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100   $a20120817d2012      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aSystemic design methodologies for electrical energy systems$b[electronic resource] $eanalysis, synthesis and management /$fedited by Xavier Roboam
210   $aHoboken, N.J. $cISTE Ltd. $cJohn Wiley and Sons Inc$d2012
215   $a1 online resource (392 p.)
225 0 $aElectrical engineering series
300   $aDescription based upon print version of record.
311   $a1-84821-388-3 
320   $aIncludes bibliographical references and index.
327   $aCover; Systemic Design Methodologies for Electrical Energy Systems; Title Page; Copyright Page; Table of Contents; Preface; Chapter 1: Introduction to Systemic Design; 1.1. The system and the science of systems; 1.1.1. First notions of systems and systems theory; 1.1.2. A brief history of systems theory and the science of systems; 1.1.3. The science of systems and artifacts; 1.2. The model and the science of systems; 1.3. Energy systems: specific and shared properties; 1.3.1. Energy and its properties; 1.3.2. Entropy and quality of energy; 1.3.3. Consequences for energy systems
327   $a1.4. Systemic design of energy systems1.4.1. The context of systemic design in technology; 1.4.2. The design process: toward an integrated design; 1.5. Conclusion: what are the objectives for an integrated design of energyconversion systems?; 1.6. Glossary of systemic design; 1.7. Bibliography; Chapter 2: The Bond Graph Formalism for an Energetic and Dynamic Approach of the Analysis and Synthesis of Multiphysical Systems; 2.1. Summary of basic principles and elements of the formalism; 2.1.1. Basic elements; 2.1.2. The elementary phenomena; 2.1.3. The causality in bond graphs
327   $a2.2. The bond graph: an "interdisciplinary formalism"2.2.1. "Electro-electrical" conversion; 2.2.2. Electromechanical conversion; 2.2.3. Electrochemical conversion; 2.2.4. Example of a causal multiphysical model: the EHA actuator [GAN 07]; 2.3. The bond graph, tool of system analysis; 2.3.1. Analysis of models properties; 2.3.2. Linear time invariant models; 2.3.3. Simplification of models; 2.4. Design of systems by inversion of bond graph models; 2.4.1. Inverse problems associated with the design approach; 2.4.2. Inversion of systems modeled by bond graph
327   $a2.4.3. Example of application to design problems2.5. Bibliography; Chapter 3: Graphic Formalisms for the Control of Multi-Physical Energetic Systems: COG and EMR; 3.1. Introduction; 3.2. Which approach should be used for the control of an energetic system?; 3.2.1. Control of an energetic system; 3.2.2. Different approaches to the control of a system; 3.2.3. Modeling and control of an energetic system; 3.2.4. Toward the use of graphic formalisms of representation; 3.3. The causal ordering graph; 3.3.1. Description by COG; 3.3.2. Structure of control by inversion of the COG
327   $a3.3.3. Elementary example: control of a DC drive3.4. Energetic Macroscopic Representation; 3.4.1. Description by EMR; 3.4.2. Structure of control by inversion of an EMR; 3.4.3. Elementary example: control of an electrical vehicle; 3.5. Complementarity of the approaches and extensions; 3.5.1. Differences and complementarities; 3.5.2. Example: control of a paper band winder/unwinder; 3.5.3. Other applications and extensions; 3.6. Bibliography; Chapter 4: The Robustness: A New Approach for the Integration of Energetic Systems; 4.1. Introduction; 4.2. Control design of electrical systems
327   $a4.2.1. The control design is an issue of integration
330   $aThis book proposes systemic design methodologies applied to electrical energy systems, in particular analysis and system management, modeling and sizing tools.It includes 8 chapters: after an introduction to the systemic approach (history, basics & fundamental issues, index terms) for designing energy systems, this book presents two different graphical formalisms especially dedicated to multidisciplinary devices modeling, synthesis and analysis: Bond Graph and COG/EMR. Other systemic analysis approaches for quality and stability of systems, as well as for safety and robustness analysis
410  0$aISTE
606   $aElectric power systems$xDesign and construction
615  0$aElectric power systems$xDesign and construction.
676   $a621.3
701   $aRoboam$b Xavier$0867762
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910830442303321
996   $aSystemic design methodologies for electrical energy systems$94084728
997   $aUNINA