR-10-PLC Eaton human-machine touch screen
XVH-340-57CAN-1-10 Human Machine Interaction
XV-102-D6-57TVR-10 Capacitive touch screen and resistive touch screen
XV-460-84TVB-1-1O Human Machine Interaction
XVM-450-65TVB-1-11 Intelligent operation control system
XT-BCB-TP-EPROM-DNET EATON HMI Human Machine Interface
XV-230-57CNN-1-10-PLC-SET Human Machine Interaction
XP-702-D0-BOX-10 EATON Touch Panel
XV-303-70-B00-A00-1C Eaton human-machine touch screen
XCC-601-DVI-V1-000 Intelligent operation control system
XV-442-57cQB1-1W EATON HMI Human Machine Interface
XN-1AI-I(0/4…20MA) Capacitive touch screen and resistive touch screen
XN-4DI-24VDC-P Human Machine Interaction