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Biomechanics : optimization, uncertainties and reliability /

In this book, the authors present in detail several recent methodologies and algorithms that they developed during the last fifteen years. The deterministic methods account for uncertainties through empirical safety factors, which implies that the actual uncertainties in materials, geometry and load...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autores principales: Kharmanda, Ghias (Autor), El Hami, Abdelkhalak (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: London ; Hoboken, NJ : ISTE LTD : John Wiley, 2017.
Colección:Reliability of multiphysical systems set ; volume 5.
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Table of Contents; Title; Copyright; Preface; Introduction; List of Abbreviations; 1 Introduction to Structural Optimization; 1.1. Introduction; 1.2. History of structural optimization; 1.3. Sizing optimization; 1.4. Shape optimization; 1.5. Topology optimization; 1.6. Conclusion; 2 Integration of Structural Optimization into Biomechanics; 2.1. Introduction; 2.2. Integration of structural optimization into orthopedic prosthesis design; 2.3. Integration of structural optimization into orthodontic prosthesis design; 2.4. Advanced integration of structural optimization into drilling surgery.
  • 2.5. Conclusion3 Integration of Reliability into Structural Optimization; 3.1. Introduction; 3.2. Literature review of reliability-based optimization; 3.3. Comparison between deterministic and reliability-based optimization; 3.4. Numerical application; 3.5. Approaches and strategies for reliability-based optimization; 3.6. Two points of view for developments of reliability-based optimization; 3.7. Philosophy of integration of the concept of reliability into structural optimization groups; 3.8. Conclusion; 4 Reliability-based Design Optimization Model; 4.1. Introduction; 4.2. Classic method.
  • 4.3. Hybrid method4.4. Improved hybrid method; 4.5. Optimum safety factor method; 4.6. Safest point method; 4.7. Numerical applications; 4.8. Classification of the methods developed; 4.9. Conclusion; 5 Reliability-based Topology Optimization Model; 5.1. Introduction; 5.2. Formulation and algorithm for the RBTO model; 5.3. Validation of the RBTO model; 5.4. Variability of the reliability index; 5.5. Numerical applications for the RBTO model; 5.6. Two points of view for integration of reliability into topology optimization; 5.7. Conclusion.
  • 6 Integration of Reliability and Structural Optimization into Prosthesis Design6.1. Introduction; 6.2. Prosthesis design; 6.3. Integration of topology optimization into prosthesis design; 6.4. Integration of reliability and structural optimization into hip prosthesis design; 6.5. Integration of reliability and structural optimization into the design of mini-plate systems used to treat fractured mandibles; 6.6. Integration of reliability and structural optimization into dental implant design; 6.7. Conclusion; Appendices; Appendix 1: ANSYS Code for Stem Geometry.
  • Appendix 2: ANSYS Code for Mini-Plate GeometryAppendix 3: ANSYS Code for Dental Implant Geometry; Appendix 4: ANSYS Code for Geometry of Dental Implant with Bone; Bibliography; Index; End User License Agreement.