We present a scheme of two-dimensional module reconfiguration based on interactions between microscale magnetic modules with potential applications in micro-robotics, particularly in automatic micro-fabrication, non-invasive diagnoses, micro-surgery, and drug delivery at unreachable sites. The approach taken is a mixture of a top-down engineering approach and a bottom-up self-assembly approach, where reconfiguration commands are delivered from outside the workspace in the form of a magnetic field, which directs configuration changes in the set of modules by changing the strengths of individual magnetic moments. The magnetic modules in the study, 750μm in size, are constrained to a liquid surface, providing a simplified two degrees of freedom translational motion environment, where the laterally interacting inter-module magnetic force determines the assembly configuration. In this way, the relative distance of the magnets simply reflects the strength of the interactions, and thus easily enables the design of the system’s reconfiguration scenario. Reconfiguration occurs when the magnetic attractive forces are changed. To direct the assembly morphology in a controlled manner, the modules are addressed magnetically by incorporating a different magnetic material into each module type, each with different magnetic hysteresis characteristics. For addressing different modules’ magnetizations, we incorporate three different magnetic materials that feature different magnetic coercivities. This allows for the independent control of the magnetization of each material using applied external fields of varying strength, leading to arbitrary configuration change in a three-module set and limited control over a four-module set. General cases with more than five modules are further discussed.
BishopKJMWilmerCESohSGrzybowskiBA (2009) Nanoscale forces and their uses in self-assembly. Small5: 1600–1630.
2.
BöhringerKFGoldbergKCohnMHoweRPisanoA (1998) Parallel microassembly with electrostatic force fields. In: IEEE International Conference on Robotics and Automation (ICRA), vol. 2, pp. 1204–1211.
3.
BonchevaMFerrignoRBruzewiczDAWhitesidesGM (2003) Plasticity in self-assembly: Templating generates functionally different circuits from a single precursor. Angewandte Chemie International Edition42: 3368–3371.
4.
BowdenNChoiISGrzybowskiBAWhitesidesGM (1999) Mesoscale self-assembly of hexagonal plates using lateral capillary forces: Synthesis using the ‘capillary bond’. Journal of American Chemical Society121: 5373–5391.
5.
BraillonPM (1978) Magnetic plate comprising permanent magnets and electropermanent magnets. US Patent 4075589.
6.
CohnMBKimCJ (1991) Self-assembling electrical networks: An application of micromachining technology. In: International Conference on Solid-State Sensors and Actuators, pp. 490–493.
7.
DejeuJRougeotPGauthierMBoireauW (2009) Robotic submerged microhandling controlled by pH switching. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 1855–1860.
8.
DemaineEDHohenbergerSLiben-NowellD (2002) Tetris is Hard, even to Approximate. Technical Report, Cornell University.
9.
DillerEFloydSPawasheCSittiM (2012) Control of multiple heterogeneous magnetic micro-robots in two dimensions. IEEE Transactions on Robotics, 28: 172–182. DOI: 10.1109/TRO.2011.2170330.
10.
DillerEPawasheCFloydSSittiM (2011) Assembly and Disassembly of Magnetic Mobile Micro-Robots towards Deterministic 2-D Reconfigurable Micro-Systems, International Journal of Robotics Research30(14): 1667–1680.
11.
DillerEMiyashitaSSittiM (2012a) Magnetic hysteresis for multi-state addressable magnetic microrobotic control. In: International Conference on Intelligent Robots and Systems, pp. 2325–2331.
DonaldBRLeveyCGMcGrayCDPaprotnyIRusD (2006) An untethered, electrostatic, globally controllable MEMS micro-robot. Journal of Microelectromechanical Systems15: 1–15.
14.
DonaldBRLeveyCGPaprotnyI (2008) Planar microassembly by parallel actuation of MEMS microrobots. Journal of Microelectromechanical Systems17: 789–808.
15.
EdgarRFMartzloffFDTompkinsRE (1972) Magnetic latch and switch using cobalt-rare earth permanent magnets. US Patent 3671893.
16.
FeinerALovellCALowryTNRidingerPG (1960) The ferreed - a new switching device. The Bell System Technical Journal39: 1–30.
17.
FloydSPawasheCSittiM (2009a) Microparticle manipulation using multiple untethered magnetic micro-robots on an electrostatic surface. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 528–533.
18.
FloydSPawasheCSittiM (2009b) Modeling and experimental characterization of an untethered magnetic micro-robot. The International Journal of Robotics Research28: 1077–1094.
19.
FrutigerDRVollmersKKratochvilBENelsonBJ (2009) Small, fast, and under control: wireless resonant magnetic micro-agents. The International Journal of Robotics Research13: 1–24.
20.
GendreauDGauthierMHeribanDLutzP (2010) Modular architecture of the microfactories for automatic micro-assembly. Robotics and Computer-Integrated Manufacturing26: 354–360.
21.
GilpinKKnaianARusD (2010) Robot pebbles: One centimeter module for programmable matter through self-disassembly. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 2485–2492.
22.
GraciasDHTienJBreenTLHsuCWhitesidesGM (2000) Forming electrical networks in three dimensions by self-assembly. Science289: 1170–1172.
GrzybowskiBAWinklemanAWilesJABrumerYWhitesidesGM (2003) Electrostatic self-assembly of macroscopic crystals using contact electrification. Nature Materials2: 241–245.
25.
HosokawaKShimoyamaIMiuraH (1996) Two-dimensional micro-self-assembly using the surface tension of water. Sensors and Actuators A57: 117–125.
26.
IsraelsonAF (1969) Turn-off permanent magnet. US Patent 3452310.
27.
JacobsHOTaoARSchwartzAGraciasDHWhitesidesGM (2002) Fabrication of a cylindrical display by patterned assembly. Science296: 323–325.
28.
KaragozlerMECampbellJDFedderGKGoldsteinSCWellerMPYoonBW (2007) Electrostatic latching for inter-module adhesion, power transfer, and communication in modular robots. In: IEEE International Conference on Intelligent Robots and Systems (IROS), pp. 2779–2786.
29.
KlavinsE (2007) Programmable self-assembly. IEEE Control System Magazine27: 43–56.
30.
KummerMPAbbottJJKratochvilBEBorerRSengulANelsonBJ (2010) Octomag: An electromagnetic system for 5-dof wireless micromanipulation. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 1006–1017.
31.
LoveJCUrbachARPrentissMGWhitesidesGM (2003) Three-dimensional self-assembly of metallic rods with submicron diameters using magnetic interactions. Journal of American Chemical Society125: 12696–12697.
32.
MaoCThalladiVRWolfeDBWhitesidesSWhitesidesGM (2002) Dissections: Self-assembled aggregates that spontaneously reconfigure their structures when their environment changes. Journal of the American Chemical Society124: 14508–14509.
33.
MastrangeliMAbbasiSVarelCHoofCVCelisJPBöhringerKF (2009) Self-assembly from milli- to nanoscales: methods and applications. Journal of Micromechanics and Microengineering19: 1–37.
34.
MermoudGMastrangeliMUpadhyayUMartinoliA (2012) Real-time automated modeling and control of self-assembling systems. In: IEEE International Conference on Robotics and Automation.
35.
MiyashitaSCasanovaFLungarellaMRolf PfeiferF (2008) Peltier-based freeze–thaw connector for waterborne self-assembly systems. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 1325–1330.
36.
MiyashitaSNagyZNelsonBJPfeiferR (2009) The influence of shape on parallel self-assembly. Entropy11: 643–666.
37.
NappNBurdenSKlavinsE (2006) The statistical dynamics of programmed self-assembly. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 1469–1476.
38.
OsswaldMIidaF (2011) A climbing robot based on hot melt adhesion, Proceedings of the 2011 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS 2011), 25–30 September 2011, San Francisco, USA, 5107–5112.
39.
PawasheCFloydSSittiM (2009) Magnetic microrobot control using electrostatic clamping. Applied Physics Letters94: 164108.
PenroseLS (1958) Mechanics of self-reproduction. Annals of Human Genetics23: 59–72.
42.
PignataroDF (2001) Electrically switchable magnet system. US Patent 6229422.
43.
RamadanQUkYSVaidyanathanK (2007) Large scale microcomponents assembly using an external magnetic array. Applied Physics Letters90: 172502.
44.
RandhawaJSKanuLNSinghGGraciasDH (2010) Importance of surface patterns for defect mitigation in three-dimensional self-assembly. Langmuir26: 12534–12539.
45.
RochatFSchoeneichPBonaniMMagnenatSMondadaFBleulerH (2010) Design of magnetic switchable device (MSD) and applications in climbing robot. In: The 13th International Conference on Climbing and Walking Robots and the Support Technologies for Mobile Machines (CLAWAR), pp. 375–382.
46.
RothemundPWK (2000) Using lateral capillary forces to compute by self-assembly. Proceedings of the National Academy of Sciences97: 984–989.
47.
SaitouK (1999) Conformational switching in self-assembling mechanical systems. IEEE Transactions on Robotics and Automation15: 510–520.
SchempfHChemelBEverettN (1995) Neptune: Above-ground storage tank inspetion robot system. IEEE Robotics and Automation Society Magazine2: 9–15.
50.
ShetyeSBEskinaziIArnoldDP (2008) Self-assembly of millimeter-scale components using integrated micromagnets. IEEE Transactions on Magnetics44: 4293–4296.
51.
SittiM (2009) Voyage of the microrobots. Nature458: 1121–1122.
52.
TolleyMTKalontarovMNeubertJEriksonDLipsonH (2010) Stochastic modular robotic systems: A study of fluidic assembly strategies. IEEE Transactions on Robotics26: 518–530.
53.
WhitePZykovVBongardJLipsonH (2005) Three dimensional stochastic reconfiguration of modular robots. In: International Conference on Robotics Science and Systems (RSS), pp. 161–168.
54.
WhitesidesGMGrzybowskiB (2002) Self-assembly at all scales. Science295: 2418–2421.
55.
WolfeDBSneadAMaoCBowdenNBWhitesidesGM (2003) Mesoscale self-assembly: Capillary interactions when positive and negitive menisci have similar amplitudes. Langmuir19: 2206–2214.
56.
YokoiHNagaiTIshidaTFujiiMIidaT (2003) Morpho-functional Machines: The New Species: Designing Embodied Intelligence. New York: Springer.
57.
ZhouQChangB (2006) Microhandling using robotic manipulation and capillary self-alignment. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 5883–5888.
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