Quantum-inspired cognitive agents

Huber-Liebl, Markus; Römer, Ronald; Wirsching, Günther; Schmitt, Ingo; Graben, Peter beim; Wolff, Matthias

doi:10.3389/fams.2022.909873

Cited by 4 publications

(2 citation statements)

References 63 publications

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“…The largest of these is quantum computing, where the underlying logic is featured in so-called quantum gates; see, for example, [4]. Other potential fields of applications have also been proposed, such as the evaluation of large datasets using contingency tables [5] or for quantum-inspired cognitive agents [6][7][8]. However, arguably because of the complex theoretical foundation of quantum logic and the peculiar settings described by it, until now, the range of applications has been limited.…”

Section: Introductionmentioning

confidence: 99%

A First Approach to Quantum Logical Shape Classification Framework

Köhler,

Kahra,

Breuß

2024

Mathematics

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Quantum logic is a well-structured theory, which has recently received some attention because of its fundamental relation to quantum computing. However, the complex foundation of quantum logic borrowing concepts from different branches of mathematics as well as its peculiar settings have made it a non-trivial task to devise suitable applications. This article aims to propose for the first time an approach using quantum logic in image processing for shape classification. We show how to make use of the principal component analysis to realize quantum logical propositions. In this way, we are able to assign a concrete meaning to the rather abstract quantum logical concepts, and we are able to compute a probability measure from the principal components. For shape classification, we consider encrypting given point clouds of different objects by making use of specific distance histograms. This enables us to initiate the principal component analysis. Through experiments, we explore the possibility of distinguishing between different geometrical objects and discuss the results in terms of quantum logical interpretation.

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Section: Introductionmentioning

confidence: 99%

A First Approach to Quantum Logical Shape Classification Framework

Köhler,

Kahra,

Breuß

2024

Mathematics

View full text Add to dashboard Cite

show abstract

“…The largest of these is quantum computing, where the underlying logic is featured in so-called quantum gates, see for example [4]. Other potential fields of applications have also been proposed, such as the evaluation of large datasets using contingency tables [5] or for quantum-inspired cognitive agents [6][7][8]. However, arguably because of the complex theoretical foundation of quantum logic and the peculiar settings described by it, up to now the range of applications has been limited.…”

Section: Introductionmentioning

confidence: 99%

A First Approach to Quantum Logical Shape Classification Framework

Köhler,

Kahra,

Breuß

2024

Preprint

View full text Add to dashboard Cite

Quantum logic is a well-structured theory, which has recently received some attention because of its fundamental relation to quantum computing. However, the complex foundation of quantum logic borrowing concepts from different branches of mathematics as well as its peculiar settings have made it a non-trivial task to device suitable applications. This article aims to propose for the first time an approach to use quantum logic in image processing at hand of a process for shape classification. We show how to make use of the principal component analysis to realize quantum logical propositions. In this way we are able to assign a concrete meaning to the rather abstract quantum logical concepts, and we are able to compute a probability measure from the principal components. For shape classification we consider encrypting given point clouds of different objects by making use of specific distance histograms. This enables to initiate the principal component analysis. At hand of experiments, we explore the possibility to distinguish between different geometrical objects and discuss the results in terms of quantum logical interpretation.

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Beyond neurons and spikes: cognon, the hierarchical dynamical unit of thought

2023

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From the dynamical point of view, most cognitive phenomena are hierarchical, transient and sequential. Such cognitive spatio-temporal processes can be represented by a set of sequential metastable dynamical states together with their associated transitions: The state is quasi-stationary close to one metastable state before a rapid transition to another state. Hence, we postulate that metastable states are the central players in cognitive information processing. Based on the analogy of quasiparticles as elementary units in physics, we introduce here the quantum of cognitive information dynamics, which we term “cognon”. A cognon, or dynamical unit of thought, is represented by a robust finite chain of metastable neural states. Cognons can be organized at multiple hierarchical levels and coordinate complex cognitive information representations. Since a cognon is an abstract conceptualization, we link this abstraction to brain sequential dynamics that can be measured using common modalities and argue that cognons and brain rhythms form binding spatiotemporal complexes to keep simultaneous dynamical information which relate the ‘what’, ‘where’ and ‘when’.

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Quantum-inspired cognitive agents

Cited by 4 publications

References 63 publications

A First Approach to Quantum Logical Shape Classification Framework

A First Approach to Quantum Logical Shape Classification Framework

A First Approach to Quantum Logical Shape Classification Framework

Beyond neurons and spikes: cognon, the hierarchical dynamical unit of thought

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