Towards Generalizing the Information Theory for Neural Communication

Végh, János; Berki, Ádám József

doi:10.3390/e24081086

Cited by 3 publications

(4 citation statements)

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“…The " neural dynamics " was studied and " spatiotemporal spreading of population activity was mapped " (Plenz and Aertsen 1996 ) by methods used to describe the static computing methods : interspike intervals histograms, auto-correlation and cross-correlation. Because of the peculiarities of this information handling, there are severe doubts whether the notions of the classic neural information theory are valid for biological computing systems (Végh and Berki 2022 ). The correct method of describing biological computation is still missing, given that the significant item of the computing is missed: the time and position are connected through the information transfer speed (called conduction velocity).…”

Section: Computing Paradigmsmentioning

confidence: 99%

“…Given that a physical carrier delivers the information (in all implementations, although the representation of the information is different (Végh and Berki 2022 )), the transfer time is crucial in all computing implementations. As the computing model requires, the operand must reach the operator unit’s input section, and for all physical carriers, the transfer speed is finite.…”

Section: The Effect Of the Finite Speed Of The Information Carriermentioning

confidence: 99%

“…We use " the broad definition of learning: use present information to adjust a circuit, to improve future performance " (Sterling and Laughlin 2017 ). However, the definition needs to explain also, what is the "present information" (or information at all (Végh and Berki 2022 )). Figure 4 shows how the model explains in what form the information is stored and adjusted in biological neurons.…”

Section: Time Information Storage and Learning In Biological Implemen...mentioning

confidence: 99%

“…The opposite claim is also valid: we cannot describe a neural network without accounting for the temporal behavior of its neurons. Végh and Berki ( 2022 ) provides a more detailed analysis.…”

Section: Time Information Storage and Learning In Biological Implemen...mentioning

confidence: 99%

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On the Role of Speed in Technological and Biological Information Transfer for Computations

Végh¹,

Berki

2022

Acta Biotheor

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In all kinds of implementations of computing, whether technological or biological, some material carrier for the information exists, so in real-world implementations, the propagation speed of information cannot exceed the speed of its carrier. Because of this limitation, one must also consider the transfer time between computing units for any implementation. We need a different mathematical method to consider this limitation: classic mathematics can only describe infinitely fast and small computing system implementations. The difference between mathematical handling methods leads to different descriptions of the computing features of the systems. The proposed handling also explains why biological implementations can have lifelong learning and technological ones cannot. Our conclusion about learning matches published experimental evidence, both in biological and technological computing.

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Section: Computing Paradigmsmentioning

confidence: 99%

Section: The Effect Of the Finite Speed Of The Information Carriermentioning

confidence: 99%

Section: Time Information Storage and Learning In Biological Implemen...mentioning

confidence: 99%

Section: Time Information Storage and Learning In Biological Implemen...mentioning

confidence: 99%

See 2 more Smart Citations

On the Role of Speed in Technological and Biological Information Transfer for Computations

Végh¹,

Berki

2022

Acta Biotheor

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Information Theory

Alcina,

Rios Guevara,

Gonzalez

et al. 2024

Encyclopedia of Religious Psychology and Behavior

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Revisiting neural information, computing and linking capacity

Végh¹,

Berki

2023

MBE

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<abstract><p>Neural information theory represents a fundamental method to model dynamic relations in biological systems. However, the notion of information, its representation, its content and how it is processed are the subject of fierce debates. Since the limiting capacity of neuronal links strongly depends on how neurons are hypothesized to work, their operating modes are revisited by analyzing the differences between the results of the communication models published during the past seven decades and those of the recently developed generalization of the classical information theory. It is pointed out that the operating mode of neurons is in resemblance with an appropriate combination of the formerly hypothesized analog and digital working modes; furthermore that not only the notion of neural information and its processing must be reinterpreted. Given that the transmission channel is passive in Shannon's model, the active role of the transfer channels (the axons) may introduce further transmission limits in addition to the limits concluded from the information theory. The time-aware operating model enables us to explain why (depending on the researcher's point of view) the operation can be considered either purely analog or purely digital.</p></abstract>

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Towards Generalizing the Information Theory for Neural Communication

Cited by 3 publications

References 53 publications

On the Role of Speed in Technological and Biological Information Transfer for Computations

On the Role of Speed in Technological and Biological Information Transfer for Computations

Information Theory

Revisiting neural information, computing and linking capacity

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