[1] Xiong Youlun, Yin Zhouping. Digital manufacturing and digital equipment: the evelopment direction of the manufacturing technology and equipment in the 21th Century[J]. Digital Manufacture Science, 2003, 1(1-4): 1-13.

[2] Department of Engineering and Material Science, National Natural Science Foundation Committee. Development Strategy Report of Mechanical Engineering 2011-2020[M]. Beijing: Science Press, 2010. 16-20.

[3] Zhang Yongzhong, Shi Likai, Zhang Pingzhi, et al.. The newest advance in laser rapid forming of metallic powders[J]. Rare Metal Materials and Engineering, 2000, 29(6): 361-365.

[4] Huang Shuhuai, Xiao Yuejia. The prospect of rapid prototyping technology[J]. China Mechanical Engineering, 2000, 11(1-2): 195-200.

[5] K Sanjay. Selective laser sintering: aqualitative and objective approach[J]. JOM, 2003, 55(10): 43-47.

[6] Yan Yongnian, Qi Haibo, Lin Feng, et al.. Produced three-dimensional metal parts by electron beam selective melting[J]. Chinese J Mechanical Engineering, 2007, 43(6): 87-92.

[7] Zhong Minlin, Ning Guoqing, Liu Wenjin. Research and development on laser direct manufacturing metallic components[J]. Laser Technology, 2002, 26(5): 388-391.

[8] Wu Weihui, Yang Yongqiang. Key techniques of selective laser melting rapid prototyping system[J]. Chinese J Mechanical Engineering, 2007, 43(8): 175-180.

[9] Su Xunbin. Study on Digital Design and Direct Fabrication of Functional Parts Based on Selective Laser Melting[D]. South China University of Technology, 2011. 30-32.

[10] Zhang Dongyun, Wang Ruize, Zhao Jianzhe, et al.. Latest advance of laser direct manufacturing of metallic parts[J]. Chinese J Lasers, 2010, 37(1): 19-25.

[11] Wu Weihui, Yang Yongqiang, Wang Di, et al.. Research on variable density rapid manufacturing process based on selective laser melting technology[J]. Chinese J Lasers, 2010, 37(7): 1879-1884.

[12] Daniel Thomas. The Development of Design Rules for Selective Laser Melting[D]. Cradiff: University of Wales, 2009.

[13] Su Xubin, Yang Yongqiang, Wang Di, et al.. Study on process of non-assembly mechanisms directly fabricated by selective laser melting[J]. Chinese J Lasers, 2011, 38(6): 0603021.

[14] Y H Chen, Z Z Chen. Major factors in rapid prototyping of mechanisms[J]. J Key Engineering Materials, 2010, 443: 516-521.

[15] C Mavroidis, K J DeLaurentis, J Won. Fabrication of non-assembly mechanisms and robotic system using rapid prototyping[J]. J Mechanial Design, 2001, 123(4): 516-524.

[16] H Lipson, F C Moon, J Hai. 3D printing the history of mechanisms[J]. J Mechanical Design, 2005, 127(5): 1029-1033.

[17] K Park, Y S Kim, C S Kim. Integrated application of CAD/CAM/CAE and RP for rapid development of humanoid biped robot[J]. J Materials Processing Technology, 2007, 187-188: 609-613.

[18] S Rajagopalan, M Cutkosky. Error analysis for the in-situ fabrication of mechanisms[J]. J Mechanical Design, 2003, 125: 809-822.

[19] Hongjie Jiao, Yidu Zhang, Wuyi Chen. The lightweight design of low RCS pylon based on structural bionics[J]. J Bionic Engineering, 2010, 7(2): 182-190.

[20] A G Evans, J W Hutchinson, N A Fleck, et al.. The topological design of multifunctional cellular metals[J]. Progress in Materials Science, 2001, 46(3-4): 309-327.

[21] M Dotcheva, H Millward, D Thomas. Investigation of rapid manufactured cellular structures for injection moulding tools[C]. Proceedings of 6th CIRP Int Conf on Intelligent Computation in Manufacturing Engineering, 2008. 369-374.

[22] S Tsopanos, C J Sutcliffe, I Owen. The manufacture of micro cross-flow heat exchangers by selective laser melting[C]. Proceedings of ECI Fifth International Conference on Enhanced, Compact and Ultra Compact Heat Exchangers, 2005. 410-417.