دانلود کتاب Design Methodology for Future Products: Data Driven, Agile and Flexible

فهرست مطالب :

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 References Chapter 15: Methodical Approaches for Engineering Complex Systems 15.1 Introduction 15.2 Development of Complex Systems for Supporting the Concept of the Circular Economy 15.3 Methodical Approaches for Developing Complex Systems 15.3.1 Planning of Product Upgrading and Evolution by Release Planning 15.3.2 An Approach for Modelling Requirements and Systems at Different Hierarchical Levels 15.3.3 Hybrid Concepts for Project Management in Product Design Processes 15.3.4 Potentials and Implications of I4.0 for Product Development 15.4 Conclusion and Future Work References