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Not-All-Equal and 1-in-Degree Decompositions: Algorithmic Complexity and Applications
A Not-All-Equal (NAE) decomposition of a graph \(G\) is a decomposition of the vertices of \(G\) into two parts such that each vertex in \(G\) has at least one neighbor in each part. Also, a 1-in-Degree decomposition of a graph \(G\) is a decomposition of the vertices of \(G\) into two parts \(A\) a...
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| creator | Dehghan, Ali Mohammad-Reza, Sadeghi Ahadi, Arash |
| description | A Not-All-Equal (NAE) decomposition of a graph \(G\) is a decomposition of the vertices of \(G\) into two parts such that each vertex in \(G\) has at least one neighbor in each part. Also, a 1-in-Degree decomposition of a graph \(G\) is a decomposition of the vertices of \(G\) into two parts \(A\) and \(B\) such that each vertex in the graph \(G\) has exactly one neighbor in part \(A\). Among our results, we show that for a given graph \(G\), if \(G\) does not have any cycle of length congruent to 2 mod 4, then there is a polynomial time algorithm to decide whether \(G\) has a 1-in-Degree decomposition. In sharp contrast, we prove that for every \(r\), \(r\geq 3\), for a given \(r\)-regular bipartite graph \(G\) determining whether \(G\) has a 1-in-Degree decomposition is \( \mathbf{NP} \)-complete. These complexity results have been especially useful in proving \( \mathbf{NP} \)-completeness of various graph related problems for restricted classes of graphs. In consequence of these results we show that for a given bipartite 3-regular graph \(G\) determining whether there is a vector in the null-space of the 0,1-adjacency matrix of \(G\) such that its entries belong to \(\{\pm 1,\pm 2\}\) is \(\mathbf{NP} \)-complete. Among other results, we introduce a new version of {Planar 1-in-3 SAT} and we prove that this version is also \( \mathbf{NP} \)-complete. In consequence of this result, we show that for a given planar \((3,4)\)-semiregular graph \(G\) determining whether there is a vector in the null-space of the 0,1-incidence matrix of \(G\) such that its entries belong to \(\{\pm 1,\pm 2\}\) is \(\mathbf{NP} \)-complete. |
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Also, a 1-in-Degree decomposition of a graph \(G\) is a decomposition of the vertices of \(G\) into two parts \(A\) and \(B\) such that each vertex in the graph \(G\) has exactly one neighbor in part \(A\). Among our results, we show that for a given graph \(G\), if \(G\) does not have any cycle of length congruent to 2 mod 4, then there is a polynomial time algorithm to decide whether \(G\) has a 1-in-Degree decomposition. In sharp contrast, we prove that for every \(r\), \(r\geq 3\), for a given \(r\)-regular bipartite graph \(G\) determining whether \(G\) has a 1-in-Degree decomposition is \( \mathbf{NP} \)-complete. These complexity results have been especially useful in proving \( \mathbf{NP} \)-completeness of various graph related problems for restricted classes of graphs. In consequence of these results we show that for a given bipartite 3-regular graph \(G\) determining whether there is a vector in the null-space of the 0,1-adjacency matrix of \(G\) such that its entries belong to \(\{\pm 1,\pm 2\}\) is \(\mathbf{NP} \)-complete. Among other results, we introduce a new version of {Planar 1-in-3 SAT} and we prove that this version is also \( \mathbf{NP} \)-complete. In consequence of this result, we show that for a given planar \((3,4)\)-semiregular graph \(G\) determining whether there is a vector in the null-space of the 0,1-incidence matrix of \(G\) such that its entries belong to \(\{\pm 1,\pm 2\}\) is \(\mathbf{NP} \)-complete.</description><identifier>EISSN: 2331-8422</identifier><language>eng</language><publisher>Ithaca: Cornell University Library, arXiv.org</publisher><subject>Algorithms ; Apexes ; Complexity ; Decomposition ; Graph theory ; Mathematical analysis ; Matrix methods ; Polynomials</subject><ispartof>arXiv.org, 2018-01</ispartof><rights>2018. This work is published under http://arxiv.org/licenses/nonexclusive-distrib/1.0/ (the “License”). 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In consequence of these results we show that for a given bipartite 3-regular graph \(G\) determining whether there is a vector in the null-space of the 0,1-adjacency matrix of \(G\) such that its entries belong to \(\{\pm 1,\pm 2\}\) is \(\mathbf{NP} \)-complete. Among other results, we introduce a new version of {Planar 1-in-3 SAT} and we prove that this version is also \( \mathbf{NP} \)-complete. 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| subjects | Algorithms Apexes Complexity Decomposition Graph theory Mathematical analysis Matrix methods Polynomials |
| title | Not-All-Equal and 1-in-Degree Decompositions: Algorithmic Complexity and Applications |
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