[1] LANG R J. The science of origami[J]. Physics World,2007,20(2):30-31. [2] TACHI T. Origamizing polyhedral surfaces[J]. IEEE Transactions on Visualization & Computer Graphics,2010,16(2):298-311. [3] DEMAINE E D. Folding and unfolding linkages,paper,and polyhedra[M]. Berlin Heidelberg:Springer,2000. [4] MUELLER S,KRUCK B,BAUDISCH P. Laser Origami:Laser-cutting 3D objects[C]//Proceedings of the SIGCHI Conference on Human Factors in Computing Systems,New York:ACM,2013:2585-2592. [5] ZIRBEL S A,WILSON M E,MAGLEBY S P,et al. An origami-inspired self-deployable array[C]//ASME Smart Materials,Adaptive Structures and Intelligent Systems,New York:ASME,2013:V001T01A026. [6] RANDALL C L,GULTEPE E,GRACIAS D H. Self-folding devices and materials for biomedical applications[J]. Trends in Biotechnology,2012,30(3):138-146. [7] FERNANDES R,GRACIAS D H. Self-folding polymeric containers for encapsulation and delivery of drugs[J]. Advanced Drug Delivery Reviews,2012,64(14):1579-1589. [8] WANG Yanhu,GE Lei,WANG Panpan,et al. A three-dimensional origami-based immuno-biofuel cell for self-powered,low-cost,and sensitive point-of-care testing[J]. Chemical Communications,2014,50(16):1947-1949. [9] EDMONDSON B,BOWEN L,GRAMES C,et al. Oriceps:Origami-inspired forceps[C]//ASME 2013 Conference on Smart Materials,Adaptive Structures and Intelligent Systems,American Society of Mechanical Engineers,New York:ASME,2013:V001T01A027. [10] KURIBAYASHI K,TSUCHIYA K,YOU Z,et al. Self-deployable origami,stent grafts as a biomedical application of Ni-rich TiNi shape memory alloy foil[J]. Materials Science & Engineering A,2006,419(1):131-137. [11] YOON C,XIAO R,PARK J,et al. Functional stimuli responsive hydrogel devices by self-folding[J]. Smart Materials and Structures,2014,23(9):094008. [12] LEE D Y,KIM J S,KIM S R,et al. The deformable wheel robot using magic-ball origami structure[C]//ASME International Design Engineering Technical Conferences and Computers and Information in Engineering Conference,New York:ASME,2013:V06BT07A040. [13] WHITE P J,LATSCHA S,SCHLAEFER S,et al. Dielectric elastomer bender actuator applied to modular robotics[C]//IEEE International Conference on Intelligent Robots and Systems,Piscataway:IEEE,2011:408-413. [14] HOOVER A M,FEARING R S. Fast scale prototyping for folded millirobots[C]//IEEE International Conference on Robotics and Automation,Piscataway:IEEE,2008:886-892. [15] LEE J Y,KANG B B. Development of a multi-functional soft robot (snUMaX) and performance in robosoft grand challenge[J]. Frontiers in Robotics and AI,2016,3:UNSP63. [16] SNYDER M P,SANDERS B,EASTEP F E,et al. Vibration and flutter characteristics of a folding wing[J]. Journal of Aircraft,2009,46(3):791-799. [17] BUNGET G,SEELECKE S. BATMAV:A 2-DOF bio-inspired flapping flight platform[J]. Proceedings of SPIE the International Society for Optical Engineering,2010,7643(2):379-380. [18] POUNDS P E. Paper plane:Towards disposable low-cost folded cellulose-substrate UAVs[C]//Proceedings of Australian Robotics and Automation Association,Sydney:ARAA,2012:143-151. [19] MA Jiayao,YOU Zhong. The origami crash box[J]. Origami,2011(5):277-290. [20] MA Jiayao,YOU Zhong. A novel origami crash box with varying proles[C]//ASME 2013 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference,New York:ASME,2013:V06BT07A048. [21] ZHOU Caihua,WANG Bo,MA Jiayao,et al. Dynamic axial crushing of origami crash boxes[J]. International Journal of Mechanical Sciences,2016,118:1-12. [22] TOLMAN S S,DELIMONT I L,HOWELL L L,et al. Material selection for elastic energy absorption in origami-inspired compliant corrugations[J]. Smart Materials and Structures,2014,23(9):094010. [23] WU Weina,YOU Zhong. A solution for folding rigid tall shopping bags[J]. Proceedings of the Royal Society A:Mathematical,Physical and Engineering Sciences,2011,467(2133):2561-2574. [24] CHENG Qianqian,SONG Zemin,MA Teng,et al. Folding paper-based lithium-ion batteries for higher areal energy densities[J]. Nano Letters,2013,13(10):4969-4974. [25] SONG Zemin,MA Teng,TANG Rui,et al. Origami lithium-Ion batteries[J]. Nature Communications,2014(5):1810-1821. [26] NAM I,KIM G P,PARK S,et al. All-solid-state,origami-type foldable super capacitor chips with integrated series circuit analogues[J]. Energy and Environmental Science,2014,7(3):1095-1102. [27] MIYASHITA S,MEEKER L,TOLLEY M T,et al. Self-folding miniature elastic electric devices[J]. Smart Materials and Structures,2014,23(9):094005. [28] OCAMPO J,ZANARDI M,VACCARO P O,et al. Characterization of GaAs-based micro-origami mirrors by optical actuation[J]. Microelectronic Engineering,2004,73(1):429-434. [29] EARLY J T,HYDE R,BARON R L. Twenty-meter space telescope based on diffractive Fresnel lens[C]//SPIE 48th Annual Meeting Cardiff:SPIE,2004:148-156. [30] THRALL A,QUAGLIA C. Accordion shelters:A historical review of origami-like deployable shelters developed by the US military[J]. Engineering Structures,2014(59):686-692. [31] MARTIN F,THRALL A. Honeycomb core sandwich panels for origami-inspired deployable shelters:Multi-objective optimization for minimum weight and maximum energy efficiency[J]. Engineering Structures,2014(69):158-167. [32] QUAGLIA C,BALLARD Z,THRALL A. Parametric modeling of an air-liftable origami-inspired deployable shelter with a novel erection strategy[J]. Mobile and Rapidly Assembled Structures IV,2014(136):23-33. [33] FUCHI K,DIAZ A R,ROTHWELL E J,et al. An origami tunable metamaterial[J]. Journal of Applied Physics,2012,111(8):2075-2084. [34] SCHENK M,GUEST S D. Geometry of Miura-folded metamaterials[J]. PNAS,2013,110(9):3276-3281. [35] MARTINEZ R V,FISH C R,CHEN X,et al. Elastomeric origami:Programmable paper-elastomer composites as pneumatic actuators[J]. Advanced Function Material,2012(22):1376-1384. [36] FANG Hongbin,ZHANG Yetong,WANG K W. Origami-based earthworm-like locomotion robots[J]. Bioinspiration and Biomimetics,2017,12:065003. [37] LI S,VOGT D M,RUS D,et al. Fluid-driven origami-inspired artificial muscles[J]. Proceedings of the National Academy of Sciences of the United States of America,2017,114(50):13132-13137. [38] KIM S J,LEE D Y,JUNG G P,et al. An origami-inspired,self-locking robotic arm that can be folded flat[J]. Science Robotics,2018,3(16):eaar2915. [39] ZHANG Ketao,QIU Chen,DAI Jiansheng. An origami parallel structure integrated deployable continuum robot[C]//ASME 2015 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference,New York:ASME,2015:V05BT08A032. [40] JEONG D,LEE K. Design and analysis of an origami-based three-finger manipulator[J]. Robotica,2018,36:261-274. [41] KAMRAVA S,MOUSANEZHAD D,FELTON S M,et al. Programmable Origami strings[J]. Advanced Materials Technologies,2018:1700276. [42] TOLLEY M T,FELTON S M,MIYASHITA S,et al. Self-folding origami:Shape memory composites activated by uniform heating[J]. Smart Materials and Structures,2014,23(9):094006. [43] FELTON S,TOLLEY M,DEMAINE E,et al. A method for building self-folding machines[J]. Science,2014,345(6197):644-646. [44] PAIK J K,AN B,RUS D,et al. Robotic origamis:Self-morphing modular robot[J]. ICMC,2012:206919. [45] ONAL C D,WOOD R J,RUS D. An origami-inspired approach to worm robots[J]. IEEE/ASME Trans. Mechatron,2013,18:430-438. [46] MIYASHITA S,GUITRON S,LUDERSDORFER M,et al. An untethered miniature origami robot that self-folds,walks,swims,and degrades[C]//IEEE 2015 International Conference on Robotics and Automation,Piscataway:IEEE,2015:1490-1496. [47] MIYASHITA S,GUITRON S,LI S,et al. Robotic metamorphosis by origami exoskeletons[J]. Science Robotics,2017,2:eaao4369. [48] BRUCE P L,AMEYA N,RANDALL W. Effect of metal ion type on the movement of hydrogel actuator based On catechol-metal ion coordination chemistry[J]. Sensors and Actuators B,2016(227):248-254. [49] OKUZAKI H,SAIDO T,SUZUKI H,et al. A biomorphic origami actuator fabricated by folding a conducting paper[J]. Journal of Physics:Conference Series,2008,127:012001. [50] HIRAI T,KOBAYASHI S,HIRAI M,et al. Bending induced by creeping of plasticized poly(vinyl chloride) gel[J]. Proceedings of SPIE-The International Society for Optical Engineering,2004,5385:433-441. [51] ZHAO Jianwen,NIU Junyang,MCCOUL D,et al. Phenomena of nonlinear oscillation and special resonance of a dielectric elastomer minimum energy structure rotary joint[J]. Applied Physics Letters,2015,106(13):133504. [52] BASSIK N,BRAFMAN A,ZARAFSHAR A M,et al. Enzymatically triggered actuation of miniaturized tools[J]. Journal of the American Chemical Society,2010,132(46):16314-16317. [53] KWAN K W,LI S J,HAU N Y,et al. Light-stimulated actuators based on nickel hydroxide-oxyhydroxide[J]. Science Robotics,2018,3:eaat4051. [54] AHMED S,LAUFF C,CRIVARO A,et al. Multi-field responsive origami structures:Preliminary modeling and experiments[C]//ASME 2013 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference,New York:ASME,2013,DETC-12405:V06BT07A028. [55] LAGOUDAS D C. Shape memory alloys:Modeling and engineering applications[M]. Berlin Heidelberg:Springer,2008. |