Tim Berners-Lee, August 2005
$Revision: 1.18 $ of $Date: 2008/08/01 21:02:19 $
Status: An early draft of a semi-formal semantics of the N3 logical
properties.
Up to Design Issues
An RDF language for the Semantic Web
Notation 3 Logic
This article gives an operational semantics for Notation3 (N3) and some
RDF properties for expressing logic. These properties, together with N3's
extensions of RDF to include variables and nested graphs, allow N3 to be used
to express rules in a web environment.
This is an informal semantics in that should be understandable by a human
being but is not a machine readable formal semantics. This document is aimed
at a logician wanting to a reference by which to compare N3 Logic with other
languages, and at the engineer coding an implementation of N3 Logic and who
wants to check the detailed semantics.
These properties are not part of the N3 language, but are properties which
allow N3 to be used to express rules, and rules which talk about the provence
of information, contents of documnts on the web, and so on. Just as OWL is
expressed in RDF by defining properties, so rules, queries, differences, and
so on can be expressed in RDF with the N3 extension to formulae.
The log: namespace has functions, which have built-in meaning for cwm and
other software.
See also:
The prefix log: is used below as shorhand for the namespace
<http://www.w3.org/2000/10/log#>. See the schema for a summary.
Motivation
The motivation of the logic was to be useful as a tool in in open web
environment. The Web contains many sources of information, with different
characteristics and relationships to any given reader. Whereas a closed
system may be built based on a single knowledge base of belived facts, an
open web-based system exists in an unbounded sea of interconnected
information resources. This requires that an agent be aware of the provenance
of information, and responsible for its disposition. The language for use in
this environemnt typically requires the ability to express what document or
message said what, so the ability to quote subgraphs and match them against
variable graphs is essential. This quotation and reference, with its
inevitable possibility of direct or indirect self-reference, if added
directly to first order logic presents problems such as paradox traps. To
avoid this, N3 logic has deliberately been kept to limited expressive power:
it currently contains no general first order negation. Negated forms of many
of the built-in functions are available, however.
A goal is that information, such as but not limited to rules, which requires
greater expresive power than the RDF graph, should be sharable in the same
way as RDF can be shared. This means that one person should be able to
express knowledge in N3 for a certian purpose, and later independently
someone else resue that knowledge for a different unforseen purpose. As the
context of the later use is unknown, this prevents us from making implicit
closed assumptions about the total set of knowledge in the system as a
whole.
Further, we require that other users of N3 in the web can express new
knowledge without affecting systems we have already built. This means that
N3 must be fundamentally monotonic: the addition of new information from
elsewhere, while it might cause an inconsistency by contradicting the old
information (which would have to be resolved before the combined system is
used), the new information cannot silently change the meaning of the original
knowledge.
The non-monotonicity of many existing systems follows from a form of negation
as failure in which a sentence is deemed false if it not held within (or,
derivable from) thecurrent knowledge
base. It is this concept of current knowledge base, which is a
variable quantity, and teh ability to indirectly make reference to it which
causes the non-monotonicity. In N3Logic, while a current knowledge base is a
fine concept, there is no ability to make reference to it implicitly in the
negative. The negation provided is the ability only for a specific given
document (or, essentially, some abstract formula) to objectively detremine
whether or not it holds, or allows one to derive, a given fact. This has
been called Scoped Negation As
Failure (SNAF).
Formal syntax
The syntax of N3 is defined by the context-free
grammar This is available in machine-readable form in Notation3 and RDF/XML.
The top-level production for an N3 document is
<http://www.w3.org/2000/10/swap/grammar/n3#document>.
In the semantics below we will consider these productions using notation as
follows.
| Production |
N3 syntax examples |
notation below for instances |
| symbol |
<foo#bar>
<http://example.com/> |
c d e f |
| variable |
Any symbol quantified by @forAll or @forSome in the same or an
outer formula. |
x y z |
| formula |
{ ... } or an
entire document |
F G H K |
| set of universal variables of F |
@forAll :x, :y. |
uvF |
| set of existential variables of F |
@forSome :z, :w. |
evF |
| set of statements of F |
|
stF |
| statement |
<#myCar>
<#color> "green". |
Fi or {s p o} |
| string |
"hello world" |
s |
| integer |
34 |
i |
| list |
( 1 2 ?x <a> ) |
L M |
| Element i of list L |
|
Li
|
| length of list |
|
|L| |
| expression |
see grammar |
n m |
| Set* |
{$ 1, 2, <a> $} |
S T
|
*The set syntax and semantics are not part of the current Notation3 language
but are under consideraton.
Semantics
Note. The Semantics of a generic RDF
statement are not defined here. The extensibility of RDF is deliberately
such that a document may draw on predicates from many sources. The statement
{n c m} expresses that the relationship denoted by c holds between the things
denoted by n and m. The meaning of the statement {n c m} in general is
defined by any specification for c. The Architecture of the WWW specifies
informally how the curious can discover information about the relation. It
discusses how the architecture and management of the WWW is such that a given
social entity has juristdiction over certain symbols (though for example
domain name ownership). This philosophy and architecture is not discussed
further here. Here though we do define the semantics of certain specific
predicates which allow the expression of the language. In analysing the
language the reader is invited to consider statements of unknown meaning
ground facts. N3Logic defines the semantics of certain properties. Clearly a
system which recognizes further logical predicates, beyond those defined
here, whose meaning introduces greater logical expressiveness would change
the properties of the logic.
Simplifications
N3 has a number of types of shortcut syntax and syntactic sugar. For
simplicity, in this article we consider a language simpler the full N3 syntax
referenced above though just as expressive, in that we ignore most syntactic
sugar. The following simplifications are made.
We ignore syntactic sugar of comma and semicolon as shorthand notations.
That is, we consider a simpler language in which any such syntax has been
expanded out. Loosely:
| A sentence of the form |
becomes two sentences |
| subject stuff ; morestuff . |
subject stuff . subject
morestuff . |
| subject predicate stuff ,
object . |
subject predicate stuff
subject predicate object . |
For those familiar withh N3, the other simplifications in th elanguage
considered here are as follows.
- prefixes have been expanded and all qualfied names replaced with
symbols using full URIs between angle brackets.
- The path syntax which uses "!" and "^" is assumed expanded into its
equivalemt blank node form;
- The "is ... of " backwards construction has been replaced by the
equivalent forwards direction syntax.
- The "=" syntax is not used as shorthand for owl:sameAs. In fact, we use
= here in the text for value equality.
- @keywords is not used
- The @a shorthand for rdf:type is replaced with a direct use of the
full URI symbol for rdf:type
- all ?x forms are replaced with explict universal quantification in the
enclosing parent of the current formula.
Notation3 has explictly quantified existential variables as well as blank
nodes. The description below does not mention blank nodes, although they are
very close in semantics to existentially quantified variables. We consider
for now a simpler langauge in which blank nodes have ben replaced by
explicitly named variables existentially quantified in the same formula.
We have only included strings and integers, rather than the whole set of RDF
types an user-defined types.
These simplifications will not deter us from using N3 shorthand in examples
where it makes them more readable, so the reader is assumed familar with
them.
Defining N3 Entailment
The RDF specification defines a very weak form of entailment, known as RDF
entailment or simple entailment. He we define the equivelent very simple
N3-entailment. This does not provide us with useful powers of inference: it
is alsmot textual includsion, but just has conjunction elimination
(statement removal) , universal elimination, existential introduction and
variable renaming. Most of this is quite traditional. The only thing to
distinguish N3 Logic from typical logics is the Formula, which allows N3
sentences to make statements about N3 sentences. The following details are
included for compleness and may be skipped.
Substitution
Substitution is defined to recurively apply
inside compound terms, as is usual. Note only that substitution does descend
into compund terms, while substitution of owl:sameAs, discussed later, does
not.
We define a substitution operator σx/m which replaces occurrences of the
variable x. with the expression m.
For compound terms, substitution of a compiound term (list, formula or set)
is performed by performing substitution of each component, recursively.
Abbreviating the substitution σx/m as σ , we define substitution
operator as usual:
σx = m (x is replaced by m)
σy = y (y not equal to x)
σa = a (symbols and literals are unchanged)
σi = i
σs = s
σ( a b ... c ) = ( σa σb ... σc )
(substitution goes into compound terms)
σ{$ a, b, ... c $} = {$ σa, σb, ... σc $}
uv σF = σ uvF
ev σF = σ evF
st σF = σ stF
In general a substitution operator is the sequential application of single
substitutions:
σ = σx1/m1σx2/m2σx2/m2 ... σxn/mn
Value equality
Value equality between terms is defined in
an oridinary way, compatible with RDF.
For concepts which exist in RDF, we use RDF equality. This is RDF node
equality. These atomic concepts have a simple form of equality.
For lists, equality is defined as a pairwise matching.
For sets, equality is defined as a mapping between equal terms existing in
each direction.
For formulae, equality F = G is defined as a substitution σ existing mapping variables to variables.
(Note that as here RDF Blank Nodes are considered as existential variables,
the substitution will map b-nodes to b-nodes.)
The table below is a summary for completeness.
| Production |
Equality |
| symbol |
uri is equal unicode string |
| variable |
variable name is equal unicode string |
| formula |
F = G iff |stF| = |stG| and there is some substitution σ
such that (∀i
. ∃j . σFi = σGj. ) |
| statement |
Subjects are equal, predicates are equal, and objects are equal
|
| string |
equal unicode string |
| integer |
equal integer |
| list L = M |
|L| = |M| & (∀i . Li = Mi ) |
| set S = T |
(∀i . ∃j . Si = Tj. ) & (∀i . ∃j . Si = Tj. ) |
| formula F = G |
∃σ. σ F = σ G |
| unicode string |
Unicode strings should be in canonical form. They are equal if the
corresponding characters have numerically equal code points. |
Conjunction
N3, like RDF, has an implied conjunction,
with its normal properties, between the statements of a formula.
The semantics of a formula which has no quantifiers (@forAll or @forSome) are
the conjunction of the semantics of the statments of which it is composed.
We define the conjunction elimination operator ce(i) of removing the
statement Fi from formula F. By the
conventional semantics of conjunction, the ce(i) operator is
truth-preserving. If you take a formula and remove a statement from it it is
still true.
CE: From F follows ce(i) F
Existential quantification
Existential quantifiers and Universal
qnatifiers have the usual qualities
Any formula, including the root
formula which matches the "document" production of the grammar, may
have a set of existential variables indicated by an @forSome declaration. This indicates
that, where the formula is considered true, it is true for at least one
substitution mapping the existantial variables onto non-variables.
As usual, we define a truth-preserving Existential Introduction operator on
formulae, that of introducing an existentially quantified variable in place
of any term. The operation ei(x, n) is defined as
- Creation of a new variable x
which occurs nowhere else
- The application of σx/n to F
- The addition ofx to evF.
EI: From F follows ei(x,n) F for any x not occuring anywhere else
Universal quantification
Any formula, (including the root formula), may have a set of universal
variables. These are indicated by @forall declarations. The scope of
the @forAll is outside the scope of any @forSome.
If both universal and existential quantification are specified for the
same context, then the scope of the universal quantification is outside the
scope of the existentials:
{ @forAll <#h>. @forSome <#g>. <#g> <#loves> <#h> }.
means
∀<#h> ( ∃<#g> (( <#g> <#loves> <#h>
))
The semantics of @forAll is that for any substitution σ = subst(x, n) where x member of uvF, if F is
true then σF is also true. Any @forAll declaration may also be
removed, preserving truth. Combining these, we define a truth-preserving
operation ue(x, n) such that ue(x, n) F is formed by
- Removal of x from evF
- Application of subst(x, n)
We have the axiom of universal elimination
UE: From F follows ue(x, n) F for all x in evF
As the actual variable used in a formula is quite irrelevant to its
semantics, the operation of replacing that variable with another one not used
elsewhere within the formula is truth-preserving.
Variable renaming
We define the operation of variable renaming vr(x,y) on F when x is a member of uvF or is
a member of evF.
VR: From F follows vr(x, y)
F where x is in uvF or evF and
y does not occur in F
Occurrence in F is defined recursively in the same way as susbtitution:
x occurs in F iff σx/nF is not equal to F for arbitrary
n.
Union of formulae
The union H = F∪G of two formulae F and G is formed, as usual, as
follows.
A variable renaming operator is applied to G such that the resulting formula
G' has no variables which are occur unquantified or differently quantified or
existentially quantified in F, and vice-versa. (F and G' may share univeral
variables).
F∪G is then defined by:
st(F∪G) = stF ∪ st G' ; ev(F∪G) = evF ∪ evG' ;
uv(F∪G) = uvF ∪ uv G'
N3 entailment
The operators conjunction elimination, existential elimination, univsal
introduction and variable renaming are truth preserving. We define an N3
entailment operator (τ) as any operator which is the successive
application of any sequence (possibly empty) of such operators. We say a
formula F n3-entails a formula τ F. By a combination of SE, EI, UE and
VR, τ F logically follows from F.
Note. RDF Graph is a subclass of N3
formula. If F and G are RDF graphs, only CI and EI apply and n3-entailment
reduces to simple entailment from RDF Semantics. (@@check for any RDF
weirdnesses)
We have now defined this simple form of N3-entailment, which amounts
to little more than textual inclusion in one expression of a subset of
another. We have not defined the normal collection of implication,
disjunction and negation which first order logic, as N3logic does provide for
first order negation. We have, in the process, defined a substition
operation which we can now use to define implication, which allows us to
express rules.
Logic properties and built-in
functions
We now define the semantics of N3 statements whose predicate is one of a
small set of logic properties. These are statements whose truth can be
established by performing calculations, or by accessing the web.
One of our objectives was to make it possible to make statements about, and
to query, other statements such as the contents of data in information
resources on the web. We have, in formulae, the ability to represent such
sets of statements. Now, to allow statements about them, we take some of
the relationships we have defined and give them URIs so that these statements
and queries can be written in N3.
While the properties we introduced can be used simply as ground facts in a
database, is very useful to take advantage of the fact that in fact they can
be calculated. In some cases, the truth or falsehood of a binary relation
can be calculated; in others, the relationship is a function so one argument
(subject or object of the statement) can be calculated from the other.
We now show how such properties are defined, and give examples of how an
inference system can use them. A motivation here is to do for logical
information what RDF did for data: to provide a common data model and a
common syntax, so that extensions of the language are made simply by
defining new terms in an ontology. Declarative programing languages like
scheme[@@] of course do this. However, they differ in their choice of pairs
rather than the RDF binary relational model for data, and lack the use of
univsal identifiers as symbols. The goal with N3 was to make a minimal
extension to the RDF data model, so that the same language could be used for
logic and data, which in practice are mixed as a colloidal solution in many
real applications.
Calculated entailment
We introduce also a set of properties whose truth may be evaluated directly
by machine. We call these "built-in" functions. The implemnation as
built-in functions is not in general required for any implementaion of the
N3 language, as they can always soundly be treated as ground facts. However,
their usefulness derives from their implementation. We say that for example
{ 1 math:negation -1 } is entailed by calculation. Like other RDF
properties, the set is designed to be extensible, as others can use URIs for
new functions. A much larger set of such properties is described for example
in the CWM bultt-ins list, and the semantics of those are not described
here.
When the truth of a statement can be deduced because its predicate is a
built-in function, then we call the derivation of the statement from no
other evidence calculated
entailment.
We now define a small set of such properties which provide the power of N3
logic for inference on the web.
log:includes
If a formula G n3-entails another formula F, this is expressed in N3 logic
as
F log:includes G.
Note. In deference to the fact that RDF
treats lists not as terms but as things constructed from first and rest
pairs, we can view formulae which include lists as including rdf:first and
rdf:rest statements. The effect on inclusion is that two other entailment
operations are added: the addition of any statement of the form L rdf:first nwhere n is the first element of L, or L rdf:rest
K where K is list forming the remaining non-first elements of L. This is
not essential to a further understanding of the logic, nor to the operation
of a system which does not contain any explicit mention of the terms
rdf:first or rdf:rest.
For the discussion of n3-entailment, clearly:
From F and F log:includes G logically follows G
This can be calculated, because it is a mathematical operation on two
compound terms. It is typically used in a query to test the contents of a
formula. Below we will show how it can be used in the antecedent of a
rule.
log:notIncludes
We write of formulae F and G: F log:notIncludes G if it is not the case that G n3-entails F.
As a form of negation, log:notincludes is completely monotonic. It can be
evaluated by a mathematical calculation on the value of the two terms: no
other knowledge gained can influence the result. This is the scoped negation as failure mentioned in
the introduction. This is not a non-monotonic negation as failure.
Note on computation: To acertain whether
G n3-entails F in the worst case involves checking for all
possible n3-entailment transformations which are combinations of the
variables which occur in G. This operation may be tedious: it is strictly
graph isomorphism complete. However the use of symbols rather than variables
for a good proportiion of nodes makes it much more tractable for practical
graphs. The ethos that it is a good idea to give name things with URIs
(symbols in N3) is a basic meme of web architecture [AWWW]. It has direct
practical application in the calculation of n3-entailment, as comparison of
graphs whose nodes are labelled is much faster (of order n log (n)))
The log:implies property relates two formulae, expressing implication. The
shorthand notation for log:implies is => . A statemnt using log:implies,
unlike log:includes, cannot be calculated. It is not a built-in function,
but the predicate which allows the expression of a rule.
The semantics of implication are standard,
but we eleborate them now for completeness.
F log:implies G is true if and only if when the formula F is true then also G
is true.
MP: From F and F => G follows G
A statement in formula H is of the form F=>G can be considered as rule, in
which case, the subject F is the premise (antecedent) of the rule, and the
object G is the consequent.
Implication is normally used within a formula with universally quantified
variables.
For example, universal quantifiers are used with a rule
in H as follows. Here H is the formula containng the rules, and K the
formula upon which the rules are applied, which we can call the
knowledgebase.
If F => G is in H, and then for every σ which is a transformation
composed of universal eliminations of variables universally quantified in H,
then it also follows that σF => σG. Therefore, for
every σ such that K includes σF, σG follows from K.
In the particular case that H and K are both the knowledge base, or formula
belived true at the top level, then
GMP: From F => G and σF follows σG if
σ is a transformation composed of universal eliminations of variables
universally quantified at the top level.
Filtering
When a knowledge base (formula) contains a lot of information, one way to
filter offf a subset is to run a set of rules on the knowledge base, and take
only the new data which is generated by the rules. This is the filter
operation.
When you apply rules to a knowledge base, the filter result of rules in H applied to K
is the union of all σG for every statement F => G which is in H,
for every σ which s a transformation composed of universal eliminations
of variables universally quantified in H such that K includes σF.
Repeated application of rules
When rules are added back repeatedly into the same knowledge base, in order
to prevent the unnecessary extra growth of the knowledge base, before adding
σG to it, there is a check to see whether the H already includes
σG, and if it does, the adding of σG is skipped.
Let the result of rules in H applied to K, ρHK, be the
union of K with all σG for every statement F => G which is in H,
for every σ which is a transformation composed of universal
eliminations of variables universally quantified in H, such that K includes
σF, and K does not n3-entail σG.
Note. This form of rule allows existentials
in the consequent: it is not datalog. It is is clearly possible in a
forward-chgaining reasoner to generate an unbounded set of conclusions with
rules of the form (using shorthand)
{ ?x a :Person } => { ?x :mother [
a :Person] }.
While this is a trap for the unwary user of
a forward-chaining reasoner, it was found to be essential in general to be
able to genearte arbitrary RDF containing blank nodes, for example when
translating information from one ontology into another.
Consider the repeated application of rules in H to K, ρiHK. If there are no
existentially quantified variables in the consequents of any of the rules in
H, then this is like datalog, and there will be some threshold n above which no more data is added, and
there is a closure: ρiHK = ρnHK for all i>n. In fact in many practical
applications even with the datalog constraint removed, there is also a
closure. This ρ∞HK is the result of running
a forward-chaining reasoner on H and K.
Rule Inference on the knowledge base
In the case in which rules are in the same formula as the data, the single
rule operation can be written ρKK, and the closure under rule
application ρ∞KK
Cwm note: the --rules command
line option calculates ρKK, and
the --think calculates ρ∞KK. The
--filter=H calculates the filter result of H on the knowledge base.
Examples
Here a simple rule uses log:implies.
@prefix log: <http://www.w3.org/2000/10/swap/log#>.
@keywords.
@forAll x, y, z. {x parent y. y sister z} log:implies {x aunt z}
This N3 formula has three
univsally quantifiied variables and one statement. The subject of the
statement,
{x parent y. y sister z}
is the antecedent of the rule and the object,
{x aunt z}
is the conclusion. Given data
Joe parent Alan.
Alan sister Susie.
a rule engine would conclude
Joe aunt Susie.
As a second example, we use a rule which looks inside a formula:
@forAll x, y, z.
{ x wrote y.
y log:includes {z weather w}.
x home z
} log:implies {
Boston weather y
}
Here the rule fires when x is bound to a symbol denoting some person who
is the author of a formula y, when the formula makes a statement about the
weather in (presumbably some place) z, and x's home is z. That is, we belive
statements about the weather at a place only from people who live there.
Given the data
Bob lives Boston.
Bob wrote { Boston weather sunny }.
Alice lives Adelaide.
Alice wrote { Boston weather cold }
a valid inference would be
Boston weather sunny.
log:supports
We say that F log:supports G if there is some sequence of rule inference
and/or calculated entailment and/or n3 entailment operators which when
applied to F produce G.
log:conclusion
The log:conclusion property expresses the relationship between a formula and
its deductive closure under operations of n3-entailment, rule entailment and
calculated entailment.
As noticed above, there are circumstances when this will not be finite.
log:conclusion is the transitive closure of log:supports.
log:supports can be written in terms of log:conclusion and log:includes.
{ ?x log:supports ?y } if and only iff { ?x log:conclusion [ log:includes
?y ]}
However, log:supports may be evaluated in many cases without evaluating
log:conclusion: one can determine whether y can be derived from x in many
ways, such as backward chaining, without necessarily having to evaluate the
(possibly infinte) deductive closure.
Now we have a system which ahs the capacity to do inference using rules, and
to operate on formulae. However, it operates in a vacuum. In fact, our goal
is that the system should operate in the context of the web.
Involving the Web
We therefore expose the web as a mapping between URIs and the information
returned whn such a URI is dereferenced, using appropriate protocols. In N3,
the information resource is identified by a symbol, which is in fact is its
URI. In N3, infromation is represented in formulae, so we represent the
information retrieved as a formula.
Not all information on the web is, of course in N3. However the architecture
we design is that N3 should here be the interlingua. Therefore, from the
point of view of this system, the semantics of a document is exactly what can
be expressed in N3, no more and no less.
log:semantics**
c log:semantics F is true iff c is a document whose logical semantics
expressed in N3 is the formula F.
The relation between a document and the logical expression which
represents its meaning expressed as N3. The Architectrue of the World Wide
Web [AWWW] defines algorithms by which a machine can determine
representations of document given its symbol (URI). For a representation
in N3, this is the formula which corresponds to the document production of the grammar. For
a representation in RDF/XML it is the formula which is the entire graph
parsed. For any other langauges, it may be calculated in as much a
specification exists which defines the equivalent N3 semantics for files in
that language.
On the meaning of N3 formula
This is not of course the semantics of the document in any absolute
sense. It is the semantics expressed in N3. In turn, the full semantics of
an N3 formula are grounded, in the definitons of the properties and classes
used by the formula. In the HTTP space in which URIs are minted by an
authority, definitive information about those definitions may be found by
dereferencing the URIs. This information may be in natural language, in some
macine-processable logic, or a mixture. Two patterns are important for the
semantic web.
One is the grounding of properties and classes by defining them in natural
language. Natural language, of course, is not cabable of giving an absolute
meaning to anything in theory, but in practice a well wrirtten document
carefully written by a group of people achieves a precision of definition
which is quite sufficient for the community to be able to exchange data using
the terms concerned. The other pattern is the raft-like defintion of terms
in terms of related neighbouring ontologies.
@@@@ A full discussion of the grounding of meaning in a web of such
definitions is beyond the scope fo this article. Here we define only the
operation semantics of a system using N3.
@@@@ Edited up to here
The log:semantics of an N3 document is the formula acheived by parsing
representation of the document.
(Cwm note: Cwm knows how to go get a document and parse N3 and RDF/XML
it in order to evaluate this. )
Other languages for web documents may be defined whose N3 semantics are
therefore also calculable, and so they could be added in due course.
See for example [GRDDL], [RDF/A], etc
However, for the purpose of the analysis of the language, it is a
convenient to consider the semantic web simply as a binary 1:1 relation
between a subset of symbols and formulae.
For a document in Notation3, log:semantics is the
log:parsedAsN3 of the log:contents of the document.
log:says
log:says is defined by:
F log:says G iff ∃ H . F
log:semantics H and H
log:includes G
In other words, loosely a document says something if a representation of it
in the sense of the Architecture of the World Wide Web [AWWW] N3-entails
it.
The semantics of log:says are similar to that of says in [PCA].
Miscellaneous
log:Truth
This is a class of true formulae.
From { F rdf:type log:Truth } follows F
The cwm engine will proces rules in the (indirectly command-line
specified) formula or any formula which that declares to be a Truth.
The dereifier will output any described formulae whcih are described as
being in the class Truth.
This class is not at all central to the logic.
Working with OWL
@@ Summary
- owl:sameAs considered the same as N3 value equality for data values.
Axioms of equality. log:equalTo and log:notEqualTo compared with
owl:SameAs. Compare math and string equality, and sparql equality.
- Operating in equality-aware mode.
- No attempt at connecting OWL DL langauge with the N3 logic.
- Use of functional properties of a datatype conflictng with OWL DL.
Conclusion
The semantics of N3 have been defined, as have some built-in opertor
properties which add logical inference using rules to the langauge, and allow
rules to define inference which can be drawn from specific web documents on
the web, as a function of ofther informatiuon about those documents.
The language has been found to have some useful practical properties. The
separation betwen the Nottaion3 extensions to RDF and the logic properties
has allowed N3 by itself to be used in many other applications directly, and
to be used with other properties to provide other functionality such as the
expression of patches (updates) [Diff].
The use of log:notIncludes to allow default reasoning without
non-monotonic behavior achieves a desgn goal for disributed rule systems.
**[Footnote: Philosophers may be distracted here into worrying about the
meaning of meaning. At least we didn't call this function "meaning"! In as
much as N3 is used as an interlingua for interoperability for different
systems, this for an N3 based system is the meaning expressed by a document.
One reviwer was aghast at the definition of semantics as being that of
retreival of a representation, its parsing and assimilation in terms of the
local common logical framework. I suspect however that the meaning of the
paper to the reviewer could be considered quite equivalently the result of
the process of retreival of a representation of the paper, its parsing by the
review, and its assimilation in terms of the reviewer's local logical
framework: a similar though perhaps imperfect process.
Of course, the semantics of many documents are not expressable in logica at
all, and many in logic but not in N3. However, we are building a system for
which a prime goal is the reading and investigation of machine-readable
documents on the web. We use the URI log:semantics for this function and
apologize for any heartache it may cause.]
F = G iff |stF| = |stG| and there is
some substitution σ such that (∀i . ∃j . σFi = σGj. )
formatting XHTML 1 with nvu
yes, discuss notational abbrevaition, but
not abstract syntax
hmm... are log:includes, log:implies and
such predicates? relations? operators? properties?
To do: describe the syntactic sugar
transformations formally to close the loop.