Inferring a Tree from Lowest Common Ancestors with an Application to the Optimization of Relational Expressions

Abstract: We present an algorithm for constructing a tree to satisfy a set of lineage constraints on common ancestors. We then apply this algorithm to synthesize a relational algebra expression from a simple tableau, a problem arising in the theory of relational databases.

“…We end this section by giving a short description of the Build algorithm [1,23], which decides if there exists a rooted tree (i.e. a network without reticulations) displaying a given set of triplets L. The Build algorithm constructs a graph R L (L) with a vertex for each taxon and an edge {x, y} precisely if there exists a triplet…”

“…The first step of the algorithm is to construct the graph R b (B) 1 , which has a vertex for each taxon and an edge {x, y} if (at least) one of N (x; y) and N (y; x) is contained in B. The algorithm searches for a nonempty strict subset U of the vertices of Ω b (B) such that there is no arc (π 1 , π 2 ) with π 1 / ∈ U and π 2 ∈ U .…”

“…4, we present an exponential-time algorithm for an arbitrary set consisting of binets and trinets (see Theorem 2). This algorithm uses a top-down approach that is somewhat similar in nature to the Build algorithm [1,23] but it is considerably more intricate. The algorithm can be generalised to instances containing level-1 networks with arbitrarily many leaves since trinets encode level-1 networks [11].…”

“…We consider binets as well as trinets since they can provide important information to help piece together sets of trinets. Our approach can be regarded as a generalisation of the wellknown supertree algorithm called Build [1,23] for checking whether or not a set of triplets is displayed by a phylogenetic tree and constructing such a tree if this is the case. In particular, the algorithm we present in Sect.…”

Reconstructing Phylogenetic Level-1 Networks from Nondense Binet and Trinet Sets

“…We end this section by giving a short description of the Build algorithm [1,23], which decides if there exists a rooted tree (i.e. a network without reticulations) displaying a given set of triplets L. The Build algorithm constructs a graph R L (L) with a vertex for each taxon and an edge {x, y} precisely if there exists a triplet…”

“…The first step of the algorithm is to construct the graph R b (B) 1 , which has a vertex for each taxon and an edge {x, y} if (at least) one of N (x; y) and N (y; x) is contained in B. The algorithm searches for a nonempty strict subset U of the vertices of Ω b (B) such that there is no arc (π 1 , π 2 ) with π 1 / ∈ U and π 2 ∈ U .…”

“…4, we present an exponential-time algorithm for an arbitrary set consisting of binets and trinets (see Theorem 2). This algorithm uses a top-down approach that is somewhat similar in nature to the Build algorithm [1,23] but it is considerably more intricate. The algorithm can be generalised to instances containing level-1 networks with arbitrarily many leaves since trinets encode level-1 networks [11].…”

“…We consider binets as well as trinets since they can provide important information to help piece together sets of trinets. Our approach can be regarded as a generalisation of the wellknown supertree algorithm called Build [1,23] for checking whether or not a set of triplets is displayed by a phylogenetic tree and constructing such a tree if this is the case. In particular, the algorithm we present in Sect.…”

Reconstructing Phylogenetic Level-1 Networks from Nondense Binet and Trinet Sets

“…Numerous phylogenetic inference methods, e.g. maximum parsimony, maximum likelihood, distance matrix fitting, subtrees consistency, and quartet based methods have been proposed over the years [15,1,14,26,17,27,4]; furthermore, it is rather common to compare the same set of species w.r.t. different biological sequences or different genes, hence obtaining various trees.…”

Efficient Algorithms for Descendent Subtrees Comparison of Phylogenetic Trees with Applications to Co-evolutionary Classifications in Bacterial Genome

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