We give two sufficient conditions for the lattice Co(R n , X) of relatively convex sets of R n to be join-semidistributive, where X is a finite union of segments. We also prove that every finite lower bounded lattice can be embedded into Co(R n , X), for a suitable finite subset X of R n .
Let L be a join-distributive lattice with length n and width(Ji L) ≤ k. There are two ways to describe L by k − 1 permutations acting on an n-element set: a combinatorial way given by P. H. Edelman and R. E. Jamison in 1985 and a recent lattice theoretical way of the second author. We prove that these two approaches are equivalent. Also, we characterize join-distributive lattices by trajectories.
Closure system on a finite set is a unifying concept in logic programming,
relational data bases and knowledge systems. It can also be presented in the
terms of finite lattices, and the tools of economic description of a finite
lattice have long existed in lattice theory. We present this approach by
describing the so-called D-basis and introducing the concept of ordered direct
basis of an implicational system. A direct basis of a closure operator, or an
implicational system, is a set of implications that allows one to compute the
closure of an arbitrary set by a single iteration. This property is preserved
by the D-basis at the cost of following a prescribed order in which
implications will be attended. In particular, using an ordered direct basis
allows to optimize the forward chaining procedure in logic programming that
uses the Horn fragment of propositional logic. One can extract the D-basis from
any direct unit basis S in time polynomial in the size of S, and it takes only
linear time of the cardinality of the D-basis to put it into a proper order. We
produce examples of closure systems on a 6-element set, for which the canonical
basis of Duquenne and Guigues is not ordered direct.Comment: 25 pages, 10 figures; presented at AMS conference,
TACL-2011,ISAIM-2012 and at RUTCOR semina
Abstract. We show that every optimum basis of a finite closure system, in D. Maier's sense, is also right-side optimum, which is a parameter of a minimum CNF representation of a Horn Boolean function. New parameters for the size of the binary part are also established. We introduce the K-basis of a general closure system, which is a refinement of the canonical basis of V. Duquenne and J.L. Guigues, and discuss a polynomial algorithm to obtain it. We study closure systems with unique critical sets, and some subclasses of these where the K-basis is unique. A further refinement in the form of the E-basis is possible for closure systems without D-cycles. There is a polynomial algorithm to recognize the D-relation from a K-basis. Thus, closure systems without D-cycles can be effectively recognized. While the E-basis achieves an optimum in one of its parts, the optimization of the others is an NP-hard problem.
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