Particle computation: complexity, algorithms, and logic

Becker, Aaron T.; Demaine, Erik D.; Fekete, Sándor P.; Lonsford, Jarrett; Morris-Wright, Rose

doi:10.1007/s11047-017-9666-6

Cited by 22 publications

(24 citation statements)

References 66 publications

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“…This section is a continuation of the work done by [5][6][7]. In their papers, they discuss the occupancy problem in a tilt-based system which asks whether a given location can be occupied by any tile on the board.…”

Section: Pspace-complete Resultsmentioning

confidence: 99%

“…Our proofs rely on a reduction from a 2-tunnel gadget network game with different gadget types that was recently proven to be PSPACE-complete by Demaine, Grosof, Lynch, and Rudoy [11]. Previous work on occupancy has shown the problem to be NP-hard [6] even when restricted to 1 × 1 pieces that do not stick. A closely related problem of computing the minimum number of tilts needed to reconfigure between two board configurations has been shown to PSPACE-complete for 1 × 1 non-sticking pieces [6].…”

Section: Our Contributions In Detailmentioning

confidence: 99%

“…Previous work on occupancy has shown the problem to be NP-hard [6] even when restricted to 1 × 1 pieces that do not stick. A closely related problem of computing the minimum number of tilts needed to reconfigure between two board configurations has been shown to PSPACE-complete for 1 × 1 non-sticking pieces [6]. A summary of our complexity results, along with closely related prior work, is provided in Table 2.…”

Section: Our Contributions In Detailmentioning

confidence: 99%

“…The occupancy problem was shown to be NP-Hard by [5][6][7] when only using 1 × 1 tiles. Their reduction also works to show NP-hardness for the relocation problem when only using 1 × 1 tiles.…”

Section: Problems In the Tilt Modelmentioning

confidence: 99%

“…A related problem, which asks if a given location can be occupied by any polyomino, has also been considered. This problem was shown to be NP-hard [6] in the restricted case of 1 × 1 polyominoes that never stick together (but is not known to be in NP). We also extend this line of work by showing this problem is PSPACE-Complete if polyominoes larger than than 1 × 1 tiles are allowed.…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Full Tilt: Universal Constructors for General Shapes with Uniform External Forces

Balanza-Martinez¹,

Caballero²,

Cantu³

et al. 2019

Proceedings of the Thirtieth Annual ACM-SIAM Symposium on Discrete Algorithms

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We investigate the problem of assembling general shapes and patterns in a model in which particles move based on uniform external forces until they encounter an obstacle. In this model, corresponding particles may bond when adjacent with one another. Succinctly, this model considers a 2D grid of "open" and "blocked" spaces, along with a set of slidable polyominoes placed at open locations on the board. The board may be tilted in any of the 4 cardinal directions, causing all slidable polyominoes to move maximally in the specified direction until blocked. By successively applying a sequence of such tilts, along with allowing different polyominoes to stick when adjacent, tilt sequences provide a method to reconfigure an initial board configuration so as to assemble a collection of previous separate polyominoes into a larger shape.While previous work within this model of assembly has focused on designing a specific board configuration for the assembly of a specific given shape, we propose the problem of designing universal configurations that are capable of constructing a large class of shapes and patterns. For these constructions, we present the notions of weak and strong universality which indicate the presence of "excess" polyominoes after the shape is constructed. In particular, for given integers h, w, we show that there exists a strongly universal configuration with O(hw) 1 × 1 slidable particles that can be reconfigured to build any h × w patterned rectangle. We then expand this result to show that there exists a weakly universal configuration that can build any h × w-bounded size connected shape. Following these results, which require an admittedly relaxed assembly definition, we go on to show the existence of a strongly universal configuration (no excess particles) which can assemble any shape within a previously studied "drop" class, while using quadratically less space than previous results.Finally, we include a study of the complexity of motion planning in this model. We consider the problems of deciding if a board location can be occupied by any particle (occupancy problem), deciding if a specific particle may be relocated to another position (relocation problem), and deciding if a given configuration of particles may be transformed into a second given configuration (reconfiguration problem). We show all of these problems to be PSPACE-complete with the allowance of a single 2 × 2 polyomino in addition to 1 × 1 tiles. We further show that relocation and occupancy remain PSPACE-complete even when the board geometry is a simple rectangle if domino polyominos are included.

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Section: Pspace-complete Resultsmentioning

confidence: 99%

Section: Our Contributions In Detailmentioning

confidence: 99%