Thermodynamic Analysis of Time Evolving Networks

Cheng, Ya; Wilson, Richard C.; Rossi, Luca; Torsello, Andrea; Hancock, Edwin R.

doi:10.3390/e20100759

Cited by 9 publications

(14 citation statements)

References 42 publications

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“…It could also be, as an alternative option, the probability of microstates–microstates in this case defined as aforesaid, combinations of pairwise connected networks—which, in the end, conceptually is the same as the previous notion: a probability of connection because microstates arise from connections. It is of interest that, recently, the thermodynamic entropy of a network (here networks defined as in graph theory) has been described using the Shannon formula dependent on the probabilities of the microstates (Ye et al, 2018).…”

Section: Probabilistic Description Of Brain Dynamicsmentioning

confidence: 99%

On a Simple General Principle of Brain Organization

2019

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A possible framework to characterize nervous system dynamics and its organization in conscious and unconscious states is introduced, derived from a high level perspective on the coordinated activity of brain cell ensembles. Some questions are best addressable in a global framework and here we build on past observations about the structure of configurations of brain networks in conscious and unconscious states and about neurophysiological results. Aiming to bind some results together into some sort of coherence with a central theme, the scenario that emerges underscores the crucial importance of the creation and dissipation of energy gradients in brain cellular ensembles resulting in maximization of the configurations in the functional connectivity among those networks that favor conscious awareness and healthy conditions. These considerations are then applied to indicate approaches that can be used to improve neuropathological syndromes.

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Section: Probabilistic Description Of Brain Dynamicsmentioning

confidence: 99%

On a Simple General Principle of Brain Organization

2019

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“…Recently, more literature has succeeded in characterizing natural networks [22], neuron networks [23] and biological networks [24] through thermodynamic approaches. In particular, thermodynamic temperature is able to capture critical events in evolving networks [25]. These prior works inspired us in that heat corresponds with popularity and moreover, temperature quantifies partly our body feelings of weather.…”

Section: Textmentioning

confidence: 99%

“…Inspired by the temperature design in prior work [25,27], we computed T t structure by making an analogy between G t 's evolution between two adjacent timestamps and an isochoric state of change of a general thermodynamic system. We defined the system's volume to be G t 's node number.…”

Section: Plos Onementioning

confidence: 99%

Can we ‘feel’ the temperature of knowledge? Modelling scientific popularity dynamics via thermodynamics

et al. 2021

PLoS ONE

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Just like everything in nature, scientific topics flourish and perish. While existing literature well captures article’s life-cycle via citation patterns, little is known about how scientific popularity and impact evolves for a specific topic. It would be most intuitive if we could ‘feel’ topic’s activity just as we perceive the weather by temperature. Here, we conceive knowledge temperature to quantify topic overall popularity and impact through citation network dynamics. Knowledge temperature includes 2 parts. One part depicts lasting impact by assessing knowledge accumulation with an analogy between topic evolution and isobaric expansion. The other part gauges temporal changes in knowledge structure, an embodiment of short-term popularity, through the rate of entropy change with internal energy, 2 thermodynamic variables approximated via node degree and edge number. Our analysis of representative topics with size ranging from 1000 to over 30000 articles reveals that the key to flourishing is topics’ ability in accumulating useful information for future knowledge generation. Topics particularly experience temperature surges when their knowledge structure is altered by influential articles. The spike is especially obvious when there appears a single non-trivial novel research focus or merging in topic structure. Overall, knowledge temperature manifests topics’ distinct evolutionary cycles.

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“…It could also be, as an alternative option, the probability of microstatesmicrostates in this case defined as aforesaid, combinations of pairwise connected networks -which, in the end, conceptually is the same as the previous notion: a probability of connection because microstates arise from connections. It is of interest that, recently, the thermodynamic entropy of a network (here networks defined as in graph theory) has been described using the Shannon formula dependent on the probabilities of the microstates [71].…”

Section: Neurophysiological Importance Of Dissipationmentioning

confidence: 99%

On a simple general principle of brain organization

Velázquez

Mateos

Erra

2019

Preprint

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A possible framework to characterise nervous system dynamics and its organization in conscious and unconscious states is introduced, derived from a high level perspective on the coordinated activity of brain cell ensembles. Some questions are best addressable in a global framework and here we build on past observations about the structure of configurations of brain networks in conscious and unconscious states and about neurophysiological results. Aiming to bind some results together into some sort of coherence with a central theme, the scenario that emerges underscores the crucial importance of the creation and dissipation of energy gradients in brain cellular ensembles resulting in maximisation of the configurations in the functional connectivity among those networks that favour conscious awareness and healthy conditions. These considerations are then applied to indicate approaches that can be used to improve neuropathological syndromes.

show abstract

Thermodynamic Analysis of Time Evolving Networks

Cited by 9 publications

References 42 publications

On a Simple General Principle of Brain Organization

On a Simple General Principle of Brain Organization

Can we ‘feel’ the temperature of knowledge? Modelling scientific popularity dynamics via thermodynamics

On a simple general principle of brain organization

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