Parallel Accelerated Virtual Physarum Lab Based on Cellular Automata Agents

Dourvas, Nikolaos I.; Sirakoulis, Georgios Ch.; Adamatzky, Andrew

doi:10.1109/access.2019.2927815

Cited by 7 publications

(3 citation statements)

References 54 publications

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“…In this work, we build on the simulation model of Jones (2010). While other computationally efficient VPM models have been proposed-for instance, those based on cellular automata (Dourvas et al, 2019;Kalogeiton et al, 1986) and formal logic rules (Schumann & Pancerz, 2016)we adopt this agent-based model due to its ability to construct precise trajectories. Jones's model is related to agent-based modeling of crowds and flocks (Olfati-Saber, 2006;Reynolds, 1987), but uses a continuous representation of the agents' density for navigation (Jones, 2010(Jones, , 2015b.…”

Section: Physarum Machines: Real and Virtualmentioning

confidence: 99%

Monte Carlo Physarum Machine: Characteristics of Pattern Formation in Continuous Stochastic Transport Networks

et al. 2022

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We present Monte Carlo Physarum Machine (MCPM): a computational model suitable for reconstructing continuous transport networks from sparse 2D and 3D data. MCPM is a probabilistic generalization of Jones's (2010) agent-based model for simulating the growth of Physarum polycephalum (slime mold). We compare MCPM to Jones's work on theoretical grounds, and describe a task-specific variant designed for reconstructing the large-scale distribution of gas and dark matter in the Universe known as the cosmic web. To analyze the new model, we first explore MCPM's self-patterning behavior, showing a wide range of continuous network-like morphologies—called polyphorms—that the model produces from geometrically intuitive parameters. Applying MCPM to both simulated and observational cosmological data sets, we then evaluate its ability to produce consistent 3D density maps of the cosmic web. Finally, we examine other possible tasks where MCPM could be useful, along with several examples of fitting to domain-specific data as proofs of concept.

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Section: Physarum Machines: Real and Virtualmentioning

confidence: 99%

Monte Carlo Physarum Machine: Characteristics of Pattern Formation in Continuous Stochastic Transport Networks

et al. 2022

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“…However, there are a range of works that utilize models of Physarum polycephalum to make sense of complex systems. Efficient virtual Physarum machines have been developed that utilize cellular automata [23,40] and formal logic [64], and an approach introduced by Jones [35] uses a large number of agents to generate emergent structures. This latter approach is similar in some ways to agent-based models that model crowds and flocks of birds [49,59], but differs in that it uses a continuous representation of the agents density for navigation [35,36].…”

Section: Related Workmentioning

confidence: 99%

Polyphorm: Structural Analysis of Cosmological Datasets via Interactive Physarum Polycephalum Visualization

Elek¹,

Burchett²,

Prochaska³

et al. 2020

Preprint

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Fig. 1. This figure depicts the use of the Polyphorm software tool for interactive visualization and data reconstruction during an analysis of the Bolshoi-Planck cosmological simulation dataset, which consists of approximately 840,000 simulated dark matter halos spanning a region of 170 Mpc in each dimension. Here, the entire volume is split into 4 equally sized vertical slabs, each showing a different view that enables the analysis of dark matter filaments: (a) raw data points (red) and agents (white) of our Monte Carlo Physarum Machine (MCPM) reconstruction algorithm, (b) volumetric footprint of the data ('deposit, white) and the reconstructed Cosmic Web filament density field ('trace, purple), (c) density field of the reconstruction mapped using a heatmap color palette, and (d) the same density field, but now segmented instead into three intervals using an alternative color map ('low in blue, 'medium in green, 'high in red). The filament reconstruction and interactive visualization facilitates new insights into into the structure and composition of the Cosmic Web.

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“…The state of each cell is a finite integer, which changes according to a rule that depends on the cell states in the neighborhood. There are many variations of CAs, depending on the dimension, state, and neighborhood, and they can also be applied to a wide variety of fields [4], [5], [14].…”

Section: Introductionmentioning

confidence: 99%

A New Structure of 2-State Number-Conserving Cellular Automata

Kong¹,

Imai²,

Nakanishi³

2021

IEICE Trans. Inf. & Syst.

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Two-state number-conserving cellular automaton (NCCA) is a cellular automaton of which cell states are 0 or 1, and the total sum of all the states of cells is kept for any time step. It is a kind of particle-based modeling of physical systems. We introduce a new structure of its value-1 patterns, which we call a "bundle pair" and a "bundle quad". By employing this structure, we show a relation between the neighborhood size n and n − 2 NCCAs.

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Parallel Accelerated Virtual Physarum Lab Based on Cellular Automata Agents

Cited by 7 publications

References 54 publications

Monte Carlo Physarum Machine: Characteristics of Pattern Formation in Continuous Stochastic Transport Networks

Monte Carlo Physarum Machine: Characteristics of Pattern Formation in Continuous Stochastic Transport Networks

Polyphorm: Structural Analysis of Cosmological Datasets via Interactive Physarum Polycephalum Visualization

A New Structure of 2-State Number-Conserving Cellular Automata

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