Coverart for item
The Resource Bond graphs for modelling, control and fault diagnosis of engineering systems, Wolfgang Borutzky, editor

Bond graphs for modelling, control and fault diagnosis of engineering systems, Wolfgang Borutzky, editor

Label
Bond graphs for modelling, control and fault diagnosis of engineering systems
Title
Bond graphs for modelling, control and fault diagnosis of engineering systems
Statement of responsibility
Wolfgang Borutzky, editor
Contributor
Subject
Language
eng
Summary
This compilation of contributions from experts across the world addresses readers in academia and industry who are concerned with control system design. It covers theoretical topics, applications in various areas as well as software for bond graph modelling
Dewey number
  • 620.01/51
  • 620
Index
no index present
Literary form
non fiction
Nature of contents
dictionaries
http://library.link/vocab/relatedWorkOrContributorName
Borutzky, Wolfgang
http://library.link/vocab/subjectName
  • Bond graphs
  • Engineering models
  • Systems engineering
Label
Bond graphs for modelling, control and fault diagnosis of engineering systems, Wolfgang Borutzky, editor
Instantiates
Publication
Note
4.2.4 Dynamic Causality Notation and the Reference Configuration
Antecedent source
file reproduced from an electronic resource
Contents
  • Foreword; Preface; Acknowledgements; Contents; Contributors; Abbreviations; Part I Bond Graph Theory and Methodology; 1 Decomposition of Multiports; 1.1 Introduction; 1.2 Dynamic System Models of Multidomain Physical Systems: The Key Role of Time; 1.3 Multiport Storage; 1.4 Resolution of an Analogy Paradox; 1.5 Properties of an Irreversible Transducer; 1.6 Influence of the Environment; 1.7 Co-Energy; 1.8 Decomposition of the Power Continuous Multiport; 1.9 Representation of Irreversibility; 1.10 Decomposition into Basic Elements; 1.11 Conclusion; References
  • 2 A Method for Minimizing the Set of Equations in Bond Graph Systems with Causal LoopsAbbreviations; 2.1 Introduction; 2.2 Zero-Order Causal Paths; 2.3 ZCP Class 1; 2.4 ZCP Class 2; 2.5 ZCP Class 3; 2.6 ZCP Class 4; 2.7 ZCP with a Loop-Gain Equal to 1; 2.8 Combinations of Several ZCPs; 2.8.1 Combination Between Two ZCPs Class 3; 2.8.2 Combination Between ZCPs Class 2 and 4; 2.9 Conclusions; References; 3 Controlled Switched Structures for Bond-Graph Modelling and Simulation of Hybrid Systems; 3.1 Introduction
  • 3.2 Summary Review of Some Bond-Graph Devices for Modelling Switching Systems and Auxiliary Tools3.2.1 Bond-Graph Switching Devices; 3.2.2 Auxiliary Tools; 3.2.2.1 Residual Sinks; 3.2.2.2 Conservation of Charge and Impulse and Integrator Resetting; 3.3 Switchable-Structure Bond; 3.3.1 Formal Definition of SS-Bond; 3.3.2 SS-Bond Internal Realization; 3.3.3 Modelling Example: Series RLC Circuit; 3.3.4 Modelling Other Switched Formalisms Using SS-Bonds; 3.3.4.1 Modelling the Switchable Bond Using SS-Bond; 3.3.4.2 Mode 1: Electrical Switch ON and Diode OFF
  • 3.3.4.3 Mode 2: Electrical Switch OFF, Diode ON3.3.4.4 Modelling the Ideal Switch Element Using SS-Bond; 3.3.5 Application Example: Modelling Stick-Slip Friction with SS-Bonds; 3.3.5.1 Application Example; 3.3.5.2 Simulation Results; 3.4 Generalized Switched Junction Structures; 3.4.1 Formal Definition of the GSJ; 3.4.2 GSJ Internal Realization; 3.4.3 Modelling Example: Series RLC Circuit; 3.4.4 Modelling Other Switched Formalisms Using GSJ; 3.4.4.1 Representing CJ with Fixed Causality Using GSJ; 3.4.4.2 Representing Switched Power Junction using GSJ
  • 3.4.5 Application Example: Z-Source DC Breaker3.4.5.1 Z-Source DC Circuit Breaker; 3.4.5.2 Simulation Results; 3.5 Non-Instantaneous or Soft-Switching Modelling; 3.5.1 Soft-Switching Approach in the Stick-SlipFriction Example; 3.5.2 Soft-Switching Approach in the Z-Source DC Breaker; 3.6 Conclusions; References; 4 Dynamic Causality in Hybrid Bond Graphs; 4.1 Introduction; 4.1.1 Dynamic Causality; 4.1.2 Categorising Discontinuities; 4.2 Structural Discontinuities; 4.2.1 The Controlled Junction; 4.2.2 Simplification of the Hybrid Bond Graph; 4.2.3 The Dynamic Causality Assignment Procedure
Control code
ocn967891871
Dimensions
unknown
Edition
2nd ed
Extent
1 online resource (680 pages)
File format
one file format
Form of item
online
Isbn
9783319474335
Level of compression
unknown
Quality assurance targets
unknown
Reformatting quality
unknown
Specific material designation
remote
System control number
(OCoLC)967891871
Label
Bond graphs for modelling, control and fault diagnosis of engineering systems, Wolfgang Borutzky, editor
Publication
Note
4.2.4 Dynamic Causality Notation and the Reference Configuration
Antecedent source
file reproduced from an electronic resource
Contents
  • Foreword; Preface; Acknowledgements; Contents; Contributors; Abbreviations; Part I Bond Graph Theory and Methodology; 1 Decomposition of Multiports; 1.1 Introduction; 1.2 Dynamic System Models of Multidomain Physical Systems: The Key Role of Time; 1.3 Multiport Storage; 1.4 Resolution of an Analogy Paradox; 1.5 Properties of an Irreversible Transducer; 1.6 Influence of the Environment; 1.7 Co-Energy; 1.8 Decomposition of the Power Continuous Multiport; 1.9 Representation of Irreversibility; 1.10 Decomposition into Basic Elements; 1.11 Conclusion; References
  • 2 A Method for Minimizing the Set of Equations in Bond Graph Systems with Causal LoopsAbbreviations; 2.1 Introduction; 2.2 Zero-Order Causal Paths; 2.3 ZCP Class 1; 2.4 ZCP Class 2; 2.5 ZCP Class 3; 2.6 ZCP Class 4; 2.7 ZCP with a Loop-Gain Equal to 1; 2.8 Combinations of Several ZCPs; 2.8.1 Combination Between Two ZCPs Class 3; 2.8.2 Combination Between ZCPs Class 2 and 4; 2.9 Conclusions; References; 3 Controlled Switched Structures for Bond-Graph Modelling and Simulation of Hybrid Systems; 3.1 Introduction
  • 3.2 Summary Review of Some Bond-Graph Devices for Modelling Switching Systems and Auxiliary Tools3.2.1 Bond-Graph Switching Devices; 3.2.2 Auxiliary Tools; 3.2.2.1 Residual Sinks; 3.2.2.2 Conservation of Charge and Impulse and Integrator Resetting; 3.3 Switchable-Structure Bond; 3.3.1 Formal Definition of SS-Bond; 3.3.2 SS-Bond Internal Realization; 3.3.3 Modelling Example: Series RLC Circuit; 3.3.4 Modelling Other Switched Formalisms Using SS-Bonds; 3.3.4.1 Modelling the Switchable Bond Using SS-Bond; 3.3.4.2 Mode 1: Electrical Switch ON and Diode OFF
  • 3.3.4.3 Mode 2: Electrical Switch OFF, Diode ON3.3.4.4 Modelling the Ideal Switch Element Using SS-Bond; 3.3.5 Application Example: Modelling Stick-Slip Friction with SS-Bonds; 3.3.5.1 Application Example; 3.3.5.2 Simulation Results; 3.4 Generalized Switched Junction Structures; 3.4.1 Formal Definition of the GSJ; 3.4.2 GSJ Internal Realization; 3.4.3 Modelling Example: Series RLC Circuit; 3.4.4 Modelling Other Switched Formalisms Using GSJ; 3.4.4.1 Representing CJ with Fixed Causality Using GSJ; 3.4.4.2 Representing Switched Power Junction using GSJ
  • 3.4.5 Application Example: Z-Source DC Breaker3.4.5.1 Z-Source DC Circuit Breaker; 3.4.5.2 Simulation Results; 3.5 Non-Instantaneous or Soft-Switching Modelling; 3.5.1 Soft-Switching Approach in the Stick-SlipFriction Example; 3.5.2 Soft-Switching Approach in the Z-Source DC Breaker; 3.6 Conclusions; References; 4 Dynamic Causality in Hybrid Bond Graphs; 4.1 Introduction; 4.1.1 Dynamic Causality; 4.1.2 Categorising Discontinuities; 4.2 Structural Discontinuities; 4.2.1 The Controlled Junction; 4.2.2 Simplification of the Hybrid Bond Graph; 4.2.3 The Dynamic Causality Assignment Procedure
Control code
ocn967891871
Dimensions
unknown
Edition
2nd ed
Extent
1 online resource (680 pages)
File format
one file format
Form of item
online
Isbn
9783319474335
Level of compression
unknown
Quality assurance targets
unknown
Reformatting quality
unknown
Specific material designation
remote
System control number
(OCoLC)967891871

Library Locations

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