RAMSEY MINIMAL GRAPHS FOR PAIR OF CYCLE AND STAR GRAPHS
Frank Plumpton Ramsey introduced the Ramsey theory, which enables us to determine whether a logic formula is correct or incorrect (Ramsey, 1930). Then, this theory was developed and studied in various variants along with the generalization. One of the generalizations is the Ramsey minimal graph t...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/80737 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Frank Plumpton Ramsey introduced the Ramsey theory, which enables us to
determine whether a logic formula is correct or incorrect (Ramsey, 1930). Then, this
theory was developed and studied in various variants along with the generalization.
One of the generalizations is the Ramsey minimal graph that was introduced by
Burr et al. (1976).
Let G and H be any simple graphs. The notation F ! (G,H) implies that for
any red-blue coloring on the edges of F, there exists a red copy of a subgraph G
or a blue copy of a subgraph H. Then, for every edge e 2 E(F), the notation
F ? e 9 (G,H) implies that there is a red-blue coloring on the edges of F ? e
such that the graph F ?e contains no red copy of a subgraph G and no blue copy of
a subgraph H. A class R(G,H) is a set of graphs that fulfills these two following
conditions : (i) F ! (G,H) and (ii) for any e 2 F, F ? e 9 (G,H).
A pair of (G,H) is called finite Ramsey if the class R(G,H) has finite elements,
while a pair of (G,H)-minimal is called infinite Ramsey if the class R(G,H) has
infinite elements.
The research in this dissertation is a study of the infinite class R(G,H), where G
is a cycle and H is a star. The problem of characterizing and determining all of
the Ramsey (G,H)-minimal graphs for any G and H is not simple or easy work to
do, even for G and H that are in small-order and simple-structure graphs. But this
problem is still an interesting problem to study. Some Ramsey minimal graphs in
the classesR(C3,K1,2),R(C4,K1,2), orR(C6,K1,2) have been obtained. However,
in general, the characterization graphs in R(Cm,K1,n) for any m $ 3 and n $ 2
are still an open problem.
The results in this dissertation can be divided into two parts, namely the Ramsey
graph (Cm,K1,2)-minimal for m $ 7 and the Ramsey graph (C4,K1,n) for n $ 2.
In the first part, the results are the Ramsey graph (C2m,K1,2) for m $ 6, which
is constructed by modifying the Harary graph, and the Ramsey graph (Cm,K1,2)
which is obtained from a certain class of circulant graphs for m $ 7. For m 2
{8, 9, 10} and m = 4k + 3, with k a positive integer, it can be shown that the class
of circulant graphs is the Ramsey graph (Cm,K1,2)-minimum.
The main result in the second part is a method of Ramsey minimal graph
construction called the theta-F graph. The theta-F graph is constructed by
any edge-weighted graph F. We obtain the sufficient and necessary conditions
regarding the sum of the edge weights of F such that the theta-F graph is a Ramsey
graph (C4,K1,n)-minimal. In addition, we derive the properties of the distribution
of edge weights and vertex weights in the graph F. The vertex weight is the sum of
the edge weights incident to that vertex.
The construction method mentioned above is extended by incorporating subdivision
operations on F. By doing subdivision operations repeatedly, we obtain an infinite
class of theta-graphs in R(C4,K1,n) for n $ 2. Based on the conditions for vertex
and edge weights, several sequences of edge weights for tree and unicyclic graphs
are also given to obtain theta-trees and theta-unicyclic, which are members of the
class R(C4,K1,n). For an additional result, we give the construction of a new class
of graphs called H(n) graphs, which are (C4,K1,n)-minimal Ramsey graphs for
every n $ 3. |
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