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Ships and Offshore Structures Volume 12, 2017 - Issue 2
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Original Articles

Prediction of offshore structural response extreme values by three different approaches of efficient time simulation technique

M.K. Abu HusainDepartment of Engineering, UTM Razak School of Engineering and Advanced Technology, Universiti Teknologi Malaysia, Kuala Lumpur, MalaysiaCorrespondence[email protected]
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,
N.I. Mohd ZakiDepartment of Engineering, UTM Razak School of Engineering and Advanced Technology, Universiti Teknologi Malaysia, Kuala Lumpur, MalaysiaView further author information
&
G. NajafianSchool of Engineering, University of Liverpool, Liverpool, United KingdomView further author information
Pages 290-301 | Received 12 May 2015, Accepted 20 Nov 2015, Published online: 11 Mar 2016

References

  • Abu Husain MK, Mohd Zaki NI, Mallahzadeh H, Najafian G. 2014. Short-term probability distribution of the extreme values of offshore structural response by an efficient time simulation technique, Ships Offshore Struct. doi:10.1080/17445302.2014.986877
  • Abu Husain MK, Mohd Zaki NI, Najafian G. 2013. Derivation of the probability of extreme values of offshore structural response by efficient time simulation method. Open Civ Eng J. 7:261–272.
  • Abu Husain MK, Najafian G. 2010. An efficient Monte Carlo simulation technique for derivation of the probability distribution of the extreme values of offshore structural response. Proceedings of the 29th International Conference on Offshore Mechanics and Arctic Engineering; 2010 June 6–11; Shanghai, China; Shanghai: ASME. p. 369–375.
  • Alfred Mohammed E, Chan HS, Hirdaris SE. 2012. Global wave load combinations by cross-spectral methods. Mar Struct. 29(1):131–151.
  • Bitner-Gregersen ME, Bhattacharya SB, Chatjigeorgiou IK, Eames I, Ellermann K, Ewans K, Hermanski G, Johnson MC, Ma N, Maisondieu C, et al. 2014a. Recent developments on uncertainties of environmental description. Ocean Eng. 86C:26–46.
  • Bitner-Gregersen ME, Ewans K, Johnson MC. 2014b. Some uncertainties associated with wind and wave description and their importance for engineering applications. Ocean Eng. 86C:11–25.
  • Borgman LE. 1967. Random hydrodynamic forces on objects. Ann Math Stat. 38:37–51.
  • Borgman LE. 1969. Ocean wave simulation for engineering design. ASCE J Waterways Harbours Div. 95(WW4):557–583.
  • Burrows R. 1979. Probabilistic description of the response of offshore structures to random wave loading. In: Mechanics of wave induced forces on cylinders. London: Pitman Advanced Publishing Program. p. 731–747.
  • Clough RW, Penzien J. 1993. Dynamics of structures. 2nd ed. New York (NY): McGraw-Hill Inc.
  • Corak M, Parunov J, Guedes Soares C. 2015. Long-term prediction of combined wave and whipping bending moments of containership. Ships Offshore Struct. 10(1):4–19.
  • Eatock T, Rajagopalan A. 1981. Super harmonic resonance effects in drag dominated structures. In: D Faulkner; MJ Cowling; PA Frieze, editors. Proceedings of the 2nd International Symposium on Integrity of Offshore Structures; 1981 July 1–3; Glasgow, Scotland; Glasgow: Applied Science Publishers. p. 85–104.
  • Grigoriu M. 1993. On the spectral representation method in simulation. Probabilistic Eng Mech. 8(2):75–90.
  • Hirdaris SE. 2014. Special issue on uncertainty modelling for ships and offshore structures. Ocean Eng. 86:1–2.
  • Hirdaris SE, Bai W, Dessi D, Ergin A, Gu X, Hermundstad OA, Huijsmans R, Iijima K, Nielsen UD, Parunov J, et al. 2014. Loads for use in design of ships and offshore structures. Ocean Eng. 78:131–174.
  • Jensen JJ. 2008. Extreme value predictions and critical wave episodes for marine structures by FORM. Ships Offshore Struct. 3(4):325–333.
  • Liaw CY, Zheng XY. 2003. Polynomial approximations of wave loading and super harmonic responses of fixed structures. J Offshore Mech Arctic Eng ASME. 25(3):161–167.
  • Marooka CK, Yokoo IH. (1997). Numerical simulation and spectral analysis of irregular sea waves. J Offshore Polar Eng. 189–196.
  • Mohd Zaki NI, Abu Husain MK, Najafian G. 2014. Extreme structural response values from various methods of simulating wave kinematics. Ships Offshore Struct. doi:10.1080/17445302.2014.987947
  • Naess A, Gaidai O, Haver S. 2007. Efficient estimation of extreme response of drag-dominated offshore structures by Monte Carlo simulation. Appl Ocean Res. 34(16):2188–2219.
  • Najafian G. 2007a. Probability models for offshore structural response due to Morison wave loading. part I: drag-only response. Ocean Eng. 34(17–18):2277–2288.
  • Najafian G. 2007b. Application of system identification techniques in efficient modelling of offshore structures part I: model development. Appl Ocean Res. 29(1–2):1–16.
  • Najafian G. 2007c. Application of system identification techniques in efficient modelling of offshore structures part II: model validation. Appl Ocean Res. 29(1–12):17–36.
  • Pierson WJ, Moskowitz L. 1964. A proposed spectral form for fully developed wind seas based on the similarity theory of S.A. Kitaigorodskii. J Geophys Res. 69:5181–5190.
  • Qiu W, Sena Sales JJ, Lee DY, Lie H, Magarovskii V, Mikami T, Rousset JM, Sphaier S, Tao L, Wang X. 2014. Uncertainties related to predictions of loads and responses for ocean and offshore structures. Ocean Eng. 86C:58–67.
  • Rice SO. 1944. Mathematical analysis of random noise. Bell Syst Tech J. 23:282–332.
  • Rice SO. 1945. Mathematical analysis of random noise. Bell Syst Tech J. 24:46–156.
  • Tickell RG. 1977. Continuous random wave loading on structural members. Struct Eng. 55(5):209–222.
  • Torhaug R, Winterstein SR, Braathen A. 1998. Nonlinear ship loads: stochastic models for extreme response. J Ship Res. 42(1):46–55.
  • Tucker MJ, Carter DJT, Challenor PG. 1984. Numerical simulation of random sea: a common error and its effect upon wave group statistics. Appl Ocean Res. 29(6):118–122.
  • Tung CC. 1995. Effect of free surface fluctuation on total wave force on cylinder. J Eng Mech ASCE. 121(2):274–280.

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