JAEM 2017, Vol 7, No 1JAEM 2017, Vol 7, No 1 koleksiyonunu içerir.http://belgelik.isikun.edu.tr/xmlui/handleiubelgelik/24002026-04-09T08:41:50Z2026-04-09T08:41:50ZExtremum seeking control of uncertain systemsDinçmen, Erkinhttp://belgelik.isikun.edu.tr/xmlui/handleiubelgelik/60402024-07-17T14:43:33Z2017-01-01T00:00:00ZExtremum seeking control of uncertain systems
Dinçmen, Erkin
Extremum seeking is used in control problems where the reference trajectory or reference set point of the system is not known but it is searched in real time in order to maximize or minimize a performance function representing the optimal behaviour of the system. In this paper, extremum seeking algorithm is applied to the systems with parametric uncertainties.
2017-01-01T00:00:00ZA note on line graphsSatyanarayana, BhavanariSrinivasulu, DevanaboinaSyam Prasad, Kunchamhttp://belgelik.isikun.edu.tr/xmlui/handleiubelgelik/26212024-05-07T21:37:05Z2017-02-20T00:00:00ZA note on line graphs
Satyanarayana, Bhavanari; Srinivasulu, Devanaboina; Syam Prasad, Kuncham
The line graph and 1-quasitotal graph are well-known concepts in graph theory. In Satyanarayana, Srinivasulu, and Syam Prasad [13], it is proved that if a graph G consists of exactly m connected components Gi (1 ? i ? m) then L(G) = L(G1) = L(G2) ? ... ? L(Gm) where L(G) denotes the line graph of G, and ? denotes the ring sum operation on graphs. In [13], the authors also introduced the concept 1- quasitotal graph and obtained that Q1(G) = G?L(G) where Q1(G) denotes 1-quasitotal graph of a given graph G. In this note, we consider zero divisor graph of a finite associate ring R and we will prove that the line graph of Kn?1 contains the complete graph on n vertices where n is the number of elements in the ring R.
2017-02-20T00:00:00ZNumerical solution of a 2D- diffusion reaction problem modelling the density of di-vacancies and vacancies in a metalPamuk, Serdalhttp://belgelik.isikun.edu.tr/xmlui/handleiubelgelik/26202024-05-07T21:37:04Z2017-01-03T00:00:00ZNumerical solution of a 2D- diffusion reaction problem modelling the density of di-vacancies and vacancies in a metal
Pamuk, Serdal
A decomposition solution of a diffusion reaction problem, which models the density of di-vacancies and vacancies in a metal is presented. The results are compared with the numerical solutions. Zero - diffusion solutions are obtained numerically and some figures are illustrated.
2017-01-03T00:00:00ZPartitioning a graph into monopoly setsNaji, Ahmed MohammedNandappa D., Sonerhttp://belgelik.isikun.edu.tr/xmlui/handleiubelgelik/26192024-05-07T21:36:58Z2017-01-01T00:00:00ZPartitioning a graph into monopoly sets
Naji, Ahmed Mohammed; Nandappa D., Soner
In a graph G = (V, E), a set M ? V (G) is said to be a monopoly set of G if every vertex v ? V ? M has, at least, d(v)/2 neighbors in M. The monopoly size of G, denoted by mo(G), is the minimum cardinality of a monopoly set. In this paper, we study the problem of partitioning V (G) into monopoly sets. An M-partition of a graph G is the partition of V (G) into k disjoint monopoly sets. The monatic number of G, denoted by µ(G), is the maximum number of sets in M-partition of G. It is shown that 2 ? µ(G) ? 3 for every graph G without isolated vertices. The properties of each monopoly partite set of G are presented. Moreover, the properties of all graphs G having µ(G) = 3, are presented. It is shown that every graph G having µ(G) = 3 is Eulerian and have ?(G) ? 3. Finally, it is shown that for every integer k /? {1, 2, 4}, there exists a graph G of order n = k having µ(G) = 3.
2017-01-01T00:00:00Z