Abstract
Let \(G=(V_G, E_G)\) be a simple connected graph. The multiplicatively weighted Harary index of \(G\) is defined as \(H_M(G)=\sum _{\{u,v\}\subseteq V_G}\delta _G(u)\delta _G(v)\frac{1}{d_G(u,v)},\) where \(\delta _G(u)\) is the vertex degree of \(u\) and \(d_G(u,v)\) is the distance between \(u\) and \(v\) in \(G.\) This novel invariant is in fact the modification of the Harary index in which the contributions of vertex pairs are weighted by the product of their degrees. Deng et al. (J Comb Optim 2014, doi:10.1007/s10878-013-9698-5) determined the extremal values on \(H_M\) of graphs among \(n\)-vertex trees (resp. unicyclic graphs). In this paper, as a continuance of it, the monotonicity of \(H_M(G)\) under some graph transformations were studied. Using these nice mathematical properties, the extremal graphs among \(n\)-vertex trees with given graphic parameters, such as pendants, matching number, domination number, diameter, vertex bipartition, et al. are characterized, respectively. Some sharp upper bounds on the multiplicatively weighted Harary index of trees with given parameters are determined.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Alizadeh Y, Iranmanesha A, Došlić T (2013) Additively weighted Harary index of some composite graphs. Discret Math 313:26–34
Ashrafi AR, Saheli M, Ghorbani M (2011) The eccentric connectivity index of nanotubes and nanotori. J Comput Appl Math 235:4561–4566
Bollobás B, Tyomkyn M (2012) Walks and paths in trees. J Graph Theory 70:54–66
Bondy JA, Murty USR (2008) Graph theory. Graduate texts in mathematics, vol 244. Springer, New York
Deng HY, Krishnakumari B, Venkatakrishnan YB, Balachandran S (2014) Multiplicatively weighted Harary index of graphs. J Comb Optim doi:10.1007/s10878-013-9698-5
Dobrynin A, Entringer R, Gutman I (2001) Wiener index of trees: theory and applications. Acta Appl Math 66:211–249
Geng XY, Li SC, Zhang M (2013) Extremal values on the eccentric distance sum of trees. Discrete Appl Math 161:2427–2439
Haynes TW, Hedetniemi ST, Slater PJ (1998) Fundamentals of domination in graphs. Marcel Dekker Inc, New York
Hua HB, Zhang SG (2012) On the reciprocal degree distance of graphs. Discrete Appl Math 160(7–8):1152–1163
Ilić A (2010) Trees with minimal Laplacian coefficients. Comput Math Appl 59:2776–2783
Ivanciuc O, Balaban TS, Balaban AT (1993) Reciprocal distance matrix, related local vertex invariants and topological indices. J Math Chem 12:309–318
Kelmans AK (1976) Comparison of graphs by their number of spanning trees. Discrete Math 16:241–261
Li SC, Li Y, Zhang XX (2013) Edge-grafting theorems on permanents of the Laplacian matrices of graphs and their applications. Electron J Linear Algebra 26:28–48
Plavšsić D, Nikolić S, Trinajstić N, Mihalić Z (1993) On the Harary index for the characterization of chemical graphs. J Math Chem 12:235–250
Su GF, Gutman I, Xiong LM, Xu L Reciprocal product-degree distance of graphs, Filomat, to appear
Su GF, Xiong LM, Su XF, Chen XL (2013) Some results on the reciprocal sum-degree distance of graphs. J Comb Optim doi:10.1007/s10878-013-9645-5
Wiener H (1947) Structural determination of paraffin boiling point. J Am Chem Soc 69:17–20
Xu K (2012) Trees with the seven smallest and eight greatest Harary indices. Discrete Appl Math 160:321–331
Xu K, Liu M, Das KC, Gutman I, Furtula B (2014) A survey on graphs extremal with respect to distance-based topological indices. MATCH Commun Math Comput Chem 71:461–508
Zhang MJ, Li SC Results on reciprocal product-degree distance of bipartite graphs, preprint
Zhong L, Xu K (2014) Inequalities between vertex-degree-based topological indices. MATCH Commun Math Comput Chem 71:627–642
Acknowledgments
The authors would like to express their sincere gratitude to the referees for a very careful reading of this paper and for all their insightful comments, which lead a number of improvements to this paper. This work is financially supported by the National Natural Science Foundation of China (Grant Nos. 11271149, 11371062), the Program for New Century Excellent Talents in University (Grant No. NCET-13-0817) and the Special Fund for Basic Scientific Research of Central Colleges (Grant No. CCNU13F020).
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Li, S., Zhang, H. Some extremal properties of the multiplicatively weighted Harary index of a graph. J Comb Optim 31, 961–978 (2016). https://doi.org/10.1007/s10878-014-9802-5
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10878-014-9802-5