1. Chalmers, D. W., The Potential for the use of composite materials in marine structures. Marine Structures, 7(2-5), 1994; 441-456.
2. Alfers, J. B., & Bushby, A. C., Down to sea in plastics. Buships J 1952; 1:5-10.
3. Alfers, J.B., & Graner, W.R., Reinforced plastics a structural material for marine applications. Trans Soc Naval Arch Marine Eng 1954; 62:5-29.
4. Fried, N., & Graner, W.R., Durability of reinforced-plastics structural material in marine service. Marine Technology 1996; 3:321-7.
5. Spaulding, K.B., A history of the construction of fiberglass boats for the Navy. Bureau Ships J 1996; 15:2-11.
6. Use of fiber-reinforced plastics in the marine industry. Ship Structure Committee Report SSC-360. Springfield, VA: National Technical Information Service; 1990.
7. Cheetam, M.A., Naval application of reinforced plastics. Plastics Polym 1986; 36(121):15-20.
8. Lemiere, Y., The evolution of composite materials in submarine structures. In: Proceedings of the International Conference on Nautical Construction with Composite Materials, Paris, 1992 December 7-9. Paper 43.
9. Mouritz A. P., Gellert E., Burchill P., & Challis K., Review of advanced composite structures for naval ships and submarines. Compos Struct 2001; 53:21–41.
10. Dixon R.H., & Ramsey B.W., & Usher P.J., Design and build of the GRP hull of HMS Wilton. RINA Symposium on GRP Ship Construction, London; 1972. p. 1-32.
11. Schutz H., Aspects of material selection for MCMV hulls. In: Proceeding of the International Symposium on Mine Warfare Vessels and Systems, London, 1984 June 12-45. Paper 14.
12. Beale R.F., Selection of glass-reinforced plastics materials for large marine structures. British polym J 1971;3:1-8.
13. Mouritz A.P., Gellert, E., Burchill, P., & Challis K., Review of advanced composite structures for naval ships and submarines. Compos Struct 2001; 53:21–41.
14. Hashin, Z., & Rotem, A., A Fatigue Criterion for Fiber-Reinforced Materials, Journal of Composite Materials, Vol. 7, 1973; 448-464.
15. Hashin, Z., Failure Criteria for Unidirectional Fiber Composites, Journal of Applied Mechanics, Vol. 47, 1980; 329-334.
16. Sun, C.T., Quinn, B.J., & Oplinger, D.W., Comparative Evaluation of Failure Analysis Methods for Composite Laminates. DOT/FAA/AR-95/109, 1996.
17. Dávila C.G., & Camanho P.P., Failure Criteria for FRP Laminates in Plane Stress. NASA/TM-2003-212663. NASA Langley Research Center. Hampton, VA 23681, 2003.
18. Kim, K. S., Yoo, J. S., Yi, Y. M., & Kim, C. G., Failure mode and strength of uni-directional composite single lap bonded joints with different bonding methods. Compos. Struct., 2006, 72, 477–485.
19. Rispler, A.R., Steven, G.P., & Tong, L., Failure analysis of composite T Joints including inserts. J Reinf Plastic Compos 1997; 16:1642–58.
20. Kumari, S., & Sinha, P.K., Finite element analysis of composite wing T joints. J Reinf Plastic Compos 2002; 21:1561–85.
21. Shenoi, R.A., & Hawkins, G.L., Influence of material and geometry variations on the behaviour of bonded tee connections in FRP ships. Composites 1992; 23:335–45.
22. Zhou, D.W., Louca, L.A., & Saunders, M., Numerical simulation of sandwich T-joints under dynamic loading. Compos Part B: Eng 2008; 39:973–85.
23. Li, H.C.H., Dharmawan, F., Herszberg, I., & John, S., Fracture behaviour of composite maritime T-joints. Compos Struct 2006; 75:339–50.
24. 周晉緯,單搭接異質接合數值模擬與機械性質探討,國立高雄科技大學碩士論文,2018。25. 郭家閎,FRP接合設計與機械強度之探討,國立高雄海洋科技大學碩士論文,2016。26. 陳宏鐘,船舶結構學,國立高雄海洋科技大學上課講義。
27. 陳秋珺,FRP帽型樑搭接形式與力學特性之研究,國立高雄海洋科技大學碩士論文,2013。