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On-line Access: 2024-08-27
Received: 2023-10-17
Revision Accepted: 2024-05-08
Crosschecked: 2022-05-04
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Citations: Bibtex RefMan EndNote GB/T7714
Xiang-juan BAI, Jian-zhong SHANG, Zi-rong LUO, Tao JIANG, Qian YIN. Development of amphibious biomimetic robots[J]. Journal of Zhejiang University Science A, 2022, 23(3): 157-187.
@article{title="Development of amphibious biomimetic robots",
author="Xiang-juan BAI, Jian-zhong SHANG, Zi-rong LUO, Tao JIANG, Qian YIN",
journal="Journal of Zhejiang University Science A",
volume="23",
number="3",
pages="157-187",
year="2022",
publisher="Zhejiang University Press & Springer",
doi="10.1631/jzus.A2100137"
}
%0 Journal Article
%T Development of amphibious biomimetic robots
%A Xiang-juan BAI
%A Jian-zhong SHANG
%A Zi-rong LUO
%A Tao JIANG
%A Qian YIN
%J Journal of Zhejiang University SCIENCE A
%V 23
%N 3
%P 157-187
%@ 1673-565X
%D 2022
%I Zhejiang University Press & Springer
%DOI 10.1631/jzus.A2100137
TY - JOUR
T1 - Development of amphibious biomimetic robots
A1 - Xiang-juan BAI
A1 - Jian-zhong SHANG
A1 - Zi-rong LUO
A1 - Tao JIANG
A1 - Qian YIN
J0 - Journal of Zhejiang University Science A
VL - 23
IS - 3
SP - 157
EP - 187
%@ 1673-565X
Y1 - 2022
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/jzus.A2100137
Abstract: amphibious robots are becoming increasingly important for civilian, scientific, and environmental missions. They are widely used in disaster rescue, ecosystem monitoring, and entertainment. However, some have two different locomotion systems that need to be changed manually to fulfill both swimming in the water and moving on land, which may reduce their efficiency and reliability. Applying bioinspiration and biomimetics, many recently developed amphibious robots can undertake various tasks in complex amphibious environments with high mobility, flexibility, and energy efficiency. This review overviews the latest developments in amphibious robots, emphasizing biomimetic design concepts, backbone driving mechanisms, and typical applications. The performance indices of amphibious robots mimicking 13 different natural sources are compared, based on 10 different propulsion principles/modes, travel speed, working efficiency, maneuverability, and stability. Finally, the current challenges and perspectives of amphibious bio-inspired robots are discussed. This article summarizes the current types of amphibious robots and their movement and behavior solutions. The design concepts and operating mechanisms of amphibious robots reviewed here can be readily applied to other robotic studies.
[1]AdamatzkyA, KomosinskiM, 2009. Artificial Life Models in Hardware. Springer, London, UK, p.35-64.
[2]AltendorferR, MooreN, KomsuogluH, et al., 2001. RHex: a biologically inspired hexapod runner. Autonomous Robots, 11(3):207-213.
[3]AndrewsJG, BuzziS, ChoiW, et al., 2014. What will 5G be? IEEE Journal on Selected Areas in Communications, 32(6):1065-1082.
[4]ArientiA, CalistiM, Giorgio-SerchiF, et al., 2013. PoseiDRONE: design of a soft-bodied ROV with crawling, swimming and manipulation ability. MTS/IEEE OCEANS-San Diego, p.21-27.
[5]AyersJ, 2004. Underwater walking. Arthropod Structure & Development, 33(3):347-360.
[6]BarnesCR, BestMMR, JohnsonFR, et al., 2013. Challenges, benefits, and opportunities in installing and operating cabled ocean observatories: perspectives from NEPTUNE Canada. IEEE Journal of Oceanic Engineering, 38(1):144-157.
[7]BoxerbaumAS, WerkP, QuinnR, et al., 2005. Design of an autonomous amphibious robot for surf zone operation: Part I mechanical design for multi-mode mobility. Proceedings of the IEEE/ASME International Conference on Advanced Intelligent Mechatronics, p.1459-1464.
[8]BreithauptR, DahnkeJ, Ghazi-ZahediK, et al., 2002. Robo-Salamander–an approach for the benefit of both robotics and biology. Proceedings of the 5th International Conference on Climbing and Walking Robots, p.55-62.
[9]CalistiM, CorucciF, ArientiA, et al., 2015. Dynamics of underwater legged locomotion: modeling and experiments on an octopus-inspired robot. Bioinspiration & Biomimetics, 10(4):046012.
[10]CaoYJ, ShangJZ, LiangKS, et al., 2012. Review of soft-bodied robots. Journal of Mechanical Engineering, 48(3):25-33 (in Chinese).
[11]ChenL, WangYC, LiB, 2002. Present state and future direction towards snake-robot research. Robot, 24(6):559-563 (in Chinese).
[12]ChenYH, LeS, TanQC, et al., 2017. A lobster-inspired robotic glove for hand rehabilitation. Proceedings of the IEEE International Conference on Robotics and Automation, p.4782-4787.
[13]ChigisakiS, MoriM, YamadaH, et al., 2005. Design and control of amphibious snake-like robot ACM-R5. Nippon Kikai Gakkai Robotikusu, Mekatoronikusu Koenkai Koen Ronbunshu.
[14]CrespiA, BadertscherA, GuignardA, et al., 2005. AmphiBot I: an amphibious snake-like robot. Robotics and Autonomous Systems, 50(4):163-175.
[15]CrespiA, KarakasiliotisK, GuignardA, et al., 2013. Salamandra Robotica II: an amphibious robot to study salamander-like swimming and walking gaits. IEEE Transactions on Robotics, 29(2):308-320.
[16]DerraikJGB, 2002. The pollution of the marine environment by plastic debris: a review. Marine Pollution Bulletin, 44(9):842-852.
[17]DeyBB, ManjannaS, DudekG, 2013. Ninja legs: amphibious one degree of freedom robotic legs. Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems.
[18]DiardJ, BessiereP, MazerE, 2004. A theoretical comparison of probabilistic and biomimetic models of mobile robot navigation. International Conference on Robotics & Automation, p.933-938.
[19]DudekG, GiguereP, PrahacsC, et al., 2007. AQUA: an amphibious autonomous robot. Computer, 40(1):46-53.
[20]DuellmanWE, TruebL, 1994. Biology of Amphibians, 2nd Edition. Johns Hopkins University Press, Baltimore, USA.
[21]DunnillMS, 1973. Animal tissue techniques. Journal of Clinical Pathology, 26(4):316.
[22]ZurichETH, 2010. Naro-Tartaruga. Swiss Federal Institute of Technology, Switzerland. http://www.naro.ethz.ch/p2/tartaruga.html
[23]FanJZ, ZhangW, KongPC, et al., 2017a. Design and dynamic model of a frog-inspired swimming robot powered by pneumatic muscles. Chinese Journal of Mechanical Engineering, 30(5):1123-1132.
[24]FanJZ, ZhangW, YuanBW, et al., 2017b. Propulsive efficiency of frog swimming with different feet and swimming patterns. Biology Open, 6(4):503-510.
[25]FavaliP, PersonR, BarnesCR, et al., 2010. Seafloor observatory science. Proceedings of OceanObs’09: Sustained Ocean Observations and Information for Society, p.292-303.
[26]FESTO, 2006. Aqua_ray. FESTO Company.https://www.festo.com/PDF_Flip/corp/Festo_Aqua_ray/en/index.html
[27]FESTO, 2013. Bionic technology bearers for the water technology sector. FESTO Company.https://www.festo.com/PDF_Flip/corp/Festo_AquaJellies/en/files/assets/common/downloads/Festo_AquaJellies_en.pdf
[28]FloydS, SittiM, 2008. Design and development of the lifting and propulsion mechanism for a biologically inspired water runner robot. IEEE Transactions on Robotics, 24(3):698-709.
[29]FranzMO, MallotHA, 2000. Biomimetic robot navigation. Robotics and Autonomous Systems, 30(1-2):133-153.
[30]FuL, WangBR, XuXH, 2005. Dynamic model and simulation of biped robot with heterogeneous legs. Journal of Northeastern University (Natural Science), 26(7):617-620 (in Chinese).
[31]FurnessRW, CamphuysenK, 1997. Seabirds as monitors of the marine environment. ICES Journal of Marine Science, 54(4):726-737.
[32]GermanA, JenkinM, 2009. Gait synthesis for legged underwater vehicles. Proceedings of the 5th International Conference on Autonomic and Autonomous Systems, p.189-194.
[33]GreinerH, ShectmanA, ChikyungW, et al., 1996. Autonomous legged underwater vehicles for near land warfare. Proceedings of the Symposium on Autonomous Underwater Vehicle Technology, p.41-48.
[34]GuoSX, MaoSL, ShiLW, et al., 2012. Development of an amphibious mother spherical robot used as the carrier for underwater microrobots. Proceedings of the International Conference on Complex Medical Engineering, p.758-762.
[35]GuoSX, HeYL, ShiLW, et al., 2018. Modeling and experimental evaluation of an improved amphibious robot with compact structure. Robotics and Computer-Integrated Manufacturing, 51:37-52.
[36]GuoZY, LiT, WangML, 2018. A survey on amphibious robots. Proceedings of the 37th Chinese Control Conference, p.5299-5304.
[37]HajdukM, KoukolováL, 2015. Trends in industrial and service robot application. Applied Mechanics and Materials, 791:161-165.
[38]HanB, LuoX, WangXJ, et al., 2011. Mechanism design and gait experiment of an amphibian robotic turtle. Advanced Robotics, 25(16):2083-2097.
[39]HarkinsR, WardJ, VaidyanathanR, et al., 2005. Design of an autonomous amphibious robot for surf zone operations: Part II–hardware, control implementation and simulation. Proceedings of the IEEE/ASME International Conference on Advanced Intelligent Mechatronics, p.1465-1470.
[40]HeYL, ShiLW, GuoSX, et al., 2016. Preliminary mechanical analysis of an improved amphibious spherical father robot. Microsystem Technologies, 22(8):2051-2066.
[41]HeYL, ZhuLQ, SunGK, et al., 2019a. Underwater motion characteristics evaluation of multi amphibious spherical robots. Microsystem Technologies, 25(2):499-508.
[42]HeYL, ZhuLQ, SunGK, et al., 2019b. Visual positioning system for small-scaled spherical robot in underwater environment. Microsystem Technologies, 25(2):561-571.
[43]HeYL, ZhuLQ, SunGK, et al., 2019c. Cooperative localization and evaluation of small-scaled spherical underwater robots. Microsystem Technologies, 25(2):573-585.
[44]HiroseS, YamadaH, 2009. Snake-like robots [Tutorial]. IEEE Robotics & Automation Magazine, 16(1):88-98.
[45]HiranoL, Martins-FilhoL, DuarteR, et al., 2009. Development of an amphibious robotic propulsor based on electroactive polymers. Proceedings of the 4th International Conference on Autonomous Robots and Agents, p.284-289.
[46]HopkinsJK, SpranklinBW, GuptaSK, 2009. A survey of snake-inspired robot designs. Bioinspiration & Biomimetics, 4(2):021001.
[47]IjspeertAJ, 2001. A connectionist central pattern generator for the aquatic and terrestrial gaits of a simulated salamander. Biological Cybernetics, 84(5):331-348.
[48]IjspeertAJ, 2008. Central pattern generators for locomotion control in animals and robots: a review. Neural Networks, 21(4):642-653.
[49]IjspeertAJ, CabelguenJM, 2006. Gait transition from swimming to walking: investigation of salamander locomotion control using nonlinear oscillators. In: Adaptive Motion of Animals and Machines. Springer, Tokyo, Japan, p.177-188.
[50]IjspeertAJ, CrespiA, RyczkoD, et al., 2007. From swimming to walking with a salamander robot driven by a spinal cord model. Science, 315(5817):1416-1420.
[51]IngerRF, 1964. Animal species and evolution by Ernst Mayr. Copeia, 1964(1):245-247.
[52]JiangCQ, LiYW, 2008. Multi-sensor information fusion and its application. Electro-Optic Technology Application, 22(9):6095-6098.
[53]JiangT, Munguia-LopezJG, Flores-TorresS, et al., 2019. Extrusion bioprinting of soft materials: an emerging technique for biological model fabrication. Applied Physics Reviews, 6(1):011310.
[54]KarakasiliotisK, ThandiackalR, MeloK, et al., 2016. From cineradiography to biorobots: an approach for designing robots to emulate and study animal locomotion. Journal of the Royal Society Interface, 13(119):20151089.
[55]KatoN, 2011. Swimming and walking of an amphibious robot with fin actuators. Marine Technology Society Journal, 45(4):181-197.
[56]KaznovV, SeemanM, 2010. Outdoor navigation with a spherical amphibious robot. Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems, p.5113-5118.
[57]KimK, UraT, 2013. Terrain-adaptive optimal guidance for near-bottom survey by an autonomous underwater vehicle. Proceedings of the IEEE International Underwater Technology Symposium, p.1-8.
[58]KiontkeK, SudhausW, 2006. Ecology of Caenorhabditis Species. Wormbook.
[59]LachsWR, SutantoD, 1995. Application of battery energy storage in power systems. Proceedings of the International Conference on Power Electronics & Drive Systems, p.6.
[60]LaddTD, JelezkoF, LaflammeR, et al., 2010. Quantum computers. Nature, 464(7285):45-53.
[61]LaschiC, MazzolaiB, MattoliV, et al., 2009. Design and development of a soft actuator for a robot inspired by the octopus arm. In: Khatib O, Kumar V, Pappas GJ (Eds.), Experimental Robotics. The Eleventh International Symposium. Springer.
[62]LiMX, GuoSX, HirataH, et al., 2017. A roller-skating/walking mode-based amphibious robot. Robotics and Computer-Integrated Manufacturing, 44:17-29.
[63]LiSC, XuLD, ZhaoSS, 2018. 5G internet of things: a survey. Journal of Industrial Information Integration, 10:1-9.
[64]LiX, LiFQ, GuoYL, et al., 2020. The development trend and prospects of bionic sensors. Broad Review of Scientific Stories, (8):15-17.
[65]LiYS, YangMM, SunHX, et al., 2018. A novel amphibious spherical robot equipped with flywheel, pendulum, and propeller. Journal of Intelligent & Robotic Systems, 89(3):485-501.
[66]LiangX, XuM, XuLC, et al., 2012. The AmphiHex: a novel amphibious robot with transformable leg-flipper composite propulsion mechanism. Proceedings of the IEEE/RSJ International Conference on Intelligent Robots & Systems.
[67]LinZN, JiangT, KinsellaJM, et al., 2021. Assessing roughness of extrusion printed soft materials using a semi-quantitative method. Materials Letters, 303:130480.
[68]LinZN, JiangT, ShangJZ, 2022. The emerging technology of biohybrid micro-robots: a review. Bio-Design and Manufacturing, 5:107-132.
[69]LiuCB, WangYJ, RenLQ, et al., 2019. A review of biological fluid power systems and their potential bionic applications. Journal of Bionic Engineering, 16(3):367-399.
[70]LundHH, 2004. Modern artificial intelligence for human-robot interaction. Proceedings of the IEEE, 92(11):1821-1838.
[71]MartínEM, 2010. Swarm Robotics, from Biology to Robotics. In-Teh, Vukovar, Croatia, p.47.
[72]MatsuoT, YokoyamaT, UenoD, et al., 2008. Biomimetic motion control system based on a CPG for an amphibious multi-link mobile robot. Journal of Bionic Engineering, 5(S1):91-97.
[73]MayrE, 1963. Animal Species and Evolution. Belknap Press of Harvard University Press, Cambridge, UK, p.1-18.
[74]MirvakiliSM, HunterIW, 2018. Artificial muscles: mechanisms, applications, and challenges. Advanced Materials, 30(6):1704407.
[75]MuftiAA, HsiungB, 1989. Solid modeling in structural engineering. Computer-Aided Civil and Infrastructure Engineering, 4(4):275-287.
[76]MurielDF, CowenEA, 2018. On the realization of a second buckling mode in a periodically-constrained heavy elastica. Extreme Mechanics Letters, 21:76-81.
[77]NguyenPL, LeeBR, AhnKK, 2016. Thrust and swimming speed analysis of fish robot with non-uniform flexible tail. Journal of Bionic Engineering, 13(1):73-83.
[78]OhashiT, YamadaH, HiroseS, 2010. Loop forming snake-like robot ACM-R7 and its serpenoid oval control. Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems, p.413-418.
[79]PanSW, ShiLW, GuoSX, 2015. A kinect-based real-time compressive tracking prototype system for amphibious spherical robots. Sensors, 15(4):8232-8252.
[80]ParkHS, SittiM, 2009. Compliant footpad design analysis for a bio-inspired quadruped amphibious robot. Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems, p.645-651.
[81]ParkSJ, GazzolaM, ParkKS, et al., 2016. Phototactic guidance of a tissue-engineered soft-robotic ray. Science, 353(6295):158-162.
[82]PaschalT, BellMA, SperryJ, et al., 2019. Design, fabrication, and characterization of an untethered amphibious sea urchin-inspired robot. IEEE Robotics and Automation Letters, 4(4):3348-3354.
[83]PaulsonLD, 2004. Biomimetic robots. Computer, 37(9):48-53.
[84](Pliant energy systems)PES, 2017. Robotics.https://www.pliantenergy.com/robotics
[85]PfeiferR, LungarellaM, IidaF, 2007. Self-organization, embodiment, and biologically inspired robotics. Science, 318(5853):1088-1093.
[86]PhibbsP, LentzS, 2007. Cabled ocean science observatories as test beds for underwater technology. OCEANS 2007-Europe, p.1-5.
[87]SandryhailaA, MouraJMF, 2014. Big data analysis with signal processing on graphs: representation and processing of massive data sets with irregular structure. IEEE Signal Processing Magazine, 31(5):80-90.
[88]SaranliU, BuehlerM, KoditschekDE, 2001. RHex: a simple and highly mobile hexapod robot. The International Journal of Robotics Research, 20(7):616-631.
[89]SawanoS, IkedaJ, UtsumiN, et al., 1984. A sealing robot system with visual seam tracking. Robotica, 2(1):41-46.
[90]SfakiotakisM, KazakidiA, TsakirisDP, 2015. Octopus-inspired multi-arm robotic swimming. Bioinspiration & Biomimetics, 10(3):035005.
[91]ShihE, BahlP, SinclairMJ, 2002. Wake on wireless: an event driven energy saving strategy for battery operated devices. Proceedings of the 8th International Conference on Mobile Computing and Networking, p.160-171.
[92]ShiLW, GuoSX, MaoSL, et al., 2013a. Development of an amphibious turtle-inspired spherical mother robot. Journal of Bionic Engineering, 10(4):446-455.
[93]ShiLW, GuoSX, MaoSL, et al., 2013b. Development of a lobster-inspired underwater microrobot. International Journal of Advanced Robotic Systems, 10(1):44.
[94]SpeersA, TopolA, ZacherJ, et al., 2011. Monitoring underwater sensors with an amphibious robot. Proceedings of the Canadian Conference on Computer and Robot Vision, p.153-159.
[95]StefaniniC, OrofinoS, ManfrediL, et al., 2012. A novel autonomous, bioinspired swimming robot developed by neuroscientists and bioengineers. Bioinspiration & Biomimetics, 7(2):025001.
[96]SunSL, DengZL, 2004. Multi-sensor optimal information fusion Kalman filter. Automatica, 40(6):1017-1023.
[97]SunY, MaS, LuoX, 2011. Design of an eccentric paddle locomotion mechanism for amphibious robots. Proceedings of the IEEE International Conference on Robotics and Biomimetics, p.1098-1103.
[98]TakayamaT, HiroseS, 2002. Amphibious 3D active cord mechanism “HELIX” with helical swimming motion. Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems, p.775-780.
[99]ThomasAP, MilanoM, SellMGG, et al., 2005. Synthetic jet propulsion for small underwater vehicles. Proceedings of the IEEE International Conference on Robotics and Automation, p.181-187.
[100]TriantafyllouMS, TriantafyllouGS, 1995. An efficient swimming machine. Scientific American, 272(3):64-70.
[101]WangG, ChenX, JinLX, et al., 2017. Study of the free-swimming performance of a crab-like robot. Journal of Harbin Engineering University, 38(7):1072-1078 (in Chinese).
[102]WangGB, ChenDS, ChenKW, et al., 2015. The current research status and development strategy on biomimetic robot. Journal of Mechanical Engineering, 51(13):27-44 (in Chinese).
[103]WangHL, WangG, ChenX, et al., 2015. Dynamic modeling and motion control of a crablike robot in floating gait. Robot, 37(2):176-187 (in Chinese).
[104]WangW, YuJ, DingR, et al., 2009. Bio-inspired design and realization of a novel multimode amphibious robot. Proceedings of the IEEE International Conference on Automation and Logistics, p.140-145.
[105]WegstUGK, BaiH, SaizE, et al., 2015. Bioinspired structural materials. Nature Materials, 14(1):23-36.
[106]WuGH, LuZY, LuoZR, et al., 2019. Experimental analysis of a novel adaptively counter-rotating wave energy converter for powering drifters. Journal of Marine Science and Engineering, 7(6):171.
[107]WuZY, QiJ, ZhangS, 2014. Amphibious robots: a review. Applied Mechanics and Materials, 494-495:1036-1041.
[108]Alvarado PVy, ChinS, LarsonW, et al., 2010. A soft body under-actuated approach to multi degree of freedom biomimetic robots: a stingray example. Proceedings of the 3rd IEEE RAS & EMBS International Conference on Biomedical Robotics and Biomechatronics, p.473-478.
[109]YangQH, YuJZ, TanM, et al., 2007. Amphibious biomimetic robots: a review. Robot, 29(6):601-608 (in Chinese).
[110]YangXB, WangTM, LiangJH, et al., 2015. Survey on the novel hybrid aquatic–aerial amphibious aircraft: aquatic unmanned aerial vehicle (AquaUAV). Progress in Aerospace Sciences, 74:131-151.
[111]YangXR, LuoGE, GuoY, et al., 2001. Multisensor poly information fusion technology and its application. Proceedings of the International Conference on Sensor Technology, p.449-454.
[112]YimM, ShirmohammadiB, BenelliD, 2007. Amphibious modular robotic astrobiology. Defense and Security Symposium, p.65611S.
[113]YooSY, ShimH, JunBH, et al., 2012. Design of walking and swimming algorithms for a multi-legged underwater robot Crabster CR200. Proceedings of the Oceans Conference, p.74-87.
[114]YuJZ, DingR, YangQH, et al., 2012. On a bio-inspired amphibious robot capable of multimodal motion. IEEE/ASME Transactions on Mechatronics, 17(5):847-856.
[115]ZhaFS, BingZS, WangJ, et al., 2015. Developing of a wheel-paddle integrated propeller for amphibious robot based on moving webbed paddle wheels. Applied Mechanics and Materials, 701-702:689-696.
[116]ZhangDB, TanHL, PanXF, 2003. The realization of distributed control in snake robot. Proceedings of the 15th National Conference of Computer Science and Technology in China, p.509-512 (in Chinese).
[117]ZhangSW, LiangX, XuLC, et al., 2013. Initial development of a novel amphibious robot with transformable fin-leg composite propulsion mechanisms. Journal of Bionic Engineering, 10(4):434-445.
[118]ZhangSW, ZhouYC, XuM, et al., 2016. AmphiHex-I: locomotory performance in amphibious environments with specially designed transformable flipper legs. IEEE/ASME Transactions on Mechatronics, 21(3):1720-1731.
[119]ZhengJ, 2012. Design and Motion Analysis of Bionic Robot Crocodile Crawling Mechanism. MS Thesis, Wuhan University of Technology, Wuhan, China(in Chinese).
[120]ZhongB, ZhouYC, LiXX, et al., 2016. Locomotion performance of the amphibious robot on various terrains and underwater with flexible flipper legs. Journal of Bionic Engineering, 13(4):525-536.
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