Abductive logic programming
Abductive logic programming is a high-level knowledge-representation framework that can be used to solve problems declaratively based on abductive reasoning. It extends normal logic programming by allowing some predicates to be incompletely defined, declared as abducible predicates. Problem solving is effected by deriving hypotheses on these abducible predicates as solutions of problems to be solved. These problems can be either observations that need to be explained or goals to be achieved. It can be used to solve problems in diagnosis, planning, natural language and machine learning. It has also been used to interpret negation as failure as a form of abductive reasoning.
Syntax
Abductive logic programs have three components, where:- P is a logic program of exactly the same form as in logic programming
- A is a set of predicate names, called the abducible predicates
- IC is a set of first-order classical formulae.
false:- A1,...,An, not B1,..., not Bm.
Such a constraint means that it is not possible for all A1,...,An to be true and at the same time all of B1,...,Bm to be false.
Informal meaning and problem solving
The clauses in P define a set of non-abducible predicates and through this they provide a description of the problem domain. The integrity constraints in IC specify general properties of the problem domain that need to be respected in any solution of a problem.A problem, G, which expresses either an observation that needs to be explained or a goal that is desired, is represented by a conjunction of positive and negative literals. Such problems are solved by computing "abductive explanations" of G.
An abductive explanation of a problem G is a set of positive ground instances of the abducible predicates, such that, when these are added to the logic program P, the problem G and the integrity constraints IC both hold. Thus abductive explanations extend the logic program P by the addition of full or partial definitions of the abducible predicates. In this way, abductive explanations form solutions of the problem according to the description of the problem domain in P and IC. The extension or completion of the problem description given by the abductive explanations provides new information, hitherto not contained in the solution to the problem. Quality criteria to prefer one solution over another, often expressed via integrity constraints, can be applied to select specific abductive explanations of the problem G.
Computation in ALP combines the backwards reasoning of normal logic programming with a kind of integrity checking to show that the abductive explanations satisfy the integrity constraints.
The following two examples, written in simple structured English rather than in the strict syntax of ALP, illustrate the notion of abductive explanation in ALP and its relation to problem solving.
Example 1
The abductive logic program,, has in the following sentences:Grass is wet if it rained.
Grass is wet if the sprinkler was on.
The sun was shining.
The abducible predicates in are "it rained" and "the sprinkler was on" and the only integrity constraint in is:
false if it rained and the sun was shining.
The observation that the grass is wet has two potential explanations, "it rained" and "the sprinkler was on", which entail the observation. However, only the second potential explanation, "the sprinkler was on", satisfies the integrity constraint.
Example 2
Consider the abductive logic program consisting of the following clauses:X is a citizen if X is born in the USA.
X is a citizen if X is born outside the USA and X is a resident of the USA and X is naturalized.
X is a citizen if X is born outside the USA and Y is the mother of X and Y is a citizen and X is registered.
Mary is the mother of John.
Mary is a citizen.
together with the five abducible predicates, "is born in the USA", "is born outside the USA", "is a resident of the USA", "is naturalized" and "is registered" and the integrity constraint:
false if John is a resident of the USA.
The goal "John is citizen" has two abductive solutions, one of which is "John is born in the USA", the other of which is "John is born outside the USA" and "John is registered". The potential solution of becoming a citizen by residence and naturalization fails because it violates the integrity constraint.
A more complex example that is also written in the more formal syntax of ALP is the following.
Example 3
The abductive logic program below describes a simple model of the lactose metabolism of the bacterium E. coli. The program, P, describes that E. coli can feed on the sugar lactose if it makes two enzymes permease and galactosidase. Like all enzymes, these are made if they are coded by a gene that is expressed. The two enzymes of permease and galactosidase are coded by two genes, lac and lac respectively, in a cluster of genes – called an operon – that is expressed when the amounts of glucose are low and lactose are high or when they are both at medium level. The abducibles, A, declare all ground instances of the predicates "amount" as assumable. This reflects that in the model the amounts at any time of the various substances are unknown. This is incomplete information that is to be determined in each problem case.The integrity constraints, IC, state that the amount of any substance can only take one value.
; Domain knowledge
feed :- make, make.
make :- code, express.
express :- amount, amount.
express :- amount, amount.
code.
code.
temperature :- amount.
; Integrity constraints
false :- amount, amount, V1 ≠ V2.
; Abducibles
abducible_predicate.
The problem goal is. This can arise either as an observation to be explained or as a state of affairs to be achieved by finding a plan. This goal has two abductive explanations:
The decision which of the two to adopt could depend on addition information that is available, e.g. it may be known that when the level of glucose is low then the organism exhibits a certain behaviour – in the model such additional information is that the temperature of the organism is low – and by observing the truth or falsity of this it is possible to choose the first or second explanation respectively.
Once an explanation has been chosen, then this becomes part of the theory, which can be used to draw new conclusions. The explanation and more generally these new conclusions form the solution of the problem.
Formal semantics
The formal semantics of the central notion of an abductive explanation in ALP can be defined in the following way.Given an abductive logic program,, an abductive explanation for a problem is a set of ground atoms on abducible predicates such that:
- is consistent
The above definition takes a particular view on the formalization of the role of the integrity constraints as restrictions on the possible abductive solutions. It requires that these are entailed by the logic program extended with an abductive solution, thus meaning that in any model of the extended logic program the requirements of the integrity constraints are met. In some cases this may be unnecessarily strong and the weaker requirement of consistency, namely that is consistent, can be sufficient, meaning that there exists at least one model of the extended program where the integrity constraints hold. In practice, in many cases these two ways of formalizing the role of the integrity constraints coincide as the logic program and its extensions always have a unique model. Many of the ALP systems use the entailment view of the integrity constraints as this can be easily implemented without the need for any extra specialized procedures for the satisfaction of the integrity constraints since this view treats the constraints in the same way as the problem goal.
In many practical cases the third condition in this formal definition of an abductive explanation in ALP is either trivially satisfied or it is contained in the second condition via the use of specific integrity constraints that capture consistency.