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Published online:
8 Dec 2023
Accepted:
23 Nov 2023
Received:
2 Oct 2023
Open Access
Brief Report
Intentionality for better communication in minimally conscious AI design
R.R. Poznanski, L.A. Cacha, V. Sbitnev, N. Iannella, S. Parida, E.J. Brändas and J.Z Achimowicz
Author Affiliations
R.R. Poznanski: Integrative Neuroscience Initiative, Melbourne, Victoria, Australia 3145.
L.A. Cacha: Integrative Neuroscience Initiative, Melbourne, Victoria, Australia 3145.
V. Sbitnev: Petersburg B.P. Konstantinov Nuclear Physics Institute, Gatchina, Russian Federation. & Department of Electrical Engineering and Computer Science, University of California, Berkeley, USA.
N. Iannella: The Faculty of Mathematics and Natural Sciences, University of Oslo, Oslo 0316 Norway.
S. Parida: Silo AI, Lapinlahdenkatu 1C, 00180 Helsinki, Finland.
E.J. Brändas: Department of Chemistry, Uppsala University, 751 21 Uppsala, Sweden.
J.Z Achimowicz: Warsaw Medical Academy, Faculty of Medicine, 01-043 Warsaw, Poland
Abstract
Consciousness is the ability to have intentionality, which is a process that operates at various temporal scales. To qualify as conscious, an artificial device must express functionality capable of solving the Intrinsicality problem, where experienceable form or syntax gives rise to understanding 'meaning' as a noncontextual dynamic prior to language. This is suggestive of replacing the Hard Problem of consciousness to build conscious artificial intelligence (AI). Developing model emulations and exploring fundamental mechanisms of how machines understand meaning is central to the development of minimally conscious AI. It has been shown by Alemdar and colleagues [New insights into holonomic brain theory: implications for active consciousness. Journal of Multiscale Neuroscience 2(2023), 159-168] that a framework for advancing artificial systems through understanding uncertainty derived from negentropic action to create intentional systems entails quantum-thermal fluctuations through informational channels instead of recognizing (cf., introspection) sensory cues through perceptual channels. Improving communication in conscious AI requires both software and hardware implementation. The software can be developed through the brain-machine interface of multiscale temporal processing, while hardware implementation can be done by creating energy flow using dipole-like hydrogen ion (proton) interactions in an artificial 'wetwire' protonic filament. Machine understanding can be achieved through memristors implemented in the protonic 'wetwire' filament embedded in a real-world device. This report presents a blueprint for the process, but it does not cover the algorithms or engineering aspects, which need to be conceptualized before minimally conscious AI can become operational.
Keywords
Dodecanogram-based brain-machine interface; minimally conscious AI; intentionality; machine understanding; artificial experientiality; protonic 'wetware'; memristors; hydrodynamic pairs; dipole-like protonic resonance; energy flow; fluctuations.
How to cite this article
R.R. Poznanski, L.A. Cacha, V. Sbitnev, N. Iannella, S. Parida, E.J. Brändas & J.Z Achimowicz (2024). Intentionality for better communication in minimally conscious AI design. Journal of Multiscale Neuroscience 3(1), 1-12.
Conflict of Interest
The authors declare no conflict of interest.
Copyright
© 2024 The Author(s). Published by Neural Press.
This is an open access article distributed under the terms and conditions of the CC BY 4.0 license.
Disclaimer
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, Neural Press or the editors, and the reviewers. Any product that may be evaluated in this article, or claim that made by its manufacturer, is not guaranteed or endorsed by the publisher.
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This article belongs to the Special IssueThis article belongs to the Special Issue
Multiscalar brain adaptability in AI Systems
Lead Editor: Dr. Shantipriya Parida
Senior Scientist
Silo AI, Helsinki, Finland
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