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153
Levelwise Search and Borders of Theories in Knowledge Discovery
, 1997
"... One of the basic problems in knowledge discovery in databases (KDD) is the following: given a data set r, a class L of sentences for defining subgroups of r, and a selection predicate, find all sentences of L deemed interesting by the selection predicate. We analyze the simple levelwise algorithm fo ..."
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Cited by 259 (15 self)
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One of the basic problems in knowledge discovery in databases (KDD) is the following: given a data set r, a class L of sentences for defining subgroups of r, and a selection predicate, find all sentences of L deemed interesting by the selection predicate. We analyze the simple levelwise algorithm for finding all such descriptions. We give bounds for the number of database accesses that the algorithm makes. For this, we introduce the concept of the border of a theory, a notion that turns out to be surprisingly powerful in analyzing the algorithm. We also consider the verification problem of a KDD process: given r and a set of sentences S ` L, determine whether S is exactly the set of interesting statements about r. We show strong connections between the verification problem and the hypergraph transversal problem. The verification problem arises in a natural way when using sampling to speed up the pattern discovery step in KDD.
Methods and Problems in Data Mining. In:
 The International Conference on Database Theory,
, 1997
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Data mining, hypergraph transversals, and machine learning
, 1997
"... Several data mining problems can be formulated as problems of finding maximally specific sentences that are interesting in a database. We first show that this problem has a close relationship with the hypergraph transversal problem. We then analyze two algorithms that have been previously used in da ..."
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Cited by 77 (4 self)
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Several data mining problems can be formulated as problems of finding maximally specific sentences that are interesting in a database. We first show that this problem has a close relationship with the hypergraph transversal problem. We then analyze two algorithms that have been previously used in data mining, proving upper bounds on their complexity. The first algorithm is useful when the maximally specific interesting sentences are &quot;small&quot;. We show that this algorithm can also be used to efficiently solve a special case of the hypergraph transversal problem, improving on previous results. The second algorithm utilizes a subroutine for hypergraph transversals, and is applicable in more general situations, with complexity close to a lower bound for the problem. We also relate these problems to the model of exact learning in computational learning theory, and use the correspondence to derive some corollaries. 1
Discovering All Most Specific Sentences
 ACM Transactions on Database Systems
, 2003
"... this article, we show how the problems of finding frequent sets in relations and of finding minimal keys in databases can be reduced to this formulation. Using this theory extraction formulation [Mannila 1995, 1996; Mannila and Toivonen 1997], one can formulate general results about the complexity o ..."
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Cited by 71 (4 self)
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this article, we show how the problems of finding frequent sets in relations and of finding minimal keys in databases can be reduced to this formulation. Using this theory extraction formulation [Mannila 1995, 1996; Mannila and Toivonen 1997], one can formulate general results about the complexity of algorithms for these data mining tasks
Discovering All Most Specific Sentences by Randomized Algorithms
 In Proceedings of the 6th International Conference on Database Theory
, 1997
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New Results on Monotone Dualization and Generating Hypergraph Transversals
 SIAM JOURNAL ON COMPUTING
, 2002
"... We consider the problem of dualizing a monotone CNF (equivalently, computing all minimal transversals of a hypergraph), whose associated decision problem is a prominent open problem in NPcompleteness. We present a number of new polynomial time resp. outputpolynomial time results for significant ..."
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Cited by 51 (12 self)
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We consider the problem of dualizing a monotone CNF (equivalently, computing all minimal transversals of a hypergraph), whose associated decision problem is a prominent open problem in NPcompleteness. We present a number of new polynomial time resp. outputpolynomial time results for significant cases, which largely advance the tractability frontier and improve on previous results. Furthermore, we show that duality of two monotone CNFs can be disproved with limited nondeterminism. More precisely, this is feasible in polynomial time with O(log² n/log log n) suitably guessed bits. This result sheds new light on the complexity of this important problem.
On the Complexity of Generating Maximal Frequent and Minimal Infrequent Sets
, 2002
"... Let A be an mn binary matrix, t . . . , m} be a threshold, and # > 0 be a positive parameter. We show that given a family of O(n ) maximal tfrequent column sets for A, it is NPcomplete to decide whether A has any further maximal tfrequent sets, or not, even when the number of such ad ..."
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Cited by 47 (11 self)
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Let A be an mn binary matrix, t . . . , m} be a threshold, and # > 0 be a positive parameter. We show that given a family of O(n ) maximal tfrequent column sets for A, it is NPcomplete to decide whether A has any further maximal tfrequent sets, or not, even when the number of such additional maximal tfrequent column sets may be exponentially large. In contrast, all minimal tinfrequent sets of columns of A can be enumerated in incremental quasipolynomial time. The proof of the latter result follows from the inequality # t + 1)#, where # and # are respectively the numbers of all maximal tfrequent and all minimal tinfrequent sets of columns of the matrix A. We also discuss the complexity of generating all closed tfrequent column sets for a given binary matrix.
How Hard is it to Revise a Belief Base?
, 1996
"... If a new piece of information contradicts our previously held beliefs, we have to revise our beliefs. This problem of belief revision arises in a number of areas in Computer Science and Artificial Intelligence, e.g., in updating logical database, in hypothetical reasoning, and in machine learning. M ..."
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Cited by 43 (0 self)
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If a new piece of information contradicts our previously held beliefs, we have to revise our beliefs. This problem of belief revision arises in a number of areas in Computer Science and Artificial Intelligence, e.g., in updating logical database, in hypothetical reasoning, and in machine learning. Most of the research in this area is influenced by work in philosophical logic, in particular by Gardenfors and his colleagues, who developed the theory of belief revision. Here we will focus on the computational aspects of this theory, surveying results that address the issue of the computational complexity of belief revision.
Pinpointing in the description logic EL
 In Proceedings of KI’07, vol. 4667 of LNAI
, 2007
"... For a developer or user of a DLbased ontology, it is often quite hard to understand why a certain consequence holds, and even harder to decide how to change the ontology in case the consequence is unwanted. For example, in the current version of the medical ontology SNOMED [16], the concept Amputat ..."
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Cited by 43 (11 self)
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For a developer or user of a DLbased ontology, it is often quite hard to understand why a certain consequence holds, and even harder to decide how to change the ontology in case the consequence is unwanted. For example, in the current version of the medical ontology SNOMED [16], the concept AmputationofFinger
Discovery of Minimal Unsatisfiable Subsets of Constraints Using Hitting Set Dualization
 In Proc. of the 7th International Symposium on Practical Aspects of Declarative Languages (PADL05
, 2005
"... Abstract. An unsatisfiable set of constraints is minimal if all its (strict) subsets are satisfiable. The task of type error diagnosis requires finding all minimal unsatisfiable subsets of a given set of constraints (representing an error), in order to generate the best explanation of the error. Sim ..."
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Cited by 41 (0 self)
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Abstract. An unsatisfiable set of constraints is minimal if all its (strict) subsets are satisfiable. The task of type error diagnosis requires finding all minimal unsatisfiable subsets of a given set of constraints (representing an error), in order to generate the best explanation of the error. Similarly circuit error diagnosis requires finding all minimal unsatisfiable subsets in order to make minimal diagnoses. In this paper we present a new approach for efficiently determining all minimal unsatisfiable sets for any kind of constraints. Our approach makes use of the duality that exists between minimal unsatisfiable constraint sets and maximal satisfiable constraint sets. We show how to incrementally compute both these sets, using the fact that the complements of the maximal satisfiable constraint sets are the hitting sets of the minimal unsatisfiable constraint sets. We experimentally compare our technique to the best known method on a number of large type problems and show that considerable improvements in running time are obtained.