Hugendubel.info - Die B2B Online-Buchhandlung 

Merkliste
Die Merkliste ist leer.
Bitte warten - die Druckansicht der Seite wird vorbereitet.
Der Druckdialog öffnet sich, sobald die Seite vollständig geladen wurde.
Sollte die Druckvorschau unvollständig sein, bitte schliessen und "Erneut drucken" wählen.

The Future of Design Methodology

E-BookPDF1 - PDF WatermarkE-Book
302 Seiten
Englisch
Springer Londonerschienen am13.04.20112011
The Future of Design Methodology gives a holistic overview of perspectives for design methodology, addresses trends for developing a powerful methodical support for design practice and provides a starting point for future design research. The chapters are written by leading scientists from around the world, who have great expertise in design methodology, as well as the farsightedness needed to develop design methodology further.

The Future of Design Methodology is a detailed contribution to consolidated design methodology and design research. Instead of articulating the views of one scientist, it provides a comprehensive collection of perspectives and visions. The editor highlights the substantial deficiencies and problems of the current design methodology and summarizes the authors' findings to draw future-oriented conclusions. 

The comprehensive overview of the status of design methodology given in The Future of Design Methodology will help enhance the individual scientific development of junior researchers, while the authoritative perspectives on future design methodology will challenge the views of experts. It is suitable for readers working in a wide range of design fields, such as design methodology, engineering design and industrial design.


Herbert Birkhofer was awarded a PhD from the Department of Mechanical Engineering at Technische Universität Braunschweig. He is currently Professor and Head of the Product Development and Machine Elements Institute at Technische Universität Darmstadt. He is a member of the Scientific Association for Machine Elements and Design Research and of Berliner Kreis (association for the advancement of product innovation in German industry). He co-edits the journal Zeitschrift Konstruktion and is Programme Chair of two events: the annual Applied Engineering Design Systems workshops in Czechoslovakia, and the biennial DESIGN conferences in Croatia. His main research interests are product development and design methodology, knowledge management in design, empirical design research, development of environmentally sound products, and lifetime theory of solid-lubricated bearings.mehr
Verfügbare Formate
BuchGebunden
EUR160,49
BuchKartoniert, Paperback
EUR160,49
E-BookPDF1 - PDF WatermarkE-Book
EUR149,79

Produkt

KlappentextThe Future of Design Methodology gives a holistic overview of perspectives for design methodology, addresses trends for developing a powerful methodical support for design practice and provides a starting point for future design research. The chapters are written by leading scientists from around the world, who have great expertise in design methodology, as well as the farsightedness needed to develop design methodology further.

The Future of Design Methodology is a detailed contribution to consolidated design methodology and design research. Instead of articulating the views of one scientist, it provides a comprehensive collection of perspectives and visions. The editor highlights the substantial deficiencies and problems of the current design methodology and summarizes the authors' findings to draw future-oriented conclusions. 

The comprehensive overview of the status of design methodology given in The Future of Design Methodology will help enhance the individual scientific development of junior researchers, while the authoritative perspectives on future design methodology will challenge the views of experts. It is suitable for readers working in a wide range of design fields, such as design methodology, engineering design and industrial design.


Herbert Birkhofer was awarded a PhD from the Department of Mechanical Engineering at Technische Universität Braunschweig. He is currently Professor and Head of the Product Development and Machine Elements Institute at Technische Universität Darmstadt. He is a member of the Scientific Association for Machine Elements and Design Research and of Berliner Kreis (association for the advancement of product innovation in German industry). He co-edits the journal Zeitschrift Konstruktion and is Programme Chair of two events: the annual Applied Engineering Design Systems workshops in Czechoslovakia, and the biennial DESIGN conferences in Croatia. His main research interests are product development and design methodology, knowledge management in design, empirical design research, development of environmentally sound products, and lifetime theory of solid-lubricated bearings.
Details
Weitere ISBN/GTIN9780857296153
ProduktartE-Book
EinbandartE-Book
FormatPDF
Format Hinweis1 - PDF Watermark
FormatE107
Erscheinungsjahr2011
Erscheinungsdatum13.04.2011
Auflage2011
Seiten302 Seiten
SpracheEnglisch
IllustrationenXI, 302 p.
Artikel-Nr.1718827
Rubriken
Genre9200

Inhalt/Kritik

Inhaltsverzeichnis
1;Foreword;5
2;Preface and Acknowledgements;6
3;Contents;7
4;Introduction;10
4.1;1.1 Motivation;10
4.2;1.2 Design Methodology;11
4.2.1;1.2.1 History of Design Methodology;11
4.2.2;1.2.2 Goals and Subjects of Design Methodology;13
4.2.3;1.2.3 Further Development of Design Methodology;14
4.3;1.2 Design Methodology and Design Practice;16
4.4;1.3 Design Research;18
4.4.1;1.3.1 Areas of Activity in Design Research;18
4.4.2;1.3.2 Types of Design Research;20
4.5;1.4 Overview of Contributions to the Book;22
4.6;1.5 References;24
5;Part I Specific Ways to Further Develop
Design Methodology;28
5.1;2 Is Engineering Design Disappearing from
Design Research?;30
5.1.1;2.1 Disappearing Engineering Design?;30
5.1.2;2.2 The Starting Point for Embodiment;31
5.1.3;2.3 What Happens During The Embodiment Stage?;32
5.1.4;2.4 Function Reasoning;33
5.1.5;2.5 Structuring;35
5.1.6;2.6 Property Reasoning;37
5.1.7;2.7 Part Design;38
5.1.8;2.8 Embodiment and Verification;39
5.1.9;2.9 Nature of Human Design;40
5.1.10;2.10 The Challenges in Embodiment Design;40
5.1.11;2.11 Conclusion;42
5.1.12;2.12 Afterword;42
5.1.13;2.13 References;43
5.2;Methodical Support for the Development of
Modular Product Families;44
5.2.1;3.1 Introduction;44
5.2.2;3.2 The Five Attributes of Modular Products and their Effects;45
5.2.3;3.3 Strategies for Controlling External Variety;47
5.2.4;3.4 PKT s Integrated Approach for Developing Modular
Product Families;48
5.2.5;3.4.1 Product Program Planning;49
5.2.6;3.4.2 Design for Variety;50
5.2.7;3.4.3 Life Phases Modularization;51
5.2.8;3.4.4 Process-Oriented Product Development;53
5.2.9;3.4.5 Module Lightweight Design;53
5.2.10;3.5 References;54
5.3;4 Risk-Driven Design Processes: Balancing
Efficiency with Resilience in Product Design;55
5.3.1;4.1 The Challenges of Complex Product Design Projects;55
5.3.2;4.2 Uncertainty and Risk in Product Design;56
5.3.3;4.3 Risk-based View: Risk-Driven Design;58
5.3.4;4.4 Research Agenda;61
5.3.5;4.5 References;61
5.4;5 Methodology and Computer-Aided Tools - a
Powerful Interaction for Product Development;63
5.4.1;5.1 Introduction;63
5.4.2;5.2 The Fundamentals of Product Development;64
5.4.3;5.3 The Interaction between Design Methods and Computer-
Supported Tools (CAx Tools);64
5.4.4;5.4 Examples of Successful Interaction;66
5.4.4.1;5.4.1 DFX;66
5.4.4.2;5.4.2 Calculations and Simulations in Design for Production;67
5.4.4.3;5.4.3 Tolerance Analysis/Visualisation;70
5.4.4.4;5.4.4 Process Modelling;70
5.4.5;5.5 The Future Development of Methodology and CAx tools;71
5.4.6;5.6 Conclusion3;72
5.4.7;5.7 References;72
5.5;6 A Reuse Design Decision Support System Based
on Self-Organizing Maps;74
5.5.1;6.1 Introduction;74
5.5.2;6.2 Analyzing the Combination between Human and Computers;75
5.5.3;6.3 Approach;76
5.5.3.1;6.3.1 Formularization Phase;77
5.5.3.2;6.3.2 Preparation Phase;78
5.5.3.3;6.3.3 Decision Phase;78
5.5.4;6.4 Selecting the Methods for the Three Phases;78
5.5.4.1;6.4.1 Methods for Formalizing the Requirements;79
5.5.5;6.5 Developing a Procedure Model for Selecting a Product
Variant;80
5.5.6;6.6 Case Study;81
5.5.6.1;6.6.1 Implementation;81
5.5.6.2;6.6.2 Analysing the SOM to Make a Decision;82
5.5.7;6.7 Summary;83
5.5.8;6.8 References;83
5.6;7 Increasing Effectiveness and Efficiency of Product Development - A Challenge for Design
Methodologies and Knowledge Management;85
5.6.1;7.1 Present State of and Challenges in Product Development;85
5.6.2;7.2 Objectives for Product Development in the Future;86
5.6.3;7.3 The Contribution of Engineering Design Methodology and
Knowledge Management to Achieving the Objectives;87
5.6.3.1;7.3.1 Requirements on Engineering Design Methodologies;87
5.6.3.2;7.3.2 IKTD s Approach;88
5.6.3.2.1;7.3.2.1 Evaluation of Innovative Product Ideas;89
5.6.3.2.2;7.3.2.2 Systematic Design of Hybrid Intelligent Design Elements (HIKE);90
5.6.3.2.3;7.3.2.3 Proactive Support of Product Development Processes with Multi-Agent Systems (ProKon);92
5.6.3.2.4;7.3.2.4 Evaluation of Product Development Knowledge (PDKbench;93
5.6.4;7.4 Conclusion and Outlook;95
5.6.5;7.5 References;96
5.7;8 Design Theory and Methodology- Contributions to the Computer Support of
Product Development/Design Processes;97
5.7.1;8.1 Introduction;97
5.7.2;8.2 Requirements of Design Theory and Methodology;98
5.7.3;8.3 Theoretical Base;99
5.7.4;8.4 Computer Support in Product Development/Design;103
5.7.5;8.5 Conclusions;109
5.7.6;8.6 References;109
5.8;9 Summary - Specific Approaches to Further
Develop Design Methodology;111
5.8.1;9.1 Intensification and expansion of existing research focuses;111
5.8.2;9.2 Improvement of the revision of work in human-computer relations and the integration of computer usage into Design
Methodology;113
5.8.3;9.3 Fortification of the scientific foundation;114
5.8.4;9.4 Results and recognitions;115
6;Part II Holistic Ways to Supply, Extend or Replace Design Methodology
;117
6.1;10 Boundary Conditions for a New Type of Design
Task: Understanding Product/Service-Systems;119
6.1.1;10.1 Introduction;119
6.1.2;10.2 Broadening Horizons through Boundary Conditions;120
6.1.3;10.3 Six Composite Views of PSS;122
6.1.3.1;10.3.1 Competencies and Disciplines (from Engineering to Innovation);122
6.1.3.2;10.3.2 The Nature of the Offering (from Product to Service);123
6.1.3.3;10.3.3 New Production Forms (from Design to Doing);124
6.1.3.4;10.3.4 Elements of Choice (from Regulation to Choice);125
6.1.3.5;10.3.5 Executional interventions (from User Activity to Provider
Offering);125
6.1.3.6;10.3.6 Perceptions of Value (from Quality to Value);126
6.1.4;10.4 Case: PSS in the Maritime Industry;127
6.1.5;10.5 Discussion and Conclusion;128
6.1.6;10.6 References;129
6.2;11
Product/Service System Design and Beyond;131
6.2.1;11.1 Introduction;131
6.2.2;11.2 Nature of PSS Design: Differences from Traditional
Engineering Design;132
6.2.2.1;11.2.1 Three Dimensions to be Considered;132
6.2.2.2;11.2.2 Reviewing Design Research on PSS;133
6.2.2.3;11.2.3 Future Research Issues;134
6.2.3;11.3 Integrated Development of Technology and the Business
Model;135
6.2.3.1;11.3.1 Implication from Theory;135
6.2.3.2;11.3.2 Industrial Needs;136
6.2.3.3;11.3.3 Existing Knowledge and Research Opportunity;137
6.2.4;11.4 Conclusion;138
6.2.5;11.5 References;138
6.3;12
Open Product Development;141
6.3.1;12.1 Introduction;141
6.3.2;12.2 General Design Theory;143
6.3.3;12.3 Future Design Methodology;143
6.3.3.1;12.3.1 CSL- Company Strategic Landscape;147
6.3.3.2;12.3.2 DFC- Product Configuration;149
6.3.3.3;12.3.3 Kontu: Combined Variation of Product, Manufacturing
Processes and Networks;150
6.3.4;12.4 Conclusions;151
6.3.5;12.5 References;151
6.4;13
Managing Virtual Product Creation;153
6.4.1;13.1 Introduction;153
6.4.2;13.2 Lifecycle Approaches and Workflow Management;155
6.4.2.1;13.2.1Information Technology-driven Product Lifecycle;156
6.4.2.2;13.2.2 Workflow Management;158
6.4.3;13.3 Progress Monitoring and Maturity Management;160
6.4.4;13.4 Conclusion;161
6.4.5;13.5 References;162
6.5;14
Systems Engineering versus Design Methodology;163
6.5.1;14.1 Introduction;163
6.5.2;14.2 Structural Complexity;164
6.5.3;14.3 Requirement Analysis;165
6.5.4;14.4 Knowledge Identification;167
6.5.5;14.5 Design to Cost;168
6.5.6;14.6 Process Planning;170
6.5.7;14.7 Conclusion and Outlook;172
6.5.8;14.8 References;173
6.6;15 The Autogenetic Design Theory Product Development as an Analogy to Biological
Evolution;174
6.6.1;15.1 Introduction;174
6.6.2;15.2 Basic Principles of the Autogenetic Design Theory;175
6.6.3;15.3 The ADT Process Model;177
6.6.4;15.4 The ADT Prohibition Space;179
6.6.5;15.5 The ADT Product Model;181
6.6.6;15.6 Conclusion and Outlook;183
6.6.7;15.7 References;184
6.7;16 Towards a Designer-Centred Methodology: Descriptive Considerations and Prescriptive
Reflections;185
6.7.1;16.1 The PAST: What is Design Methodology Good For?;185
6.7.1.1;16.1.1 The Two Faces of Design Methodology;186
6.7.1.2;16.1.2 Deficits of Design Methodology;187
6.7.2;16.2 The Present: Do Designers Need Design Methodology?;189
6.7.2.1;16.2.1 Uncertainty as a Consequence of Routine and Non-Routine
Situations;190
6.7.2.2;16.2.2 The Users View;191
6.7.3;16.3 THE FUTURE: Design Methodology as A New Business
Model;196
6.7.3.1;16.3.1 Design Thinking as Design Methodology-lite ?;197
6.7.3.2;16.3.2 Implications for the Future of Design Methodology;198
6.7.4;16.4 References;200
6.8;17 A New Perspective on Product Engineering
Overcoming Sequential Process Models;202
6.8.1;17.1 Introduction - Five Hypotheses on Product Engineering;202
6.8.2;17.2 Different Views on Methods and Processes of Product
Engineering;204
6.8.3;17.3 Product Engineering is the Transformation of Objectives
into Objects;207
6.8.4;17.4 Validation;208
6.8.5;17.5 Introducing the Integrated Product Engineering Model
iPeM;210
6.8.6;17.6 Conclusion;211
6.8.7;17.7 References;212
6.9;18 Summary - Holistic Ways to Supply, Extend or
Replace Design Methodology;213
6.9.1;18.1 Object-related extension of Design Methodology towards a
development methodology for Product Service Systems;213
6.9.2;18.2 Process-related extensions of Design Methodology towards a methodology of computer-aided planning and development of
activities;214
6.9.3;18.3 Additions to Design Methodology with holistic methods
derived from other science areas;215
6.9.4;18.4 Alternative design methods with new paradigms;216
6.9.5;18.5 Results and recognitions;218
7;Part III General Reflections on
Design Methodology;220
7.1;19What Designers Can Learn From Leonardo, an
Ingenious Artist, Scientist and Engineer;222
7.1.1;19.1. Leonardo's Life;222
7.1.2;19.2. Some Thesis on Abilities, Skills and Methods in Art,
Science and Design;223
7.1.3;19.3 Leonardo: a First Man of the Modern Era;224
7.1.4;19.4 Useful Methods and Skills of Leonardo;225
7.1.5;19.5 Leonardo's Dream of Flying;227
7.1.6;19.6 Conclusions;228
7.1.7;19.7 References;229
7.2;20
Design ⦠but of What ?;230
7.2.1;20.1 Introduction;230
7.2.2;20.2 The Diffusing Concept of Design;231
7.2.3;20.3 The Changing Context of Design;232
7.2.4;20.4 Conclusions;237
7.2.5;20.5 References;238
7.3;21
Transferring Design Methods into Practice;239
7.3.1;21.1 Introduction;239
7.3.2;21.2 Design Practice Knowledge;241
7.3.3;21.3 Design Research Knowledge;242
7.3.4;21.4 Knowledge Transfer - A Case Study;245
7.3.5;21.5 Conclusions;247
7.3.6;21.6 References;248
7.4;22
Towards a Taxonomy of Design Research Areas;249
7.4.1;22.1 Introduction;249
7.4.2;22.2 Design and Design Research;249
7.4.3;22.3 Future of Design Research;251
7.4.4;22.4 Academic Maturity of the Discipline and Consolidation;252
7.4.5;22.5 Some Initial Proposals;254
7.4.6;22.6 Application of the Taxonomy of Design Research Areas;256
7.4.7;22.7 Summary and Initiations;258
7.4.8;22.8 References;258
7.5;23
Design Research and Education: A University Perspective;260
7.5.1;23.1 Introduction;260
7.5.2;23.2 Design Research at University;262
7.5.3;23.3 Teaching Engineering Design;265
7.5.4;23.4 The Impact of Education Policy;266
7.5.5;23.5 Industrial Needs as a Driver for Design Research;267
7.5.6;23.6 The Future;269
7.5.7;23.7 References;270
7.6;24 The Future of Design Research: Consolidation,
Collaboration and Inter-Disciplinary Learning?;273
7.6.1;24.1 Introduction;273
7.6.2;24.2 Background;274
7.6.3;24.3 Mapping the Design Research Space;276
7.6.3.1;24.3.1 Are There Areas In Which We Can Agree?;276
7.6.3.2;24.3.2 Where Is There Less Agreement?;278
7.6.3.3;24.3.3 Summary;279
7.6.4;24.4 Learning from Other Communities;280
7.6.5;24.5 Conclusion;281
7.6.6;24.6 References;281
7.7;25 Summary - General Reflections on Design
Methodology;283
7.7.1;25.1 Internal and external requirements for developing Design
Methodology;283
7.7.2;25.2 The unsolved problem of Design Methodology transfer into
practice;284
7.7.3;25.3 The creation of Design Methodology by design research;285
7.7.4;25.4 Results and recognition;287
7.8;26
Conclusions;289
7.8.1;26.1 Further development towards a life cycle development
methodology;289
7.8.2;26.2 The further development to a holistic methodology for
company development;290
7.8.3;26.3 Definition of a human-centric Design Methodology;290
7.8.4;26.4 The comprehensive integration of information technology
into Design Methodology;291
7.8.5;26.5 The consolidation of Design Methodology;291
7.8.6;26.6 Closing remarks;292
8;Index;294mehr

Autor

Herbert Birkhofer was awarded a PhD from the Department of Mechanical Engineering at Technische Universität Braunschweig. He is currently Professor and Head of the Product Development and Machine Elements Institute at Technische Universität Darmstadt. He is a member of the Scientific Association for Machine Elements and Design Research and of Berliner Kreis (association for the advancement of product innovation in German industry). He co-edits the journal Zeitschrift Konstruktion and is Programme Chair of two events: the annual Applied Engineering Design Systems workshops in Czechoslovakia, and the biennial DESIGN conferences in Croatia. His main research interests are product development and design methodology, knowledge management in design, empirical design research, development of environmentally sound products, and lifetime theory of solid-lubricated bearings.