Modeling Self-Assembly Across Scales: The Unifying Perspective of Smart Minimal Particles

Mastrangeli, Massimo; Mermoud, Grégory; Martinoli, Alcherio

doi:10.3390/mi2020082

Cited by 13 publications

(16 citation statements)

References 108 publications

(123 reference statements)

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“…Severe restrictions on computation, sensing, actuation, and communication capabilities along with inherently highly noisy interactions are however unavoidable at small physical scales. These difficulties can be mitigated by deploying stochastic coordination approaches, allowing distributed robotic systems to deliver more reliable performances and to accomplish tasks beyond the capabilities of a single robot [1].…”

Section: Introductionmentioning

confidence: 99%

Lily: A miniature floating robotic platform for programmable stochastic self-assembly

Haghighat

Droz

Martinoli

2015

2015 IEEE International Conference on Robotics and Automation (ICRA)

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Abstract-Fluid-mediated programmable stochastic selfassembly offers promising means to formation of target structures capable of a variety of functionalities. While miniaturized building blocks allow for finer resolutions in such structures, as well as access to unconventional environments, they can only be endowed with very limited on-board resources. In this paper we present the design, fabrication, and experimental results validating the key functionalities of the Lily robot as the building block in a programmable stochastic fluidic self-assembly system, capable of forming 2D structures. In particular, we aim at driving a system including an arbitrary number of Lilies to form target structures through parallel selfassembly, using exclusively local information and communication. While capable of wireless communication to a base station, Lilies are endowed with custom-designed electropermanent magnets to latch and also to communicate locally with their neighbors. Several experiments validate the reliability of the radio channel as well as the robustness of the local inductionbased communication which allows for data transfer at 9600 bps with a success rate of 92.8% without repetition. The latches are shown to hold four times the weight of a single robot and to drag in another Lily from a distance of 4 mm in water.

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Section: Introductionmentioning

confidence: 99%

Lily: A miniature floating robotic platform for programmable stochastic self-assembly

Haghighat

Droz

Martinoli

2015

2015 IEEE International Conference on Robotics and Automation (ICRA)

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“…In SA information to build structures is mostly intrinsic, distributedly encoded in the properties of the agents and in their local interactions with other agents and with the environment. SA is a form of chemistry, and it can be effectively described and modeled using chemical analogies and formalisms [2], [3], [4]. Given proper boundary conditions, it can produce structures and patterns at all physical scales [1].…”

Section: Introductionmentioning

confidence: 99%

Automated real-time control of fluidic self-assembly of microparticles

Mastrangeli

Schill

Goldowsky

et al. 2014

2014 IEEE International Conference on Robotics and Automation (ICRA)

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Abstract-Self-assembly is a key coordination mechanism for large multi-unit systems and a powerful bottom-up technology for micro/nanofabrication. Controlled self-assembly and dynamic reconfiguration of large ensembles of microscopic particles can effectively bridge these domains to build innovative systems. In this perspective, we present SelfSys, a novel platform for the automated control of the fluidic selfassembly of microparticles. SelfSys centers around a waterfilled microfluidic chamber whose agitation modes, induced by a coupled ultrasonic actuator, drive the assembly. Microparticle dynamics is imaged, tracked and analyzed in real-time by an integrated software framework, which in turn algorithmically controls the agitation modes of the microchamber. The closed control loop is fully automated and can direct the stochastic assembly of microparticle clusters of preset dimension. Control issues specific to SelfSys implementation are discussed, and its potential applications presented. The SelfSys platform embodies at microscale the automated self-assembly control paradigm we first demonstrated in an earlier platform.

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“…Comparatively little effort has been devoted to modeling robotic SA [13]. Models with high level of abstraction are usually non-spatial and assume well-mixed systems; yet, Napp et al [14] have shown that, in their Programmable Parts setup, the robots are more likely to interact with their last interaction partner than with any other.…”

Section: Introductionmentioning

confidence: 99%

A trajectory-based calibration method for stochastic motion models

Mario

Mermoud

Mastrangeli

et al. 2011

2011 IEEE/RSJ International Conference on Intelligent Robots and Systems

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Abstract-In this paper, we present a quantitative, trajectory-based method for calibrating stochastic motion models of water-floating robots. Our calibration method is based on the Correlated Random Walk (CRW) model, and consists in minimizing the Kolmogorov-Smirnov (KS) distance between the step length and step angle distributions of real and simulated trajectories generated by the robots. First, we validate this method by calibrating a physics-based motion model of a single 3-cm-sized robot floating at a water/air interface under fluidic agitation. Second, we extend the focus of our work to multi-robot systems by performing a sensitivity analysis of our stochastic motion model in the context of SelfAssembly (SA). In particular, we compare in simulation the effect of perturbing the calibrated parameters on the predicted distributions of self-assembled structures. More generally, we show that the SA of water-floating robots is very sensitive to even small variations of the underlying physical parameters, thus requiring real-time tracking of its dynamics.

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Modeling Self-Assembly Across Scales: The Unifying Perspective of Smart Minimal Particles

Cited by 13 publications

References 108 publications

Lily: A miniature floating robotic platform for programmable stochastic self-assembly

Lily: A miniature floating robotic platform for programmable stochastic self-assembly

Automated real-time control of fluidic self-assembly of microparticles

A trajectory-based calibration method for stochastic motion models

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