5,102 research outputs found
Integer Flows and Circuit Covers of Graphs and Signed Graphs
The work in Chapter 2 is motivated by Tutte and Jaeger\u27s pioneering work on converting modulo flows into integer-valued flows for ordinary graphs. For a signed graphs (G, sigma), we first prove that for each k ∈ {lcub}2, 3{rcub}, if (G, sigma) is (k -- 1)-edge-connected and contains an even number of negative edges when k = 2, then every modulo k-flow of (G, sigma) can be converted into an integer-valued ( k + 1)-ow with a larger or the same support. We also prove that if (G, sigma) is odd-(2p+1)-edge-connected, then (G, sigma) admits a modulo circular (2 + 1/ p)-flows if and only if it admits an integer-valued circular (2 + 1/p)-flows, which improves all previous result by Xu and Zhang (DM2005), Schubert and Steffen (EJC2015), and Zhu (JCTB2015).;Shortest circuit cover conjecture is one of the major open problems in graph theory. It states that every bridgeless graph G contains a set of circuits F such that each edge is contained in at least one member of F and the length of F is at most 7/5∥E(G)∥. This concept was recently generalized to signed graphs by Macajova et al. (JGT2015). In Chapter 3, we improve their upper bound from 11∥E( G)∥ to 14/3 ∥E(G)∥, and if G is 2-edgeconnected and has even negativeness, then it can be further reduced to 11/3 ∥E(G)∥.;Tutte\u27s 3-flow conjecture has been studied by many graph theorists in the last several decades. As a new approach to this conjecture, DeVos and Thomassen considered the vectors as ow values and found that there is a close relation between vector S1-flows and integer 3-NZFs. Motivated by their observation, in Chapter 4, we prove that if a graph G admits a vector S1-flow with rank at most two, then G admits an integer 3-NZF.;The concept of even factors is highly related to the famous Four Color Theorem. We conclude this dissertation in Chapter 5 with an improvement of a recent result by Chen and Fan (JCTB2016) on the upperbound of even factors. We show that if a graph G contains an even factor, then it contains an even factor H with.;∥E(H)∥ ≥ 4/7 (∥ E(G)∥+1)+ 1/7 ∥V2 (G)∥, where V2( G) is the set of vertices of degree two
Packing odd -joins with at most two terminals
Take a graph , an edge subset , and a set of
terminals where is even. The triple is
called a signed graft. A -join is odd if it contains an odd number of edges
from . Let be the maximum number of edge-disjoint odd -joins.
A signature is a set of the form where and is even. Let be the minimum cardinality a -cut
or a signature can achieve. Then and we say that
packs if equality holds here.
We prove that packs if the signed graft is Eulerian and it
excludes two special non-packing minors. Our result confirms the Cycling
Conjecture for the class of clutters of odd -joins with at most two
terminals. Corollaries of this result include, the characterizations of weakly
and evenly bipartite graphs, packing two-commodity paths, packing -joins
with at most four terminals, and a new result on covering edges with cuts.Comment: extended abstract appeared in IPCO 2014 (under the different title
"the cycling property for the clutter of odd st-walks"
Signed circuit -covers of signed -minor-free graphs
Bermond, Jackson and Jaeger [{\em J. Combin. Theory Ser. B} 35 (1983):
297-308] proved that every bridgeless ordinary graph has a circuit
-cover and Fan [{\em J. Combin. Theory Ser. B} 54 (1992): 113-122] showed
that has a circuit -cover which together implies that has a circuit
-cover for every even integer . The only left case when is
the well-know circuit double cover conjecture. For signed circuit -cover of
signed graphs, it is known that for every integer , there are
infinitely many coverable signed graphs without signed circuit -cover and
there are signed eulerian graphs that admit nowhere-zero -flow but don't
admit a signed circuit -cover. Fan conjectured that every coverable signed
graph has a signed circuit -cover. This conjecture was verified only for
signed eulerian graphs and for signed graphs whose bridgeless-blocks are
eulerian. In this paper, we prove that this conjecture holds for signed
-minor-free graphs. The -cover is best possible for signed
-minor-free graphs
- …