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Transdisciplinary Engineering Design Process [Kõva köide]

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  • Formaat: Hardback, 832 pages, kõrgus x laius x paksus: 241x196x33 mm, kaal: 1452 g
  • Ilmumisaeg: 19-Oct-2018
  • Kirjastus: John Wiley & Sons Inc
  • ISBN-10: 1119474752
  • ISBN-13: 9781119474753
Teised raamatud teemal:
Transdisciplinary Engineering Design ProcessSuurem pilt
  • Formaat: Hardback, 832 pages, kõrgus x laius x paksus: 241x196x33 mm, kaal: 1452 g
  • Ilmumisaeg: 19-Oct-2018
  • Kirjastus: John Wiley & Sons Inc
  • ISBN-10: 1119474752
  • ISBN-13: 9781119474753
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9781119474753.html
Märksõnad:

A groundbreaking text book that presents a collaborative approach to design methods that tap into a range of disciplines 

In recent years, the number of complex problems to be solved by engineers has multiplied exponentially. Transdisciplinary Engineering Design Process outlines a collaborative approach to the engineering design process that includes input from planners, economists, politicians, physicists, biologists, domain experts, and others that represent a wide variety of disciplines. As the author explains, by including other disciplines to have a voice, the process goes beyond traditional interdisciplinary design to a more productive and creative transdisciplinary process.

The transdisciplinary approach to engineering outlined leads to greater innovation through a collaboration of transdis­ciplinary knowledge, reaching beyond the borders of their own subject area to conduct “useful” research that benefits society. The author—a noted expert in the field—argues that by adopting transdisciplinary research to solving complex, large-scale engineering problems it produces more innovative and improved results. This important guide:

  • Takes a holistic approach to solving complex engineering design challenges
  • Includes a wealth of topics such as modeling and simulation, optimization, reliability, statistical decisions, ethics and project management
  • Contains a description of a complex transdisciplinary design process that is clear and logical
  • Offers an overview of the key trends in modern design engineering
  • Integrates transdisciplinary knowledge and tools to prepare students for the future of jobs

Written for members of the academy as well as industry leaders,Transdisciplinary Engineering Design Process is an essential resource that offers a new perspective on the design process that invites in a wide variety of collaborative partners. 

About the Author xi
Preface xiii
1 Systemic Thinking and Complex Problem Solving
1(76)
1.1 Introduction
1(1)
1.2 What Is Complexity?
1(6)
1.3 Source of Complexity
7(1)
1.4 Two Aspects of Complexity
8(1)
1.5 Complexity and Societal Problems
9(4)
1.6 Understanding and Managing Complexity
13(5)
1.7 Managing Complexity
18(8)
1.8 Complex Systems, Hierarchies, and Graphical Representations
26(4)
1.9 Axiomatic Design
30(6)
1.10 Collective Intelligence Management
36(13)
1.11 Design Structure Matrix
49(13)
1.12 Metrics of Complexity
62(15)
Bibliography
71(6)
2 Transdisciplinary Design Process
77(68)
2.1 Introduction
77(1)
2.2 Design
78(3)
2.3 Design Process Models
81(3)
2.4 Typical Steps in Engineering Design Process
84(18)
2.5 Design Review
102(1)
2.6 Redesign
102(3)
2.7 Other Important Design Considerations
105(9)
2.8 Transdiscipline
114(6)
2.9 Transdisciplinary Domain
120(2)
2.10 Transdisciplinary Design Process: Social Innovation through TD Collective Impact
122(6)
2.11 Generic TD Hybrid Design Process
128(1)
2.12 Transdisciplinary Research Process
129(16)
Bibliography
140(5)
3 Project Management and Product Development
145(76)
3.1 Introduction
145(1)
3.2 Project Management
145(18)
3.3 Technical Management
163(6)
3.4 Clarifying the Project Goals and Objectives
169(4)
3.5 Decision-Making
173(7)
3.6 Process of Defining Customer Needs
180(9)
3.7 Techniques and Methods for Product Development and Management
189(16)
3.8 Cascade to Production
205(1)
3.9 Production Process Planning and Tooling Design
206(15)
Bibliography
214(7)
4 Transdlsciplinary Sustainable Development
221(68)
4.1 Introduction
221(1)
4.2 Transdisciplinary Sustainable Development
222(5)
4.3 Contaminated Environment
227(1)
4.4 Groundwater Sustainability
228(3)
4.5 Soil and Groundwater Restoration
231(27)
4.6 Occupational Safety and Health
258(5)
4.7 Prevention through Design: Transdisciplinary Design Process
263(4)
4.8 Environmental Degradation, Sustainable Development, and Human Well-Being
267(4)
4.9 Ecosystems
271(8)
4.10 Conclusion
279(10)
Bibliography
279(10)
5 Design for Manufacture
289(52)
5.1 Introduction
289(1)
5.2 Why Design for Manufacture?
289(1)
5.3 The Six Steps in Motorola's DFM Method
290(1)
5.4 Lean and Agile Manufacturing
290(2)
5.5 Design for Manufacture and Assembly Guidelines
292(2)
5.6 Six Sigma
294(26)
5.7 Tolerancing in Design
320(1)
5.8 Geometric Dimensioning and Tolerancing
321(8)
5.9 Future of Manufacturing: Additive Manufacturing
329(12)
Bibliography
336(5)
6 Design Analyses for Material Selection
341(100)
6.1 Introduction
341(1)
6.2 General Steps in Materials Selection
342(12)
6.3 Classification of Materials
354(3)
6.4 Material Properties
357(4)
6.5 Analysis of Material Requirements
361(14)
6.6 Design Analysis for Fatigue Resistance
375(8)
6.7 Miner's Rule: Cumulative Fatigue Damage
383(7)
6.8 Fracture Mechanics Based Fatigue Analysis
390(21)
6.9 Design Analysis for Composite Materials
411(11)
6.10 Residual (Internal) Stress Considerations
422(4)
6.11 Material Standards and Specifications
426(4)
6.12 Corrosion Considerations
430(11)
Bibliography
432(9)
7 Statistical Decisions
441(78)
7.1 Random Variables
441(4)
7.2 Measures of Central Tendency
445(1)
7.3 Measures of Variability
446(4)
7.4 Probability Distributions
450(6)
7.5 Sampling Distributions
456(3)
7.6 Statistical Inference
459(12)
7.7 Design of Experiments
471(9)
7.8 Taguchi Methods
480(39)
Bibliography
509(10)
8 Risk, Reliability, and Safety
519(76)
8.1 Introduction
519(1)
8.2 What Is Risk?
519(12)
8.3 Basic Mathematical Concepts in Reliability Engineering
531(2)
8.4 Probability Distribution Functions Used in Reliability Analysis
533(7)
8.5 Failure Modeling
540(2)
8.6 Probability Plotting
542(2)
8.7 Basic System Reliability
544(23)
8.8 Failure Mode and Defects Analysis
567(7)
8.9 Fault-Tree Analysis
574(8)
8.10 Probabilistic Design
582(6)
8.11 Worst-Case Design
588(7)
Bibliography
590(5)
9 Optimization in Design
595(42)
9.1 Introduction
595(2)
9.2 Mathematical Models and Optimization Methods
597(23)
9.3 Optimization of System Reliability
620(17)
Bibliography
630(7)
10 Modeling and Simulation
637(34)
10.1 Modeling in Engineering
637(1)
10.2 Heuristic Modeling
638(2)
10.3 Mathematical Modeling
640(4)
10.4 Dimensional Analysis
644(3)
10.5 Similarity Laws in Model Testing
647(2)
10.6 Wind and Water Tunnels
649(1)
10.7 Numerical Modeling
649(9)
10.8 Discrete Event Simulation
658(2)
10.9 Knowledge-Based Systems in the Design Process
660(11)
Bibliography
667(4)
11 Engineering Economics
671(44)
11.1 Project/Product Cost and the Engineer
671(4)
11.2 Cost Analysis and Control
675(7)
11.3 Important Economic Concepts
682(8)
11.4 Selecting an Appropriate Rate of Return
690(2)
11.5 Evaluation of Economic Alternatives
692(23)
Bibliography
708(7)
12 Engineering Ethics
715(20)
12.1 Ethics in Industry
715(1)
12.2 Ethics and the University
716(1)
12.3 Ethics in Engineering
717(3)
12.4 Legal Responsibilities of Engineers
720(2)
12.5 Codes of Ethics
722(4)
12.6 Ethical Dilemmas
726(3)
12.7 The NSPE Code of Ethics for Engineers
729(6)
Bibliography
734(1)
13 Communications in Engineering
735(24)
13.1 Introduction
735(1)
13.2 The Formal Engineering Report
736(12)
13.3 Proposal Preparation
748(4)
13.4 Oral Communications
752(2)
13.5 Oral Presentations
754(2)
13.6 A Final Word on Communications
756(3)
Appendix A 759(22)
Appendix B 781(4)
Appendix C 785(22)
Appendix D 807(4)
Index 811
ATILA ERTAS is Professor of Mechanical Engineering and Director of the Academy of Transdisciplinary Studies, Texas Tech University, USA. Dr. Ertas has been the driving force behind the conception and development of the transdisciplinary model for education and research, and had 12 years of industrial experience prior to pursuing graduate studies.