Article A general-purpose organic gel computer that learns by itself

Pathik Sahoo ORCID (National Institute for Materials Science) ; Pushpendra Singh ORCID (National Institute for Materials Science) ; Komal Saxena (National Institute for Materials Science) ; Subrata Ghosh (National Institute for Materials Science) ; R P Singh ; Ryad Benosman ; Jonathan P Hill SAMURAI ORCID (National Institute for Materials Science) ; Tomonobu Nakayama SAMURAI ORCID (National Institute for Materials Science) ; Anirban Bandyopadhyay SAMURAI ORCID (National Institute for Materials Science)

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Pathik Sahoo, Pushpendra Singh, Komal Saxena, Subrata Ghosh, R P Singh, Ryad Benosman, Jonathan P Hill, Tomonobu Nakayama, Anirban Bandyopadhyay. A general-purpose organic gel computer that learns by itself. Neuromorphic Computing and Engineering. 2023, 3 (4), 044007. https://doi.org/10.1088/2634-4386/ad0fec
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(abstract)

To build energy minimized superstructures, self-assembling molecules explore astronomical options, colliding ∼109 molecules s−1. Thus far, no computer has used it fully to optimize choices and execute advanced computational theories only by synthesizing supramolecules. To realize it, first, we remotely re-wrote the problem in a language that supramolecular synthesis comprehends. Then, all-chemical neural network synthesizes one helical nanowire for one periodic event. These nanowires self-assemble into gel fibers mapping intricate relations between periodic events in any-data-type, the output is read instantly from optical hologram. Problem-wise, self-assembling layers or neural network depth is optimized to chemically simulate theories discovering invariants for learning. Subsequently, synthesis alone solves classification, feature learning problems instantly with single shot training. Reusable gel begins general-purpose computing that would chemically invent suitable models for problem-specific unsupervised learning. Irrespective of complexity, keeping fixed computing time and power, gel promises a toxic-hardware-free world.

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Keyword: organic computer, Optical vortex, Non-algorithmic computing, helical nanowire, Single shot learning, Deep learning network, Clique problem

Date published: 2023-12-01

Publisher: IOP Publishing

Journal:

  • Neuromorphic Computing and Engineering (ISSN: 26344386) vol. 3 issue. 4 044007

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Manuscript type: Publisher's version (Version of record)

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First published URL: https://doi.org/10.1088/2634-4386/ad0fec

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Updated at: 2024-11-13 16:30:37 +0900

Published on MDR: 2024-11-13 16:30:38 +0900

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