| |
Preface |
6 |
|
| |
About the book |
6 |
|
| |
The success of the information society |
6 |
|
| |
The remaining problems |
7 |
|
| |
Intended readership |
9 |
|
| |
Organization of the Book |
9 |
|
| |
Acknowledgements |
11 |
|
| |
Contents |
13 |
|
| |
Part I Information sharing and ontologies |
18 |
|
| |
1 Semantic integration |
19 |
|
| |
1.1 Syntactic standards |
20 |
|
| |
1.1.1 HTML: visualizing information |
20 |
|
| |
1.1.2 XML: exchanging information |
21 |
|
| |
1.1.3 RDF: a data model for meta-information |
22 |
|
| |
1.1.4 The roles of XML and RDF |
24 |
|
| |
1.2 The Problem of Heterogeneity |
26 |
|
| |
1.2.1 Structural Conflicts |
26 |
|
| |
1.2.2 Semantic Conflicts |
28 |
|
| |
1.3 Handling information semantics |
30 |
|
| |
1.3.1 Semantics from structure |
31 |
|
| |
1.3.2 Semantics from text |
32 |
|
| |
1.3.3 The need for explicit semantics |
33 |
|
| |
1.4 Representing and comparing semantics |
35 |
|
| |
1.4.1 Names and labels |
36 |
|
| |
1.4.2 Term networks |
36 |
|
| |
1.4.3 Concept lattices |
37 |
|
| |
1.4.4 Features and constraints |
38 |
|
| |
1.5 Conclusion |
39 |
|
| |
Further Reading |
39 |
|
| |
2 Ontology-based information sharing |
40 |
|
| |
2.1 Ontologies |
40 |
|
| |
2.1.1 Shared vocabularies and conceptualizations |
41 |
|
| |
2.1.2 Speci.cation of context knowledge |
42 |
|
| |
2.1.3 Beneficial applications |
44 |
|
| |
2.2 Ontologies in information integration |
46 |
|
| |
2.2.1 Content explication |
46 |
|
| |
2.2.2 Additional roles of ontologies |
49 |
|
| |
2.3 A framework for information sharing |
51 |
|
| |
2.4 A translation approach to ontology alignment |
53 |
|
| |
2.4.1 The translation process |
54 |
|
| |
2.4.2 Required infrastructure |
55 |
|
| |
2.5 Conclusions |
57 |
|
| |
3 Ontology languages for the Semantic Web |
60 |
|
| |
3.1 An abstract view |
60 |
|
| |
3.2 Two Semantic Web ontology languages |
62 |
|
| |
3.2.1 RDF Schema |
64 |
|
| |
3.2.2 OWL Lite |
65 |
|
| |
3.2.3 OWL DL |
67 |
|
| |
3.2.4 OWL Full |
68 |
|
| |
3.2.5 Computational Complexity |
69 |
|
| |
3.2.6 Simple relations between ontologies |
69 |
|
| |
3.3 Other Web-based ontology languages |
73 |
|
| |
3.3.1 Languages for expressing ontology mappings |
75 |
|
| |
3.4 Conclusions |
76 |
|
| |
Part II Creating ontologies and metadata |
77 |
|
| |
4 Ontology creation |
78 |
|
| |
4.1 Ontological engineering |
79 |
|
| |
4.2 Building an ontology infrastructure for Information sharing |
81 |
|
| |
4.3 Applying the approach |
83 |
|
| |
4.3.1 The task to be solved |
84 |
|
| |
4.3.2 The Information Sources |
85 |
|
| |
4.3.3 Sources of knowledge |
86 |
|
| |
4.4 An example walkthrough |
89 |
|
| |
4.5 Conclusions |
95 |
|
| |
5 Metadata generation |
97 |
|
| |
5.1 The role of metadata |
98 |
|
| |
5.1.1 Use of metadata |
99 |
|
| |
5.1.2 Problems with metadata management |
100 |
|
| |
5.2 The WebMaster approach |
102 |
|
| |
5.2.1 BUISY: A Web based environmental information system |
102 |
|
| |
5.2.2 The WebMaster Workbench |
103 |
|
| |
5.2.3 Applying WebMaster to the BUISY system |
105 |
|
| |
5.3 Learning classification rules |
109 |
|
| |
5.3.1 Inductive logic programming |
110 |
|
| |
5.3.2 Applying inductive logic programming |
112 |
|
| |
5.3.3 Learning experiments |
114 |
|
| |
5.3.4 Extracted classi.cation rules |
118 |
|
| |
5.4 Ontology deployment |
122 |
|
| |
5.4.1 Generating ontology-based metadata |
123 |
|
| |
5.4.2 Using ontology-based metadata |
124 |
|
| |
5.5 Conclusions |
126 |
|
| |
Part III Retrieval, integration and querying |
128 |
|
| |
6 Retrieval and Integration |
129 |
|
| |
6.1 Semantic integration |
130 |
|
| |
6.1.1 Ontology heterogeneity |
130 |
|
| |
6.1.2 Multiple systems and translatability |
132 |
|
| |
6.1.3 Approximate re-classification |
133 |
|
| |
6.2 Concept-based filtering |
135 |
|
| |
6.2.1 The idea of query-rewriting |
136 |
|
| |
6.2.2 Boolean concept expressions |
137 |
|
| |
6.2.3 Query re-writing |
139 |
|
| |
6.3 Processing complex queries |
141 |
|
| |
6.3.1 Queries as concepts |
142 |
|
| |
6.3.2 Query relaxation |
144 |
|
| |
6.4 Examples from a case study |
147 |
|
| |
6.4.1 Concept approximations |
147 |
|
| |
6.4.2 Query relaxation |
148 |
|
| |
6.5 Conclusions |
150 |
|
| |
7 Sharing statistical information |
152 |
|
| |
7.1 The nature of statistical information |
153 |
|
| |
7.1.1 Statistical metadata |
154 |
|
| |
7.1.2 A basic ontology of statistics |
155 |
|
| |
7.2 Modelling Statistics |
159 |
|
| |
7.2.1 Statistics as views |
159 |
|
| |
7.2.2 Connection with the domain |
160 |
|
| |
7.3 Translation to Semantic Web languages |
164 |
|
| |
7.3.1 Ontologies |
164 |
|
| |
7.3.2 Description of information |
168 |
|
| |
7.4 Retrieving statistical information |
171 |
|
| |
7.5 Conclusions |
173 |
|
| |
8 Spatially-related information |
175 |
|
| |
8.1 Spatial representation and reasoning |
176 |
|
| |
8.1.1 Levels of spatial abstraction |
176 |
|
| |
8.1.2 Reasoning about spatial relations |
177 |
|
| |
8.2 Ontologies and spatial relevance |
178 |
|
| |
8.2.1 Defining Spatial Relevance |
179 |
|
| |
8.2.2 Combined spatial and terminological matching |
180 |
|
| |
8.2.3 Limitations |
182 |
|
| |
8.3 Graph-based reasoning about spatial relevance |
183 |
|
| |
8.3.1 Partonomies |
184 |
|
| |
8.3.2 Topology |
186 |
|
| |
8.3.3 Directions |
187 |
|
| |
8.3.4 Distances |
188 |
|
| |
8.4 Conclusions |
190 |
|
| |
9 Integration and retrieval systems |
192 |
|
| |
9.1 OntoBroker |
193 |
|
| |
9.1.1 F-Logic and its relation to OWL |
194 |
|
| |
9.1.2 Ontologies, sources and queries |
196 |
|
| |
9.1.3 Context transformation |
198 |
|
| |
9.2 OBSERVER |
199 |
|
| |
9.2.1 Query Processing in OBSERVER |
200 |
|
| |
9.2.2 Vocabulary integration |
202 |
|
| |
9.2.3 Query plan generation and selection |
204 |
|
| |
9.3 The BUSTER system |
205 |
|
| |
9.3.1 The use of shared vocabularies |
207 |
|
| |
9.3.2 Retrieving accommodation information |
208 |
|
| |
9.3.3 Spatial and temporal information |
210 |
|
| |
9.4 Conclusions |
214 |
|
| |
Part IV Distributed ontologies |
215 |
|
| |
10 Modularization |
216 |
|
| |
10.1 Motivation |
217 |
|
| |
10.1.1 Requirements |
218 |
|
| |
10.1.2 Our approach |
218 |
|
| |
10.1.3 Related work |
219 |
|
| |
10.2 Modular ontologies |
221 |
|
| |
10.2.1 Syntax and architecture |
221 |
|
| |
10.2.2 Semantics and logical consequence |
222 |
|
| |
10.3 Comparison with OWL |
225 |
|
| |
10.3.1 Simulating OWL import |
225 |
|
| |
10.3.2 Beyond OWL |
228 |
|
| |
10.4 Reasoning in modular ontologies |
230 |
|
| |
10.4.1 Atomic concepts and relations |
230 |
|
| |
10.4.2 Preservation of Boolean operators |
230 |
|
| |
10.4.3 Compilation and integrity |
232 |
|
| |
10.5 Conclusions |
233 |
|
| |
11 Evolution management |
236 |
|
| |
11.1 Change detection and classification |
237 |
|
| |
11.1.1 Determining harmless changes |
237 |
|
| |
11.1.2 Characterizing changes |
238 |
|
| |
11.1.3 Update management |
240 |
|
| |
11.2 Application in a case study |
241 |
|
| |
11.2.1 The WonderWeb case study |
241 |
|
| |
11.2.2 Modularization in the case study |
243 |
|
| |
11.2.3 Updating the models |
244 |
|
| |
11.3 Conclusions |
245 |
|
| |
Part V Conclusions |
247 |
|
| |
12 Conclusions |
248 |
|
| |
12.1 Lessons learned |
248 |
|
| |
12.2 Assumptions and Limitations |
251 |
|
| |
12.2.1 Shared Vocabularies |
251 |
|
| |
12.2.2 On demand translation |
252 |
|
| |
12.2.3 Modular Ontologies |
253 |
|
| |
12.3 Where are we now? |
254 |
|
| |
12.4 Is that all there is? |
255 |
|
| |
A Proofs of theorems |
258 |
|
| |
A.1 Theorem 6.6 |
258 |
|
| |
A.2 Theorem 6.11 |
258 |
|
| |
A.3 Theorem 6.14 |
259 |
|
| |
A.4 Theorem 10.9 |
259 |
|
| |
A.5 Theorem 10.11 |
259 |
|
| |
A.6 Lemma 11.1 |
262 |
|
| |
A.7 Theorem 11.2 |
262 |
|
| |
References |
263 |
|
| |
Index |
277 |
|
