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Umfang: 1 Online-Ressource (306 Seiten)

ISBN: 9783030783686

Anmerkung: Description based on publisher supplied metadata and other sources , Intro -- Foreword -- Preface and Acknowledgments -- Contents -- Part I: Methods for Product Development and Management -- Chapter 1: From Agile Strategic Foresight to Sustainable Mechatronic and Cyber-Physical Systems in Circular Economies -- 1.1 Introduction -- 1.2 Generic Product Creation System -- 1.3 Building Blocks of Holistic Product Creation -- 1.3.1 New V-Model for Mechatronic and Cyber-Physical Systems -- 1.3.2 Model Based Systems Engineering -- 1.3.3 Agile Strategic Planning -- 1.3.4 Resilient Requirements Engineering (RRE) -- 1.3.5 Digital Worker and Learning Assistance -- 1.4 Summary and Outlook -- References -- Chapter 2: Model of SGE: System Generation Engineering as Basis for Structured Planning and Management of Development -- 2.1 Motivation and Requirements for a Description Model as Basis for Planning and Management of Development -- 2.2 Fundamental Elements and Hypotheses in the Model of SGE: System Generation Engineering -- 2.3 Variation Types and Reference System Characteristics as Key Factors for Innovation Potential and Development Risks, Planni... -- 2.4 Methodical Support of Variations -- 2.5 Conclusion and Outlook -- References -- Chapter 3: Technical Inheritance as an Approach to Data-Driven Product Development -- 3.1 Evolution in Technology and Generation Oriented Product Development -- 3.1.1 Evolutionary Processes in Nature and Technology -- 3.1.2 The Role of Data in the Development, Monitoring and Analysis of Modern Products -- 3.2 Paradigm of Technical Inheritance -- 3.2.1 Evolutionary Mechanisms in Technology -- 3.2.2 Process of Information Transfer -- 3.2.3 Framework of Technical Inheritance -- 3.3 Application Examples of Algorithmic Data Feedback for Technical Inheritance -- 3.3.1 Representation of the Process of Information Feedback for the Development of Structural Mechanical Components Under Dyna , 3.3.2 Application of Technical Inheritance for the Design, Monitoring and Operation of a Technical System at the Example of an... -- 3.4 Conclusions -- References -- Chapter 4: Application of Agile Experiential Learning Based on Reverse Engineering as Support in Product Development -- 4.1 Importance of Product Knowledge in the Early Phase of Product Development -- 4.2 Integration of Reference Product Knowledge into Product Development -- 4.3 Online Media as a Source of Product Knowledge -- 4.4 Recommendations and Practical Example of Use -- References -- Part II: Methods for Specific Systems and Products -- Chapter 5: Improving Products by Combining Usability and Emotions -- 5.1 Introduction -- 5.2 Usability and Emotions in Product Design -- 5.3 Dual User Integration -- 5.4 Application for Computer-Aided Design of Emotional Impressions and Physical Capacities (ACADE+P) -- 5.5 Discussion -- 5.6 Conclusion and Outlook -- References -- Chapter 6: Challenges in the Development of Biomechatronic Systems -- 6.1 Introduction -- 6.2 Biomechatronics -- 6.3 Concept Development of Biomechatronic Systems -- 6.4 Modeling of Biomechatronic Systems -- 6.4.1 Structural Modeling of Biomechatronic Systems -- 6.4.2 Model-Based Concept Development of Biomechatronic Systems -- 6.4.3 Simulation-Based Concept Development of Biomechatronic Systems -- 6.5 Procedure in Modeling and Simulation of Biomechatronic Systems -- 6.5.1 Medical Technology Lead Example: Development of a Movement Trainer to Promote Implant Healing of Hip Endoprostheses -- 6.5.2 Bionics Lead Example: Transfer of Musculoskeletal Lightweight Design to Technical Applications -- 6.6 Summary and Conclusion -- References -- Chapter 7: Design Methodologies for Sustainable Mobility Systems -- 7.1 Introduction -- 7.2 Design for Sustainability , 7.3 Social Sustainability in Vehicle Design: A Case Study for Urban Service Robots -- 7.3.1 Vehicle Design -- 7.3.2 Integrating and Evaluating Social Sustainability in the Design Process -- 7.4 Design of Sustainable Mobility Systems -- 7.4.1 Motorized Individual Transport -- 7.4.2 Urban Freight Transport -- 7.4.3 Electric Bus Systems -- 7.5 Summary and Outlook -- References -- Chapter 8: Methods for In Situ Sensor Integration -- 8.1 Introduction -- 8.2 Identification of Potential Measurands and Measuring Locations -- 8.3 Identification and Consideration of Measuring Uncertainty -- 8.4 Approach: Sensing Machine Elements -- References -- Part III: Facing the Challenges in Product Development -- Chapter 9: Context-Adapted Methods of Modern Product Development: Recommendations and Best Practice Examples -- 9.1 Introduction -- 9.2 Clarification of Terms and Situation Analysis -- 9.3 Superordinate Aspects of a Method Development -- 9.4 Best Practice Examples of Methods for Developing Context-Appropriate Support -- 9.4.1 Best Practice for Generating and Documenting Appropriate Problem Ideas -- 9.4.2 Best Practice for the Selection of Methods Appropriate to the Situation -- 9.4.3 Best Practice for the Demand-Driven Provision and Employment of Methods -- 9.4.4 Best Practice for the Company-Adapted Implementation of Processes and Methods in Companies -- 9.5 Conclusion -- References -- Chapter 10: An Approach to Develop Designer-Centred Methods: Illustrated by an Example on How to Overcome Cognitive Bias in Pr... -- 10.1 How to Develop Designer-Centred Methods? -- 10.1.1 Assessing Ways of Designer Thinking -- 10.1.2 Designer-Centred Method Synthesis -- 10.1.3 Design Method Validation -- 10.2 Method Development to Overcome Cognitive Bias in Product Development , 10.2.1 Assessing Ways of Designer Thinking: Identifying the Influence of Confirmation Bias on Designers' Understanding of Prob... -- 10.2.2 Method Development: Design-ACH to Avoid Misunderstanding of Design Problems -- 10.2.3 Method Validation: Impact of the Design-ACH -- 10.3 Implications for Future Method Development -- References -- Chapter 11: Data and Information Flow Design in Product Development -- 11.1 Introduction -- 11.2 Basic Considerations and Framework Conditions for Data and Information Flows in Development -- 11.2.1 Implications from Macrologic -- 11.2.2 Implications from Micrologic -- 11.2.3 Implications from the Organisation of Development Processes -- 11.3 Methodology for the Analysis and Assessment of Data Needs -- 11.4 Integration of Designer in Data- and Information Flow by Using Agile Methods -- 11.4.1 Basic Considerations on Agile Working -- 11.4.2 Meaning and Working Methods -- 11.4.3 Impact of the Use of Agile Methods on Data and Information Flows -- 11.5 Importance of Methods and Process Acceptance -- References -- Part IV: Model-Based Engineering in Product Development -- Chapter 12: Model-Based Systems Engineering: A New Way for Function-Driven Product Development -- 12.1 Introduction and Motivation for Function-Driven Product Development -- 12.2 Types and Applications of Functional Descriptions in Product Development -- 12.2.1 Functions in Design Theory and Methodology -- 12.2.2 Some Notes -- 12.2.3 Role and Applications of Functional Descriptions -- 12.2.4 Computer Support and Early Attempts of Functional Modelling -- 12.3 Overview over MBSE and SysML as Modelling Language -- 12.3.1 Systems Engineering (SE) -- 12.3.2 Model-Based Systems Engineering (MBSE) and SysML -- 12.3.3 Diagrams in SysML -- 12.3.4 Elements and Relations Between them in SysML -- 12.3.5 MBSE and SysML in Product Development , 12.4 Implementation of Functional Descriptions Using MBSE -- 12.4.1 Role of Functions in the Context of MBSE -- 12.4.2 Description of the Context -- 12.4.3 Description of the System -- 12.4.4 Temporal and Logical Dependence of Functions -- 12.4.5 Use of the System Model for Impact Analyses -- 12.5 Examples -- 12.6 Summary and Conclusions for Further Research -- References -- Chapter 13: Function-Oriented Model-Based Product Development -- 13.1 Introduction -- 13.2 Basic Architecture for Model-Based Systems Development -- 13.2.1 Modelling of Requirements -- 13.2.2 Functional Architecture -- 13.2.3 Principle Solution Models -- 13.2.4 Solution Library -- 13.2.5 Initial Performance Testing of Principle Solutions -- 13.3 Virtual Testing of the Behavior of Evolving Solutions -- 13.3.1 Framework for Solution Libraries Based on Behavior Models -- 13.3.2 Evolving the Solution Using Physical Behavior Models -- 13.4 Model Frameworks and Ontologies for Efficient Model Re-Use -- 13.5 Summary and Conclusion -- References -- Chapter 14: Model-Based Systems Engineering: Discovering Potentials for Methodical Modular Product Development -- 14.1 Introduction -- 14.2 Integrated PKT Approach for the Development of Modular Product Families -- 14.2.1 Design for Variety and Life Phases Modularization -- 14.2.2 Interim Summary-Deficits of the Document-Based Approach -- 14.3 Potentials Through Model-Based Approaches -- 14.3.1 Ensuring Consistency Through the Development of Meta Models -- 14.3.2 Consistent Model-Based Implementation in SysML -- 14.4 Extension of the Model-Based Implementation on the Basis of Two Application Examples -- 14.4.1 Configuration Systems for Laser Processing Systems -- 14.4.2 Model-Based Representation of the Effects of Modular Product Families -- 14.4.3 Derivation of the Potentials of the Model-Based Approach Using the Application Examples , 14.5 Conclusion and Outlook

Weitere Ausg.: Erscheint auch als Druck-Ausgabe Krause, Dieter Design Methodology for Future Products Cham : Springer International Publishing AG,c2021 ISBN 9783030783679

Sprache: Englisch

URL: Volltext  (URL des Erstveröffentlichers)