Miche: Modular Shape Formation by Self-Disassembly

Gilpin, Kyle; Kotay, Keith; Rus, Daniela; Vasilescu, Iuliu

doi:10.1177/0278364907085557

Cited by 137 publications

(95 citation statements)

References 16 publications

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“…In our system, generating a description of the goal shape is facilitated by a GUI that allows the user to virtually sculpt the desired shape and then generates a list of inclusion messages that are transmitted to the root and distributed. In [18] we show that this approach is efficient and correct. While the prior proof did not incorporate the concept of ignored modules, their effect is minimal, and we will not repeat the proof here.…”

Section: A Inclusion Message Distributionmentioning

confidence: 82%

“…A limited amount of past research has focused specifically on the algorithms employed in self-disassembling systems [16], [18], [19]. The work presented here builds on our previous work in [1], [20] on the Robot Pebbles hardware and algorithms.…”

Section: B Related Workmentioning

confidence: 99%

“…Once all modules know whether they are included in the final structure, disconnection commences and all unnecessary bonds between neighboring modules are broken in order to arrive at the desired set of goal shapes. For more information on this process, consult [18], [20] III. MULTIPLE SHAPES In this section we present an algorithm that controls and optimizes the formation of multiple shapes by sculpting an initial block of connected material.…”

Section: Experimental Context and Capabilitiesmentioning

confidence: 99%

“…MULTIPLE SHAPES In this section we present an algorithm that controls and optimizes the formation of multiple shapes by sculpting an initial block of connected material. While prior work [18] has shown that self-disassembly can form a particular shape from an initial block of material, the previous algorithm was only able to form a single shape during each iteration of the self-disassembly process, and the resulting shape had to include a unique root module. The new algorithm removes these restrictions.…”

Section: Experimental Context and Capabilitiesmentioning

confidence: 99%

See 3 more Smart Citations

Making self-disassembling objects with multiple components in the Robot Pebbles system

Gilpin¹,

Koyanagi

Rus³

2011

2011 IEEE International Conference on Robotics and Automation

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Abstract-This paper describes several novel algorithms for shape formation by subtraction in programmable matter systems. These algorithms allow the simultaneous formation of multiple different shapes from a single block of host material. The resulting shapes are allowed to intertwine in arbitrarily complex ways. We also present a proof that the algorithms operate correctly to form the desired shapes. Finally, we show experimental results from close to 100 trials using both the Robot Pebbles hardware and a unique software simulator. Multiple trials of several different experiments demonstrate the algorithms operating correctly.

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Section: A Inclusion Message Distributionmentioning

confidence: 82%

Section: B Related Workmentioning

confidence: 99%

Section: Experimental Context and Capabilitiesmentioning

confidence: 99%

Section: Experimental Context and Capabilitiesmentioning

confidence: 99%

See 2 more Smart Citations

Making self-disassembling objects with multiple components in the Robot Pebbles system

Gilpin¹,

Koyanagi

Rus³

2011

2011 IEEE International Conference on Robotics and Automation

Self Cite

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“…[2,3]), or by considering only quantized actions in quantized spaces (e.g. cellular automata such as [4] or [5], modular robotics such as [6] or [7], or parallel computing such as with StarLisp [8]). …”

Section: Discrete Devices Versus Continuous Space-timementioning

confidence: 99%

Space–time programming

Beal

Viroli

2015

Phil. Trans. R. Soc. A.

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Computation increasingly takes place not on an individual device, but distributed throughout a material or environment, whether it be a silicon surface, a network of wireless devices, a collection of biological cells or a programmable material. Emerging programming models embrace this reality and provide abstractions inspired by physics, such as computational fields, that allow such systems to be programmed holistically, rather than in terms of individual devices. This paper aims to provide a unified approach for the investigation and engineering of computations programmed with the aid of space-time abstractions, by bringing together a number of recent results, as well as to identify critical open problems.

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Multistable Shape‐Reconfigurable Architected Materials

et al. 2016

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Multistable shape-reconfigurable architected materials encompassing living hinges and enabling combinations of high strength, high volumetric change, and complex shape-morphing patterns are introduced. Analytical and numerical investigations, validated by experiments, are performed to characterize the mechanical behavior of the proposed materials. The proposed architected materials can be constructed from virtually any base material, at any length scale and dimensionality.

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Miche: Modular Shape Formation by Self-Disassembly

Cited by 137 publications

References 16 publications

Making self-disassembling objects with multiple components in the Robot Pebbles system

Making self-disassembling objects with multiple components in the Robot Pebbles system

Space–time programming

Multistable Shape‐Reconfigurable Architected Materials

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