Machine Learning for Cyber Physical Systems : : Selected Papers from the International Conference ML4CPS 2020.
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Superior document: | Technologien Für Die Intelligente Automation Series ; v.13 |
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Place / Publishing House: | Berlin, Heidelberg : : Springer Berlin / Heidelberg,, 2020. {copy}2021. |
Year of Publication: | 2020 |
Edition: | 1st ed. |
Language: | English |
Series: | Technologien Für Die Intelligente Automation Series
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Physical Description: | 1 online resource (129 pages) |
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Beyerer, Jürgen. Machine Learning for Cyber Physical Systems : Selected Papers from the International Conference ML4CPS 2020. 1st ed. Berlin, Heidelberg : Springer Berlin / Heidelberg, 2020. {copy}2021. 1 online resource (129 pages) text txt rdacontent computer c rdamedia online resource cr rdacarrier Technologien Für Die Intelligente Automation Series ; v.13 Intro -- Preface -- Table of Contents -- 1 Energy Profile Prediction of Milling Processes Using Machine Learning Techniques -- 1 Einleitung -- 2 Methode -- 3 Datenerhebung und -aufbereitung -- 3.1 Gewinnung der Zielwerte Energie- und Zeitbedarf -- 3.2 Gewinnung der Inputparameter für die Regressionsmodelle -- 3.3 Feature Engineering -- 4 Modellbildung -- 5 Ergebnisse und Validierung -- 6 Diskussion und Ausblick -- References -- 2 Improvement of the prediction quality of electrical load profiles with artificial neural networks -- 1 Introduction -- 2 Analysis of the load profiles -- 2.1 Primary data preparation and plausibility check -- 2.2 Data analysis and creation load profile classes -- 2.3 Parameter estimation -- 2.4 Splitting the data sets -- 3 Artificial neural network as prediction model -- 3.1 Research studies -- 3.2 Basic specifications of the model -- 3.3 Investigation scenarios -- 4 Simulation and evaluation of the results -- 5 Conclusion and Outlook -- References -- 3 Detection and localization of an underwater docking station in acoustic images using machine learning and generalized fuzzy hough transform -- 1 Introduction -- 2 Methodology -- 3 Experimental results -- 4 Conclusions and future work -- 5 Acknowledgements -- References -- 4 Deployment architecture for the local delivery of ML-Models to the industrial shop floor -- 1 Introduction -- 2 Aim of the presented work -- 3 Related Work -- 4 Architecture -- 5 Data connectivity and collection -- 6 ML-Model Serving -- 7 Monitoring Strategies -- 8 Lifecycle Management -- 9 Discussion -- 10 Acknowledgement -- References -- 5 Deep Learning in Resource and Data Constrained Edge Computing Systems -- 1 Introduction -- 2 Methods & -- Related Work -- 2.1 Variational Autoencoder -- 2.2 Federated Learning -- 3 Results -- 3.1 Clustering and Visualization of Wafermap Patterns. 3.2 Anomaly Detection for Sensor Data of a Furnace -- 3.3 Predictive Maintenance using Federated Learning on Edge Devices -- 4 Conclusion -- References -- 6 Prediction of Batch Processes Runtime Applying Dynamic Time Warping and Survival Analysis -- 1 Introduction -- 2 Dynamic Time Warping -- 3 Survival Analysis -- 4 Data -- 5 Proposed System -- 6 Results -- 7 Conclusion -- References -- 7 Proposal for requirements on industrial AI solutions -- 1 Introduction -- 1.1 Usage of AI in Industrial Production -- 1.2 Industrial AI -- 2 Requirements on industrial AI -- 2.1 Adaption of Industrial AI systems -- 2.2 Engineering of Industrial AI systems -- 2.3 Embedding of Industrial AI system in existing production system landscape -- 2.4 Safety and Security of Industrial AI systems -- 2.5 Trust in functionality of Industrial AI systems -- 3 Discussion -- 4 Conclusion -- Acknowledgements -- References -- 8 Information modeling and knowledge extraction for machine learning applications in industrial production systems -- 1 Introduction -- 2 Information modeling -- 3 Tool chain for knowledge extraction -- 4 Conclusion -- 5 Acknowledgement -- Appendix: Entities of the proposed information model -- References -- 9 Explanation Framework for Intrusion Detection -- 1 Introduction -- 2 Explanations for Intrusion Detection -- 3 The Modular Phases of Explanations -- 4 Experiment -- 5 Summary -- References -- 10 Automatic Generation of Improvement Suggestions for Legacy, PLC Controlled Manufacturing Equipment Utilizing Machine Learning -- 1 Introduction -- 2 Related Works -- 3 Hypothesis -- 4 Evaluation -- 5 Conclusion And Future Works -- References -- 11 Hardening Deep Neural Networks in Condition Monitoring Systems against Adversarial Example Attacks -- 1 Introduction -- 2 Related work -- 3 Solution -- 4 Results -- 5 Conclusion -- References. 12 First Approaches to Automatically Diagnose and Reconfigure Hybrid Cyber-Physical Systems -- 1 Introduction -- 2 State of the Art -- 3 The multiple-tank model -- 4 Diagnosing Hybrid Systems -- 5 Reconfiguration after faults occurred -- 6 Conclusion and future work -- 7 Acknowledgement -- References -- 13 Machine learning for reconstruction of highly porous structures from FIB-SEM nano-tomographic data -- 1 Introduction -- 2 Network architecture and and training the model -- 3 Results -- 4 Conclusion -- References. Description based on publisher supplied metadata and other sources. Electronic reproduction. Ann Arbor, Michigan : ProQuest Ebook Central, 2024. Available via World Wide Web. Access may be limited to ProQuest Ebook Central affiliated libraries. Electronic books. Maier, Alexander. Niggemann, Oliver. Print version: Beyerer, Jürgen Machine Learning for Cyber Physical Systems Berlin, Heidelberg : Springer Berlin / Heidelberg,c2020 9783662627457 ProQuest (Firm) Technologien Für Die Intelligente Automation Series https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=6436125 Click to View |
language |
English |
format |
eBook |
author |
Beyerer, Jürgen. |
spellingShingle |
Beyerer, Jürgen. Machine Learning for Cyber Physical Systems : Selected Papers from the International Conference ML4CPS 2020. Technologien Für Die Intelligente Automation Series ; Intro -- Preface -- Table of Contents -- 1 Energy Profile Prediction of Milling Processes Using Machine Learning Techniques -- 1 Einleitung -- 2 Methode -- 3 Datenerhebung und -aufbereitung -- 3.1 Gewinnung der Zielwerte Energie- und Zeitbedarf -- 3.2 Gewinnung der Inputparameter für die Regressionsmodelle -- 3.3 Feature Engineering -- 4 Modellbildung -- 5 Ergebnisse und Validierung -- 6 Diskussion und Ausblick -- References -- 2 Improvement of the prediction quality of electrical load profiles with artificial neural networks -- 1 Introduction -- 2 Analysis of the load profiles -- 2.1 Primary data preparation and plausibility check -- 2.2 Data analysis and creation load profile classes -- 2.3 Parameter estimation -- 2.4 Splitting the data sets -- 3 Artificial neural network as prediction model -- 3.1 Research studies -- 3.2 Basic specifications of the model -- 3.3 Investigation scenarios -- 4 Simulation and evaluation of the results -- 5 Conclusion and Outlook -- References -- 3 Detection and localization of an underwater docking station in acoustic images using machine learning and generalized fuzzy hough transform -- 1 Introduction -- 2 Methodology -- 3 Experimental results -- 4 Conclusions and future work -- 5 Acknowledgements -- References -- 4 Deployment architecture for the local delivery of ML-Models to the industrial shop floor -- 1 Introduction -- 2 Aim of the presented work -- 3 Related Work -- 4 Architecture -- 5 Data connectivity and collection -- 6 ML-Model Serving -- 7 Monitoring Strategies -- 8 Lifecycle Management -- 9 Discussion -- 10 Acknowledgement -- References -- 5 Deep Learning in Resource and Data Constrained Edge Computing Systems -- 1 Introduction -- 2 Methods & -- Related Work -- 2.1 Variational Autoencoder -- 2.2 Federated Learning -- 3 Results -- 3.1 Clustering and Visualization of Wafermap Patterns. 3.2 Anomaly Detection for Sensor Data of a Furnace -- 3.3 Predictive Maintenance using Federated Learning on Edge Devices -- 4 Conclusion -- References -- 6 Prediction of Batch Processes Runtime Applying Dynamic Time Warping and Survival Analysis -- 1 Introduction -- 2 Dynamic Time Warping -- 3 Survival Analysis -- 4 Data -- 5 Proposed System -- 6 Results -- 7 Conclusion -- References -- 7 Proposal for requirements on industrial AI solutions -- 1 Introduction -- 1.1 Usage of AI in Industrial Production -- 1.2 Industrial AI -- 2 Requirements on industrial AI -- 2.1 Adaption of Industrial AI systems -- 2.2 Engineering of Industrial AI systems -- 2.3 Embedding of Industrial AI system in existing production system landscape -- 2.4 Safety and Security of Industrial AI systems -- 2.5 Trust in functionality of Industrial AI systems -- 3 Discussion -- 4 Conclusion -- Acknowledgements -- References -- 8 Information modeling and knowledge extraction for machine learning applications in industrial production systems -- 1 Introduction -- 2 Information modeling -- 3 Tool chain for knowledge extraction -- 4 Conclusion -- 5 Acknowledgement -- Appendix: Entities of the proposed information model -- References -- 9 Explanation Framework for Intrusion Detection -- 1 Introduction -- 2 Explanations for Intrusion Detection -- 3 The Modular Phases of Explanations -- 4 Experiment -- 5 Summary -- References -- 10 Automatic Generation of Improvement Suggestions for Legacy, PLC Controlled Manufacturing Equipment Utilizing Machine Learning -- 1 Introduction -- 2 Related Works -- 3 Hypothesis -- 4 Evaluation -- 5 Conclusion And Future Works -- References -- 11 Hardening Deep Neural Networks in Condition Monitoring Systems against Adversarial Example Attacks -- 1 Introduction -- 2 Related work -- 3 Solution -- 4 Results -- 5 Conclusion -- References. 12 First Approaches to Automatically Diagnose and Reconfigure Hybrid Cyber-Physical Systems -- 1 Introduction -- 2 State of the Art -- 3 The multiple-tank model -- 4 Diagnosing Hybrid Systems -- 5 Reconfiguration after faults occurred -- 6 Conclusion and future work -- 7 Acknowledgement -- References -- 13 Machine learning for reconstruction of highly porous structures from FIB-SEM nano-tomographic data -- 1 Introduction -- 2 Network architecture and and training the model -- 3 Results -- 4 Conclusion -- References. |
author_facet |
Beyerer, Jürgen. Maier, Alexander. Niggemann, Oliver. |
author_variant |
j b jb |
author2 |
Maier, Alexander. Niggemann, Oliver. |
author2_variant |
a m am o n on |
author2_role |
TeilnehmendeR TeilnehmendeR |
author_sort |
Beyerer, Jürgen. |
title |
Machine Learning for Cyber Physical Systems : Selected Papers from the International Conference ML4CPS 2020. |
title_sub |
Selected Papers from the International Conference ML4CPS 2020. |
title_full |
Machine Learning for Cyber Physical Systems : Selected Papers from the International Conference ML4CPS 2020. |
title_fullStr |
Machine Learning for Cyber Physical Systems : Selected Papers from the International Conference ML4CPS 2020. |
title_full_unstemmed |
Machine Learning for Cyber Physical Systems : Selected Papers from the International Conference ML4CPS 2020. |
title_auth |
Machine Learning for Cyber Physical Systems : Selected Papers from the International Conference ML4CPS 2020. |
title_new |
Machine Learning for Cyber Physical Systems : |
title_sort |
machine learning for cyber physical systems : selected papers from the international conference ml4cps 2020. |
series |
Technologien Für Die Intelligente Automation Series ; |
series2 |
Technologien Für Die Intelligente Automation Series ; |
publisher |
Springer Berlin / Heidelberg, |
publishDate |
2020 |
physical |
1 online resource (129 pages) |
edition |
1st ed. |
contents |
Intro -- Preface -- Table of Contents -- 1 Energy Profile Prediction of Milling Processes Using Machine Learning Techniques -- 1 Einleitung -- 2 Methode -- 3 Datenerhebung und -aufbereitung -- 3.1 Gewinnung der Zielwerte Energie- und Zeitbedarf -- 3.2 Gewinnung der Inputparameter für die Regressionsmodelle -- 3.3 Feature Engineering -- 4 Modellbildung -- 5 Ergebnisse und Validierung -- 6 Diskussion und Ausblick -- References -- 2 Improvement of the prediction quality of electrical load profiles with artificial neural networks -- 1 Introduction -- 2 Analysis of the load profiles -- 2.1 Primary data preparation and plausibility check -- 2.2 Data analysis and creation load profile classes -- 2.3 Parameter estimation -- 2.4 Splitting the data sets -- 3 Artificial neural network as prediction model -- 3.1 Research studies -- 3.2 Basic specifications of the model -- 3.3 Investigation scenarios -- 4 Simulation and evaluation of the results -- 5 Conclusion and Outlook -- References -- 3 Detection and localization of an underwater docking station in acoustic images using machine learning and generalized fuzzy hough transform -- 1 Introduction -- 2 Methodology -- 3 Experimental results -- 4 Conclusions and future work -- 5 Acknowledgements -- References -- 4 Deployment architecture for the local delivery of ML-Models to the industrial shop floor -- 1 Introduction -- 2 Aim of the presented work -- 3 Related Work -- 4 Architecture -- 5 Data connectivity and collection -- 6 ML-Model Serving -- 7 Monitoring Strategies -- 8 Lifecycle Management -- 9 Discussion -- 10 Acknowledgement -- References -- 5 Deep Learning in Resource and Data Constrained Edge Computing Systems -- 1 Introduction -- 2 Methods & -- Related Work -- 2.1 Variational Autoencoder -- 2.2 Federated Learning -- 3 Results -- 3.1 Clustering and Visualization of Wafermap Patterns. 3.2 Anomaly Detection for Sensor Data of a Furnace -- 3.3 Predictive Maintenance using Federated Learning on Edge Devices -- 4 Conclusion -- References -- 6 Prediction of Batch Processes Runtime Applying Dynamic Time Warping and Survival Analysis -- 1 Introduction -- 2 Dynamic Time Warping -- 3 Survival Analysis -- 4 Data -- 5 Proposed System -- 6 Results -- 7 Conclusion -- References -- 7 Proposal for requirements on industrial AI solutions -- 1 Introduction -- 1.1 Usage of AI in Industrial Production -- 1.2 Industrial AI -- 2 Requirements on industrial AI -- 2.1 Adaption of Industrial AI systems -- 2.2 Engineering of Industrial AI systems -- 2.3 Embedding of Industrial AI system in existing production system landscape -- 2.4 Safety and Security of Industrial AI systems -- 2.5 Trust in functionality of Industrial AI systems -- 3 Discussion -- 4 Conclusion -- Acknowledgements -- References -- 8 Information modeling and knowledge extraction for machine learning applications in industrial production systems -- 1 Introduction -- 2 Information modeling -- 3 Tool chain for knowledge extraction -- 4 Conclusion -- 5 Acknowledgement -- Appendix: Entities of the proposed information model -- References -- 9 Explanation Framework for Intrusion Detection -- 1 Introduction -- 2 Explanations for Intrusion Detection -- 3 The Modular Phases of Explanations -- 4 Experiment -- 5 Summary -- References -- 10 Automatic Generation of Improvement Suggestions for Legacy, PLC Controlled Manufacturing Equipment Utilizing Machine Learning -- 1 Introduction -- 2 Related Works -- 3 Hypothesis -- 4 Evaluation -- 5 Conclusion And Future Works -- References -- 11 Hardening Deep Neural Networks in Condition Monitoring Systems against Adversarial Example Attacks -- 1 Introduction -- 2 Related work -- 3 Solution -- 4 Results -- 5 Conclusion -- References. 12 First Approaches to Automatically Diagnose and Reconfigure Hybrid Cyber-Physical Systems -- 1 Introduction -- 2 State of the Art -- 3 The multiple-tank model -- 4 Diagnosing Hybrid Systems -- 5 Reconfiguration after faults occurred -- 6 Conclusion and future work -- 7 Acknowledgement -- References -- 13 Machine learning for reconstruction of highly porous structures from FIB-SEM nano-tomographic data -- 1 Introduction -- 2 Network architecture and and training the model -- 3 Results -- 4 Conclusion -- References. |
isbn |
9783662627464 9783662627457 |
callnumber-first |
T - Technology |
callnumber-subject |
TK - Electrical and Nuclear Engineering |
callnumber-label |
TK7895 |
callnumber-sort |
TK 47895 E42 |
genre |
Electronic books. |
genre_facet |
Electronic books. |
url |
https://ebookcentral.proquest.com/lib/oeawat/detail.action?docID=6436125 |
illustrated |
Not Illustrated |
oclc_num |
1231609193 |
work_keys_str_mv |
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Technologien Für Die Intelligente Automation Series ; v.13 |
is_hierarchy_title |
Machine Learning for Cyber Physical Systems : Selected Papers from the International Conference ML4CPS 2020. |
container_title |
Technologien Für Die Intelligente Automation Series ; v.13 |
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