［1］  赵连城,蔡伟,郑玉峰.合金的形状记忆效应与超弹性[M].北京:国防工业出版社,2002.
［2］  王心美,岳珠峰,王亚芳,等.NiTi合金的超弹性力学特性及其应用[M].北京:科学出版社,2009.
［3］  杨杰,吴月华.形状记忆合金及其应用[M].合肥：中国科学技术大学出版社，1993.
［4］  江树勇,郑玉峰,张艳秋.生物医用镍钛记忆合金管材塑性成形研究进展[J].锻压技术,2009,34(3):1-5.
［5］  张春才,苏佳灿.形状记忆材料[M].上海:第二军医大学出版社,2003.
［6］  Tanaka K. A thermomechanical sketch of shape memory effect：One-dimension tensile behavior[J].Res. Mechanica,1986(18):251-263.
［7］  Liang C，Rogers C A. One-dimension thermomechanical constitutive relation for shape memory alloy[J]. J. of Intell. Mater. Syst. and Struct.,1990,(1)：207-234.
［8］  Brinson L C, Lammering R. Finite-element analysis of the behavior of shape-memory alloys and their applications[J]. International Journal of Solids and Structures,1993,30(23):3261-3280.
［9］  Auricchio F,Taylor R L. Shape-memory alloys: modeling and numerical simulations of the finite-strain superelastic behavior[J].Computer Methods in Applied Mechanics and Engineering,1997,143:175-194.
［10］  Auricchio F,Taylor R L,Lubliner J. Shape-memory alloys: Macromodelling and numerical simulations of the superelastic behavior[J].Computer Methods in Applied Mechanics and Engineering,1997,146: 281-312.
［11］  Auricchio F. Shape-memory alloys:applications,micromechanics,macromodelling and numerical simulations[D].Berkley:University of California at Berkley,1995.
［12］  Lazghab T. Modeling of shape memory alloys with plasticity[D].Miami:Florida Intenational University,2001.
［13］  Yan W Y,Wang C H,Zhang X P,et al. Theoretical Modeling of the effect of plasticity on reverse transformation in superelastic shape memory alloys[J].Material Science Engineering A,2003,354:146-156.
［14］  Savi, M A,Paiva, A. Phenomenological modeling and numerical simulation of shape memory alloys: A thermo-plastic-phase transformation coupled model[J].Journal of Intelligent Material Systems and Structures,2002,13:261-273.
［15］  Patoor E,Eberhardt A,Berveiller M. Micromechanical modelling of superelasticity in shape memory alloys[J]. Journal De Physique IV,1996,6(1):277-292.
［16］  Peultier B,Ben Zineb T,Patoor E, Macroscopic constitutive law of shape memory alloy thermomechanical behaviour:Application to structure computation by FEM[J]. Mechanics of Materials,2006(38):510-524.
［17］  Peultier B, Ben Zineb T, Patoor E, Macroscopic constitutive law for SMA: Application to structure analysis by FEM[J]. Materials Science and Engineering A,2006,438-440:454-458.
［18］  刘晓鹏.NiTi形状记忆合金的超弹性及医学应用研究[D].大连：大连理工大学,2007.
［19］  梁栋科.血管内支架的加工及其力学性能的分析与评价[D].大连：大连理工大学,2005:92-116.
［20］  Perry M D,Chang R T. Finite element analysis of Ni-Ti alloy stent deployment[A]. The Second International Conference on Shape Memory and Superelastic Technology[C]. Asilomar,CA:SMST Publication,1997.
［21］  徐强，刘玉岚，王彪,等.形状记忆合金心血管支架自扩张过程的数值模拟与支架的“最优化网格”[J].生物医学工程学,2008,(5):1101-1106.
［22］  Conti M. Finite element analysis of self-expanding braided wirestent[D].Universita Degli Studi Di Pavia & Ghent University，2007:63-78.
［23］  吴卫.人体血管支架有限元分析与结构拓扑优化[D].大连：大连理工大学,2007.
［24］  Auricchio F,Conti M,Morganti S. Shape memory alloy: From constitutive modeling to finite element analysis of stent deployment[J]. Computer Modeling in Engineering and Science,2010,57(3):225-243.
［25］  Whitcher F D.Simulations of in vivo loading condtions of nitinol vascular stent structures[J].Computers and Structures,1997,64(5-6):1005-1011.
［26］  Stolpmann J,Brauer H,Stracke H J,et al.Prascticability and limitations of finite element simulation of the dilation behavior of coronary stents[J].Materialwissenschaft and Werkstofftechnik,2003,34(8):736-745.
［27］  Perry M,Oktay S,Muskivitch J C. Finite element analysis and fatigue of stents[J]. Minimally Invasive Therapy & Allied Technologies,2002,11(4):165-171.
［28］  Zhi Y H, Wang X M, Gao Z Z,et al. Mechanical property analysis of Nitinol defective stent under uniaxial loading/unloading[J]. Materialwissenschaft and Werkstofftechnik,2008,39(7):479-485.
［29］  王磊,闫德胜,姜志民,等.Ni-Ti-Nb宽滞后形状记忆合金管接头研究和进展[J].材料科学,2004,(7):60-63.
［30］  王健,沈亚鹏.基于Total-Lagrange法SMA管接头的有限元分析[J].机械强度,2000,22(4):275-278.
［31］  Manach P Y, Favier D, Rio G. Finite element simulations of internal stresses generated during the ferroelastic deformation of NiTi bodies[J]. Journal De Physique IV,1996,6(C1):235-244.
［32］  Helm D, Numerical simulation of martensitic phase transitions in shape memory alloys using an improved integration algorithm[J]. International Journal for Numerical Methods in Engineering,2007,69(10):1997-2035.
［33］  智友海，刘永寿，岳珠峰.不同载荷下形状记忆合金管接头性能的有限元分析[J].机械设计与制造,2009,(2):4-6.
［34］  Okita K,Okabe N,Satoh T,et al. Analysis model for shape memory effect in Ti-Ni system alloy of ring configuration[J]. International Journal of Modern Physics B,2006,20(25-27):3951-3956.