The g-Extra Connectivity of the Strong Product of Paths and Cycles

Qinze, Zhu,; Tian, Yingzhi

doi:10.3390/sym14091900

Cited by 4 publications

(1 citation statement)

References 26 publications

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“…The strong products of two paths, the strong product of a path and a cycle, and the strong product of two cycles are all shown to have g-extra connectivity in article [10].…”

Section: Introductionmentioning

confidence: 98%

RETRACTED: On Cubic Roots Cordial Labeling for Some Graphs

et al. 2023

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In this paper we used the cubic roots of unit group together with the concept of cordiality in graph theory to introduce a new method of labeling, this construed cubic cordial labeling can be applied to all paths, cycles, fans and wheel graphs. Moreover, some other properties are investigated and show that the union of any two cycles and the union any two paths are cubic cordial graphs. Also, we study the cubic cordiality for the union of any cycle with a path.

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“…The strong products of two paths, the strong product of a path and a cycle, and the strong product of two cycles are all shown to have g-extra connectivity in article [10].…”

Section: Introductionmentioning

confidence: 98%

RETRACTED: On Cubic Roots Cordial Labeling for Some Graphs

et al. 2023

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Extra connectivity of networks modeled by the strong product graphs

Zhu,

Tian

2024

Applied Mathematics and Computation

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A Novel Radio Geometric Mean Algorithm for a Graph

2023

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Radio antennas switch signals in the form of radio waves using different frequency bands of the electromagnetic spectrum. To avoid interruption, each radio station is assigned a unique number. The channel assignment problem refers to this application. A radio geometric mean labeling of a connected graph G is an injective function h from the vertex set, V(G) to the set of natural numbers N such that for any two distinct vertices x and y of G, √ℎ(𝑥).ℎ(𝑦) ≥ diam + 1 − d(x,y). The radio geometric mean number of h,rgmn(h), is the maximum number assigned to any vertex of G. The radio geometric mean number of G, rgmn(G) is the minimum value of rgmn(h), taken over all radio geometric mean labeling h of G. In this paper, we present two theorems for calculating the exact radio geometric mean number of paths and cycles. We also present a novel algorithm for determining the upper bound for the radio geometric mean number of a given graph. We verify that the upper bounds obtained from this algorithm coincide with the exact value of the radio geometric mean number for paths, cycles, stars, and bi-stars.

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The g-Extra Connectivity of the Strong Product of Paths and Cycles

Cited by 4 publications

References 26 publications

RETRACTED: On Cubic Roots Cordial Labeling for Some Graphs

RETRACTED: On Cubic Roots Cordial Labeling for Some Graphs

Extra connectivity of networks modeled by the strong product graphs

A Novel Radio Geometric Mean Algorithm for a Graph

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