Teaching Staff
Dr. Winyu Rattanapitikon
Date Posted : 2022-01-05
Faculty
:
School of Civil Engineering and Technology (CET)
Name
:
Dr. Winyu Rattanapitikon
Position
:
ASSOCIATE PROFESSOR
Phone Rangsit
:
+66-2-986-9009, +66-2-986-9101, +66-2-564-3226
Phone Bangkadi
:
Phone Extension
:
1904
Education


Academic Awards


Research Areas

Mathematical modeling, Sediment Transport, and Beach Deformation
Research Interests

Mathematical Modeling for Cross Shore Sediment Transport and Beach Deformation under Regular and Irregular Waves

Many numerical models had been developed to compute sediment transport rate. However, most of the models were developed under limited experimental conditions. Therefore their validity is limited according to the range of experimental conditions which were employed in the calibration. The evidence is that many models exist. The main objective of this research is to develop a reliable sediment transport model based on a wide range of experimental conditions.

Work Experiences


Theses Supervised

Master Theses Supervised
1999  : Piyamarn Leangruxa. Wave Height Transformation Across Shore.
2001  : Romanee Karunchintadit. Irregular Wave Models.
2002  : Thirapat Vivattanasirisak. Breaker Height Formulas.
2006  : Sangapol Sawanggun. Transformation of Representative Wave Heights.

Professional Activities

Expert Review Committee for EIA, the National Environmental Board, Thailand.
List of Publications

  1. Sanyawit Siriluk; Qudeer Hussin; Winyu Rattanapitikorn; Amorn Pimanmas (2018). Behaviours of RC deep beams strengthened in shear using hemp fiber reinforced polymer composites, International Journal of GEOMATE, Vol.15, No. 47, July 2018, pp. 89-94.
  2. Winyu Rattanapitikon and Suwimol Kanokrattananukul (2018). Verification and modification of empirical formulas for computing wave shoaling, Ocean Engineering, Vol. 152, 15 March 2018,  pp. 145-153.
  3. Saleem, Shahzad; Amorn Pimanmas; Winyu Rattanapitikon (2018). Lateral response of PET FRP-confined concrete, Construction and Building Materials, Vol. 159, 20 January 2018, pp. 390–407.
  4. Chatchawin Srisuwana; Payom Rattanamaneea; and Winyu Rattanapitikon (2017). Analytical formulas for estimation of phase-averaged parameters of random waves, Ocean Engineering, Vol. 133, 15 March 2017, pp. 23-35.
  5. Winyu Rattanapitikon; and Suwimol Kanokrattananukul (2017). Examination and recalibration of empirical formulas for computing shoaling wave heights. In Proceedings of the 37th IAHR World Congress (IAHR 2017), 13-18 August 2017, Kuala Lumpur, Malaysia, pp. 3481-3487.
  6. Hussain, Qudeer; Winyu Rattanapitikon; and Amorn Pimanmas (2016). Axial load behavior of circular and square concrete columns confined with sprayed fiber-reinforced polymer composites, Polymer Composites, Vol. 37, No. 8, August 2016, pp. 2557-2567.
  7. Atipphat Suwattanakorn; Qudeer Hussain; Winyu Rattanapitikon; and Amorn Pimanmas (2016). Behavior of rectangular concrete column confined with sisal fiber reinforced polymers (Sisal FRP). In Proceedings of the 2016 International Conference on Composite Materials and Material Engineering (ICCMME2016), 9-11 March 2016, Bangkok, Thailand, Paper No. 33-ICCMME2016-346E, 4 p.
  8. Yinh, Seyha; Qudeer Hussain; Winyu Rattanapitikon; and Amorn Pimanmas (2016). Flexural behavior of reinforced-concrete (RC) beams strengthened with hemp fiber-reinforced polymer (FRP) composites. In Proceedings of the 2016 International Conference on Composite Materials and Material Engineering (ICCMME2016), 9-11 March 2016, Bangkok, Thailand, Paper No. 36-ICCMME2016-348E, 4 p.
  9. Khan, Arslan Qayyum; Qudeer Hussain; Winyu Rattanapitikon; and Amorn Pimanmas (2016). Flexural strengthening of RC beams with sisal fiber composites and sisal fiber rods. In Proceedings of the 2016 International Conference on Composite Materials and Material Engineering (ICCMME2016), 9-11 March 2016, Bangkok, Thailand, Paper No. 36-ICCMME2016-348E, 4 p.
  10. Sanyawit Siriluk; Qudeer Hussin; Winyu Rattanapitikorn; and Amorn Pimanmas (2016). Shear strengthening of reinforced concrete beams with HFRP composite. In Proceedings of the 2016 International Conference on Composite Materials and Material Engineering (ICCMME2016), 9-11 March 2016, Bangkok, Thailand, Paper No. 37-ICCMME2016-349E, 4 p.
  11. Duong, Nga Thanh; Winyu Rattanapitikon; and Tawatchai Tingsanchali (2015). Energy dissipation models for computing statistical-based and spectral-based root-mean-square wave heights. In Proceedings of the 10th Internatonal Symposium in Science and Technology 2015, 31 August - 2 September 2015, Bangkok and Pathumthani, Thailand, pp.223-229.
  12. Atipphat Panyasirikhunawut; Qudeer Hussain; Winyu Rattanapitikon; and Amorn Pimanmas (2015). Axial behavior of concrete externally confined with sisal FRP. In Proceedings of the 9th Asia Pacific Structural Engineering and Construction Conference (APSEC 2015) and 8th Asean Civil Engineering Conference (ACEC 2015) [CD-ROM], 3-5 November 2015, Kuala Lumpur, Malaysia, 6 p.
  13. Yinh, Seyha; Qudeer Hussain; Winyu Rattanapitikon; and Amorn Pimanmas (2015). Strengthening of concrete beams using sisal FRP. In Proceedings of the 9th Asia Pacific Structural Engineering and Construction Conference (APSEC 2015) and 8th Asean Civil Engineering Conference (ACEC 2015) [CD-ROM], 3-5 November 2015, Kuala Lumpur, Malaysia, 6 p.
  14. Winyu Rattanapitikon; Khiem Quang Tran; and Tomoya Shibayama (2015). Estimation of maximum possible wave heights in surf zone, Coastal Engineering Journal, Vol. 57, No. 2, June 2015, Article No. 1550001, 19 p.
  15. Winyu Rattanapitikon and Nga Thanh Duong (2014). Transformation of representative wave heights using parametric wave approach. In Proceedings of the 11th International Conference on Hydrodynamics (ICHD 2014) [CD-ROM], 19-24 October 2014, Singapore, 7 p.
  16. Thamnoon Rasmeemasmuang; Wanich Chuenjai; and Winyu Rattanapitikon (2014). Wave run-up on sandbag slopes,Maejo International Journal of Science and Technology, Vol. 8, No. 1 (January-April 2014), pp. 48-57.
  17. Winyu Rattanapitikon and Tomoya Shibayama (2013). Verification and extension of Goda formulas for computing representative wave heights transformation, Coastal Engineering Journal, Vol. 55, No. 3, 1350009 (23 p.).
  18. Poonchai Nuntakomol and Winyu Rattanapitikon (2013). Empirical formula for computing representative wave heights from zeroth moment of wave spectrum. In Proceedings of the 7th International Conference on Asian and Pacific Coasts (APAC 2013), 24-26 September 2013, Bali, Indonesia, pp. 722-729.
  19. Winyu Rattanapitikon (2013). Verification and modification of conversion formulas for estimating statistical-based representative wave heights from zeroth moment of wave spectrum based on field data, Kasetsart Journal – Natural Science, Vol. 47, No. 1, 2013, pp. 143-154.
  20. Winyu Rattanapitikon (2010). Verification of conversion formulas for computing representative wave heights, Ocean Engineering, Vol. 37, Nos. 17-18, December 2010, pp. 1554-1563.
  21. Winyu Rattanapitikon and Tomoya Shibayama (2010). Energy dissipation model for computing transformation of spectral significant wave height, Coastal Engineering Journal, Vol. 52, No. 4, December 2010, pp. 305-330.
  22. Winyu Rattanapitikon (2008). Verification of significant wave representation method, Ocean Engineering, Vol. 35, Nos. 11-12, August 2008, pp. 1259-1270.
  23. Winyu Rattanapitikon and Sangapol Sawanggun (2008). Energy dissipation model for a parametric wave approach based on laboratory and field experiments, Songklanakarin Journal of Science and Technology, Vol. 30, No. 3, May-June 2008, pp. 333-341.
  24. Winyu Rattanapitikon (2007). Calibration and modification of energy dissipation models for irregular wave breaking,Ocean Engineering, Vol. 34, Nos. 11-12, August 2007, pp. 1592-1601.
  25. Winyu Rattanapitikon and Tomoya Shibayama (2007). Estimation of shallow water representative wave heights,Coastal Engineering Journal, Vol. 49, No. 3, September 2007, pp. 291-310.
  26. Winyu Rattanapitikon and Sangapol Sawanggun (2007). Modification of a parametric wave model. In Proceedings of the Fourth International Conference on Asia and Pacific Coasts (APAC 2007) [CD-ROM], 21-24 September 2007, Nanjing, China. pp. 346-357.
  27. Pannathat Rojanamon; Taweep Chaisomphob; and Winyu Rattanapitikon (2007). Regional flow duration model for the Salawin river basin of Thailand, ScienceAsia: Journal of the Science Society of Thailand, Vol. 33, No. 4, December 2007, pp. 411-419.
  28. Pannathat Rojanamon; Taweep Chaisomphob; and Winyu Rattanapitikorn (2007). Monthly flow duration model for small hydropower project development in the upper ping river basin. In Proceedings of the 12th National Convention on Civil Engineering (NCCE12) [CD-ROM], 2-4 May 2007, Pisanulok, Thailand. Vol. 9 (WRE), pp. 383-388.
  29. Pannathat Rojanamon; Taweep Chaisomphob; and Winyu Rattanapitikon (2006). Monthly flow duration for the Salawin river basin, Thailand. In Proceedings of the International Symposium on Water Resources and Renewable Energy Development in Asia [CD-ROM], 30 November - 1 December 2006, Bangkok, Thailand. 8 p.
  30. Winyu Rattanapitikon and Tomoya Shibayama (2006). Breaking wave formulas for breaking depth and orbital to phase velocity ratio, Coastal Engineering Journal, Vol. 48, No. 4, December 2006, pp. 395-416.
  31. Winyu Rattanapitikon, Romanee Karunchintadit, and Tomoya Shibayama (2003). Irregular wave height transformation using representative wave, Coastal Engineering Journal, Vol. 45, No. 3, pp. 489-510.
  32. Winyu Rattanapitikon, Thirapat Vivattanasirisak, and Tomoya Shibayama (2003). A proposal of new breaker height formula, Coastal Engineering Journal, Vol. 45, No. 1, pp. 29-48.
  33. Winyu Rattanapitikon and Romanee Karunchintadit (2002). Comparison of dissipation models for irregular breaking waves, Songklanakarin journal of science and technology, Vol. 24, No. 1, p. 139-148.
  34. Winyu Rattanapitikon and Romanee Karunchintadit (2002). Representative wave height transformation, In Proceedings of the Fifth International Conference on Hydrodynamics, 31 October - 2 November 2002, Tainan, Taiwan, p. 359-364.
  35. Winyu Rattanapitikon and Thirapat Vivattanasirisak (2002). Comparison of breaker height formulas using large-scale wave tanks, Songklanakarin journal of science and technology, Vol. 24, No. 4, pp. 663-674.
  36. Winyu Rattanapitikon and Piyamarn Leangruxa (2001). Comparison of dissipation models for regular breaking waves,Songklanakarin journal of science and technology, Vol. 23, No. 1, pp. 63-72.
  37. Winyu Rattanapitikon (2001). Undertow velocity induced by irregular waves, Research and development journal of the Engineering Institute of Thailand, Vol. 12, No. 2, pp. 26-35.
  38. Winyu Rattanapitikon and Thirapat Vivattanasirisak (2000). Examination of breaker height formulas, In Proceedings of the 12th Congress of the Asia Pacific Division of the International Association for Hydraulic Research, 13-16 November 2000, Bangkok, Thailand, v. 3, pp. 425-434.
  39. Winyu Rattanapitikon; Piyamarn Leangruxa and Tomoya Shibayama (2000). Energy dissipation formulas for regular breaking waves, In Proceedings of the 4th International Conference on Hydrodynamics, 7-9 September 2000, Yokohama, Japan, pp. 545-550.
  40. Winyu Rattanapitikon and Tomoya Shibayama (2000). Verification and modification of breaker height formulas,Coastal Engineering Journal, Vol. 42, No. 4, pp. 389-406.
  41. Winyu Rattanapitikon and Tomoya Shibayama (2000). Simple model for undertow profile, Coastal Engineering Journal, Vol. 42, No. 1, pp. 1-30.
  42. Piyamarn Leangruxa; Winyu Rattanapitikon and Tomoya Shibayama (1999). Comparison of energy dissipation models for regular breaking waves, In Proceedings of Civil and Environmental Engineering Conference, New Frontiers and Challenges, 1999, AIT, Thailand, pp. 21-28.
  43. Winyu Rattanapitikon and Tomoya Shibayama (1999). Regular wave height transformation, Thammasat international journal of science and technology, November 1999, v. 4, no. 3, pp. 38-47.
  44. Winyu Rattanapitikon, Tomoya Shibayama (1999). Irregular wave deformation, Research and development journal of The Engineering Institute of Thailand, Vol. 10, No. 1, pp. 32-41.
  45. Winyu Rattanapitikon and Tomoya Shibayama (1999). Energy dissipation model for irregular breaking waves, InProceedings of the 5th National Convention on Civil Engineering, Thailand, Volume 2, 24 - 26 March 1999, p. WRE-148- 153.
  46. Piyamarn Leangruxa and Winyu Rattanapitikon (1999). Comparison of energy dissipation models for regular breaking waves, In Proceedings of the 5th National Convention on Civil Engineering, Thailand, Vol. 2, 24-26 March 1999, p. WRE- 48 to WRE-54.
  47. Winyu Rattanapitikon and Tomoya Shibayama (1998). Energy dissipation model for regular and irregular breaking waves, Coastal Engineering Journal, Vol. 40, No. 4, p. 327-346.
  48. Winyu Rattanapitikon and Tomoya Shibayama (1998). Energy dissipation model for irregular breaking waves, Coastal Engineering Journal, p. 112-125. (Also in Proceedings of the 26th Coastal Engineering Conference, ASCE, 1998, Copenhagon, Denmark, paper no. 8, p. 16-17.)
  49. Tawatchai Tingsanchali and Winyu Rattanapitikon (1999). 2-D modelling of dambreak wave propagation on initially dry bed, Thammasat International Journal of Science and Technology, November 1999, Vol. 4, No. 3, pp. 28-37.

Sirindhorn International Institute of Technology,
Thammasat University - Rangsit Campus
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