OTHERS_CITABLE
COMPUTING WIENER INDEX OF HAC5C7[p, q] NANOTUBES BY GAP PROGRAM
The Wiener index of a graph Gis defined as W(G) =1/2[Sum(d(i,j)] over all pair of elements of V(G), where V (G) is the set of vertices of G and d(i, j) is the distance between vertices i and j. In this paper, we give an algorithm by GAP program that can be compute the Wiener index for any graph also we compute the Wiener index of HAC5C7[p, q] and HAC5C6C7[p, q] nanotubes by this program.
http://ijmsi.ir/article-1-40-en.pdf
2015-10-26T10:20:15
1
12
10.7508/ijmsi.2008.01.001
Nanotube
Wiener Index
Adjacent Vertices.
A. Iranmanesh
1
AUTHOR
Y. Alizadeh
2
AUTHOR
OTHERS_CITABLE
Nonrigid Group Theory of Water Clusters ( Cyclic Forms): (H2O)i for 2<=i<=6
The character table of the fully nonrigid water cluster (cyclic forms), (H_{2}O){_i}, with C{_ih} symmetry derived for the first time, for 2<=i <=6. The group of all feasible permutations is the wreath product of groups S{_i}[S{_2}] which consists of i!2i operations for i = 2, ..., 6 divided into ( w.r.t) 5, 10, 20, 36, 65 conjugacy classes and 5, 10, 20, 36, 65 irreducible representations respectively. We compute the full character table of (H{_2}O){_2}, (H{_2}O){_3}, (H{_2}O){_4}, (H{_2}O){_5} and (H{_2}O){_6}.
http://ijmsi.ir/article-1-41-en.pdf
2015-10-26T10:20:15
13
30
10.7508/ijmsi.2008.01.002
Nonrigid Group Theory
Symmetry
Wreath Product
Conjugacy Classes
Character Table
Water Cluster.
M. Dabirian
1
AUTHOR
A. Iranmanesh
2
AUTHOR
OTHERS_CITABLE
Edge-Szeged and vertex-PIindices of Some Benzenoid Systems
The edge version of Szeged index and vertex version of PI index are defined very recently. They are similar to edge-PI and vertex-Szeged indices, respectively. The different versions of Szeged and PIindices are the most important topological indices defined in Chemistry. In this paper, we compute the edge-Szeged and vertex-PIindices of some important classes of benzenoid systems.
http://ijmsi.ir/article-1-42-en.pdf
2015-10-26T10:20:15
31
39
10.7508/ijmsi.2008.01.003
Edge and Vertex-Szeged indices
Edge and Vertex-PI indices
Benzenoid Systems.
Z. Bagheri
1
AUTHOR
A. Mahmiani
2
AUTHOR
O. Khormali
3
AUTHOR
OTHERS_CITABLE
The Merrifield-Simmons indices and Hosoya indices of some classes of cartesian graph product
The Merrifield-Simmons index of a graph is defined as the total number of the independent sets of the graph and the Hosoya index of a graph is defined as the total number of the matchings of the graph. In this paper, we give formula for Merrifield-Simmons and Hosoya indices of some classes of cartesian product of two graphs K{_2}×H, where H is a path graph P{_n}, cyclic graph C{_n}, or star graph S{_n}, with n vertices (These are called: ladder graph, prism graph, and book graph).
http://ijmsi.ir/article-1-43-en.pdf
2015-10-26T10:20:15
41
48
10.7508/ijmsi.2008.01.004
Merrifield-Simmons index
Hosoya index
Cartesian graph product
Ladder graph
Prism graph.
M. Sabzevari
1
AUTHOR
H. R. Maimani
2
AUTHOR
OTHERS_CITABLE
Vertex-PI Index of Some Nanotubes
The vertex version of PI index is a molecular structure descriptor which is similar to vertex version of Szeged index. In this paper, we compute the vertex-PI index of TUC4C8(S), TUC4C8(R) and HAC5C7[r, p].
http://ijmsi.ir/article-1-44-en.pdf
2015-10-26T10:20:15
49
62
10.7508/ijmsi.2008.01.005
Vertex-PI Index
Vertex-Szeged index
Molecular Graph
Nanotubes.
A. Sousaraei
1
AUTHOR
A. Mahmiani
2
AUTHOR
O. Khormali
3
AUTHOR
OTHERS_CITABLE
Some implementation aspects of the general linear methods withinherent Runge-Kutta stability
In this paper we try to put different practical aspects of the general linear methods discussed in the papers [1,6,7] under one algorithm to show more details of its implementation. With a proposed initial step size strategy this algorithm shows a better performance in some problems. To illustrate the efficiency of the method we consider some standard test problems and report more useful details of step size and order changes, and number of rejected and accepted steps along with relative global errors.
http://ijmsi.ir/article-1-45-en.pdf
2015-10-26T10:20:15
63
76
10.7508/ijmsi.2008.01.006
General linear methods
Variable step size
Inherent Runge-Kutta stability
Error estimation.
P. Mokhtary
1
AUTHOR
S. M. Hosseini
2
AUTHOR
OTHERS_CITABLE
A fuzzy production model with probabilistic resalable returns
In this paper, a fuzzy production inventory model with resalable returns has been analysed in an imprecise and uncertain environment by considering the cost and revenue parameters as trapezoidal fuzzy numbers. The main objective is to determine the optimal fuzzy production lotsize which maximizes the expected profit where the products leftout at the end of the period are salvaged and demands which are not met directly are lost. The modified graded mean integration epresentation method is used for defuzzification of fuzzy parameters of production lotsize and expected profit. An example is presented to illustrate the method applied in the model.
http://ijmsi.ir/article-1-46-en.pdf
2015-10-26T10:20:15
77
86
10.7508/ijmsi.2008.01.007
Fuzzy production model
Fuzzy random variable
Modified graded mean integration representation
Returned resalable products
Trapezoidal fuzzy numbers.
A.Nagoorgani
1
AUTHOR
P. Palaniammal
2
AUTHOR