11 research outputs found
Boolean Functions: Theory, Algorithms, and Applications
This monograph provides the first comprehensive presentation of the theoretical, algorithmic and applied aspects of Boolean functions, i.e., {0,1}-valued functions of a finite number of {0,1}-valued variables.
The book focuses on algebraic representations of Boolean functions, especially normal form representations. It presents the fundamental elements of the theory (Boolean equations and satisfiability problems, prime implicants and associated representations, dualization, etc.), an in-depth study of special classes of Boolean functions (quadratic, Horn, shellable, regular, threshold, read-once, etc.), and two fruitful generalizations of the concept of Boolean functions (partially defined and pseudo-Boolean functions). It features a rich bibliography of about one thousand items.
Prominent among the disciplines in which Boolean methods play a significant role are propositional logic, combinatorics, graph and hypergraph theory, complexity theory, integer programming, combinatorial optimization, game theory, reliability theory, electrical and computer engineering, artificial intelligence, etc. The book contains applications of Boolean functions in all these areas
Cutting corners
We define a class of subshifts defined by a family of allowed patterns of the same shape where, for any contents of the shape minus a corner, the number of ways to fill in the corner is the same. For such a subshift, a locally legal pattern of convex shape is globally legal, and there is a measure that samples uniformly on convex sets. We show by example that these subshifts need not admit a group structure by shift-commuting continuous operations. Our approach to convexity is axiomatic, and only requires an abstract convex geometry that is “midpointed with respect to the shape”. We construct such convex geometries on several groups, in particular strongly polycyclic groups and free groups. We also show some other methods for sampling finite patterns, and show a link to conjectures of Gottshalk and Kaplansky.</p
Triangulations
The earliest work in topology was often based on explicit combinatorial models – usually triangulations – for the spaces being studied. Although algebraic methods in topology gradually replaced combinatorial ones in the mid-1900s, the emergence of computers later revitalized the study of triangulations. By now there are several distinct mathematical communities actively doing work on different aspects of triangulations. The goal of this workshop was to bring the researchers from these various communities together to stimulate interaction and to benefit from the exchange of ideas and methods
New Algorithms andMethodology for Analysing Distances
Distances arise in a wide variety of di�erent contexts, one of which is partitional clustering,
that is, the problem of �nding groups of similar objects within a set of objects.¿ese
groups are seemingly very easy to �nd for humans, but very di�cult to �nd for machines
as there are two major di�culties to be overcome: the �rst de�ning an objective criterion
for the vague notion of “groups of similar objects”, and the second is the computational
complexity of �nding such groups given a criterion. In the �rst part of this thesis, we focus
on the �rst di�culty and show that even seemingly similar optimisation criteria used
for partitional clustering can produce vastly di�erent results. In the process of showing
this we develop a new metric for comparing clustering solutions called the assignment
metric. We then prove some new NP-completeness results for problems using two related
“sum-of-squares” clustering criteria.
Closely related to partitional clustering is the problem of hierarchical clustering. We
extend and formalise this problem to the problem of constructing rooted edge-weighted
X-trees, that is trees with a leafset X. It is well known that an X-tree can be uniquely
reconstructed from a distance on X if the distance is an ultrametric. But in practice the
complete distance on X may not always be available. In the second part of this thesis we
look at some of the circumstances under which a tree can be uniquely reconstructed from
incomplete distance information. We use a concept called a lasso and give some theoretical
properties of a special type of lasso. We then develop an algorithm which can construct
a tree together with a lasso from partial distance information and show how this can be
applied to various incomplete datasets
Appendix to Request for Judicial Notice of Facts and Documents
https://digital.sandiego.edu/hirabayashi_petitions/1002/thumbnail.jp
LIPIcs, Volume 244, ESA 2022, Complete Volume
LIPIcs, Volume 244, ESA 2022, Complete Volum