On the Degree-Based Topological Indices of the Tickysim SpiNNaker Model

Imran, Muhammad; Siddiqui, Muhammad Kamran; Ahmad, Ali; Ali, Usman; Hanif, Nazia

doi:10.3390/axioms7040073

Cited by 5 publications

(3 citation statements)

References 28 publications

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“…Nevertheless, in cut down poor countries and locales (for instance, certain urban networks and countries in South America, Southeast Asia, Africa, and India), there is no sufficient money to settle reagents and apparatus which can be used to gauge the biochemical properties. For topological study of dendrimers, we refer [53][54][55][56][57][58][59][60][61][62][63][64][65][66]. 7.…”

Section: Gourava Indices For Dendrimersmentioning

confidence: 99%

Valency-Based Descriptors for Silicon Carbides, Bismuth(III) Iodide, and Dendrimers in Drug Applications

Virk

Nazar

et al. 2020

Journal of Chemistry

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Silicon carbide (SiC), also called carborundum, is a semiconductor containing silicon and carbon. Dendrimers are repetitively branched molecules that are typically symmetric around the core and often adopt a spherical three-dimensional morphology. Bismuth(III) iodide is an inorganic compound with the formula BiI3. This gray-black solid is the product of the reaction between bismuth and iodine, which once was of interest in qualitative inorganic analysis. In chemical graph theory, we associate a graph to a compound and compute topological indices that help us in guessing properties of the understudy compound. A topological index is the graph invariant number, calculated from a graph representing a molecule. Most of the proposed topological indices are related either to a vertex adjacency relationship (atom-atom connectivity) in the graph or to topological distances in the graph. In this paper, we aim to compute the first and second Gourava indices and hyper-Gourava indices for silicon carbides, bismuth(III) iodide, and dendrimers.

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Section: Gourava Indices For Dendrimersmentioning

confidence: 99%

Valency-Based Descriptors for Silicon Carbides, Bismuth(III) Iodide, and Dendrimers in Drug Applications

Virk

Nazar

et al. 2020

Journal of Chemistry

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“…[16] and further extended to general n-vertex tree in [17]. The authors in Ref [2][3] determined some degree base topological indices for diamond like networks and Tickysim SpiNNaker model sheet.…”

Section: ■ Introductionmentioning

confidence: 99%

Leap Zagreb Connection Numbers for Some Networks Models

Raza

2020

Indones. J. Chem.

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The main object of this study is to determine the exact values of the topological indices which play a vital role in studying chemical information, structure properties like QSAR and QSPR. The first Zagreb index and second Zagreb index are among the most studied topological indices. We now consider analogous graph invariants, based on the second degrees of vertices, called leap Zagreb indices. We compute these indices for Tickysim SpiNNaker model, cyclic octahedral structure, Aztec diamond and extended Aztec diamond.

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“…This computing gives information about the underlying topology of neural networks. Among these computations, the computation of classical degree-based topological properties of the Tickysim spiking neural network has newly been investigated in [10]. In this study, we investigate the ev-degree and ve-degree topological properties of the Tickysim spiking neural network as a continuation of the study [10].…”

Section: Introductionmentioning

confidence: 99%

On Ev-Degree and Ve-Degree Topological Properties of Tickysim Spiking Neural Network

Cancan

2019

Computational Intelligence and Neuroscience

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Topological indices are indispensable tools for analyzing networks to understand the underlying topology of these networks. Spiking neural network architecture (SpiNNaker or TSNN) is a million-core calculating engine which aims at simulating the behavior of aggregates of up to a billion neurons in real time. Tickysim is a timing-based simulator of the interchip interconnection network of the SpiNNaker architecture. Tickysim spiking neural network is considered to be highly symmetrical network classes. Classical degree-based topological properties of Tickysim spiking neural network have been recently determined. Ev-degree and ve-degree concepts are two novel degrees recently defined in graph theory. Ev-degree and ve-degree topological indices have been defined as parallel to their corresponding counterparts. In this study, we investigate the ev-degree and ve-degree topological properties of Tickysim spiking neural network. These calculations give the information about the underlying topology of Tickysim spiking neural network.

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On the Degree-Based Topological Indices of the Tickysim SpiNNaker Model

Cited by 5 publications

References 28 publications

Valency-Based Descriptors for Silicon Carbides, Bismuth(III) Iodide, and Dendrimers in Drug Applications

Valency-Based Descriptors for Silicon Carbides, Bismuth(III) Iodide, and Dendrimers in Drug Applications

Leap Zagreb Connection Numbers for Some Networks Models

On Ev-Degree and Ve-Degree Topological Properties of Tickysim Spiking Neural Network

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