Marine Structural Design

<p>Part I: Structural Design Principles<br>1. Introduction<br>2. Wave loads for ship design and classification<br>3. Loads and dynamic response for offshore structures<br>4. Scantling of ship's hulls by rules<br>5. Ship hull scantling by analysis <br>6. Offshore structural analysis<br>7. Limit-state design of offshore structures</p> <p>Part II: Ultimate Strength<br>8. Buckling/collapse of columns and beam-columns<br>9. Buckling and local buckling of tubular members<br>10. Ultimate strength of plates and stiffened plates<br>11. Ultimate strength of cylindrical shells<br>12. A theory of nonlinear finite element analysis<br>13. Collapse analysis of ship hulls<br>14. Offshore structures under impact loads<br>15. Offshore structures under earthquake loads</p> <p>Part III: Fatigue and Fracture<br>16. Mechanism of fatigue and fracture<br>17. Fatigue capacity<br>18. Fatigue loading and stresses<br>19. Simplified fatigue assessment<br>20. Spectral fatigue analysis and design<br>21. Application of fracture mechanics<br>22. Material selections and damage to tolerance criteria</p> <p>Part IV: Structural Reliability<br>23. Basics of structural reliability <br>24. Random variables and uncertainty analysis<br>25. Reliability of ship structures<br>26. Reliability-based design and code calibration<br>27. Fatigue reliability<br>28. Probability and risk based inspection planning</p> <p>Part V: Risk Assessment<br>29. Risk assessment methodology<br>30. Risk assessment applied to offshore structures<br>31. Formal safety assessment applied to the shipping industry<br>32. Economic risk assessment for field development<br>33. Human reliability assessment<br>34. Risk centered maintenance</p>