Info
Multimedia semantics : metadata, analysis and interaction / / Raphaèel Troncy, Benoit Huet, Simon Schenk
| Multimedia semantics : metadata, analysis and interaction / / Raphaèel Troncy, Benoit Huet, Simon Schenk |
| Autore | Troncy Raphael |
| Pubbl/distr/stampa | Chichester, West Sussex, U.K. : , : Wiley, , 2011 |
| Descrizione fisica | 1 online resource (329 p.) |
| Disciplina | 006.7 |
| Altri autori (Persone) |
HuetBenoit
SchenkSimon |
| Soggetto topico |
Multimedia systems
Semantic computing Information retrieval Database searching Metadata |
| ISBN |
1-283-20439-8
9786613204394 1-119-97062-8 1-119-97023-7 1-119-97022-9 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Foreword xi -- List of Figures xiii -- List of Tables xvii -- List of Contributors xix -- 1 Introduction 1 / Raphaël Troncy, Benoit Huet and Simon Schenk -- 2 Use Case Scenarios 7 / Werner Bailer, Susanne Boll, Oscar Celma, Michael Hausenblas and Yves Raimond -- 2.1 Photo Use Case 8 -- 2.1.1 Motivating Examples 8 -- 2.1.2 Semantic Description of Photos Today 9 -- 2.1.3 Services We Need for Photo Collections 10 -- 2.2 Music Use Case 10 -- 2.2.1 Semantic Description of Music Assets 11 -- 2.2.2 Music Recommendation and Discovery 12 -- 2.2.3 Management of Personal Music Collections 13 -- 2.3 Annotation in Professional Media Production and Archiving 14 -- 2.3.1 Motivating Examples 15 -- 2.3.2 Requirements for Content Annotation 17 -- 2.4 Discussion 18 -- Acknowledgements 19 -- 3 Canonical Processes of Semantically Annotated Media Production 21 / Lynda Hardman, ZÆêljko Obrenovic ́and Frank Nack -- 3.1 Canonical Processes 22 -- 3.1.1 Premeditate 23 -- 3.1.2 Create Media Asset 23 -- 3.1.3 Annotate 23 -- 3.1.4 Package 24 -- 3.1.5 Query 24 -- 3.1.6 Construct Message 25 -- 3.1.7 Organize 25 -- 3.1.8 Publish 26 -- 3.1.9 Distribute 26 -- 3.2 Example Systems 27 -- 3.2.1 CeWe Color Photo Book 27 -- 3.2.2 SenseCam 29 -- 3.3 Conclusion and Future Work 33 -- 4 Feature Extraction for Multimedia Analysis 35 / Rachid Benmokhtar, Benoit Huet, Gaël Richard and Slim Essid -- 4.1 Low-Level Feature Extraction 36 -- 4.1.1 What Are Relevant Low-Level Features? 36 -- 4.1.2 Visual Descriptors 36 -- 4.1.3 Audio Descriptors 45 -- 4.2 Feature Fusion and Multi-modality 54 -- 4.2.1 Feature Normalization 54 -- 4.2.2 Homogeneous Fusion 55 -- 4.2.3 Cross-modal Fusion 56 -- 4.3 Conclusion 58 -- 5 Machine Learning Techniques for Multimedia Analysis 59 / Slim Essid, Marine Campedel, Gaël Richard, Tomas Piatrik, Rachid Benmokhtar and Benoit Huet -- 5.1 Feature Selection 61 -- 5.1.1 Selection Criteria 61 -- 5.1.2 Subset Search 62 -- 5.1.3 Feature Ranking 63 -- 5.1.4 A Supervised Algorithm Example 63 -- 5.2 Classification 65.
5.2.1 Historical Classification Algorithms 65 -- 5.2.2 Kernel Methods 67 -- 5.2.3 Classifying Sequences 71 -- 5.2.4 Biologically Inspired Machine Learning Techniques 73 -- 5.3 Classifier Fusion 75 -- 5.3.1 Introduction 75 -- 5.3.2 Non-trainable Combiners 75 -- 5.3.3 Trainable Combiners 76 -- 5.3.4 Combination of Weak Classifiers 77 -- 5.3.5 Evidence Theory 78 -- 5.3.6 Consensual Clustering 78 -- 5.3.7 Classifier Fusion Properties 80 -- 5.4 Conclusion 80 -- 6 Semantic Web Basics 81 / Eyal Oren and Simon Schenk -- 6.1 The Semantic Web 82 -- 6.2 RDF 83 -- 6.2.1 RDF Graphs 86 -- 6.2.2 Named Graphs 87 -- 6.2.3 RDF Semantics 88 -- 6.3 RDF Schema 90 -- 6.4 Data Models 93 -- 6.5 Linked Data Principles 94 -- 6.5.1 Dereferencing Using Basic Web Look-up 95 -- 6.5.2 Dereferencing Using HTTP 303 Redirects 95 -- 6.6 Development Practicalities 96 -- 6.6.1 Data Stores 97 -- 6.6.2 Toolkits 97 -- 7 Semantic Web Languages 99 / Antoine Isaac, Simon Schenk and Ansgar Scherp -- 7.1 The Need for Ontologies on the Semantic Web 100 -- 7.2 Representing Ontological Knowledge Using OWL 100 -- 7.2.1 OWL Constructs and OWL Syntax 100 -- 7.2.2 The Formal Semantics of OWL and its Different Layers 102 -- 7.2.3 Reasoning Tasks 106 -- 7.2.4 OWL Flavors 107 -- 7.2.5 Beyond OWL 107 -- 7.3 A Language to Represent Simple Conceptual Vocabularies: SKOS 108 -- 7.3.1 Ontologies versus Knowledge Organization Systems 108 -- 7.3.2 Representing Concept Schemes Using SKOS 109 -- 7.3.3 Characterizing Concepts beyond SKOS 111 -- 7.3.4 Using SKOS Concept Schemes on the Semantic Web 112 -- 7.4 Querying on the Semantic Web 113 -- 7.4.1 Syntax 113 -- 7.4.2 Semantics 118 -- 7.4.3 Default Negation in SPARQL 123 -- 7.4.4 Well-Formed Queries 124 -- 7.4.5 Querying for Multimedia Metadata 124 -- 7.4.6 Partitioning Datasets 126 -- 7.4.7 Related Work 127 -- 8 Multimedia Metadata Standards 129 / Peter Schallauer, Werner Bailer, Raphaël Troncy and Florian Kaiser -- 8.1 Selected Standards 130 -- 8.1.1 MPEG-7 130 -- 8.1.2 EBU P_Meta 132. 8.1.3 SMPTE Metadata Standards 133 -- 8.1.4 Dublin Core 133 -- 8.1.5 TV-Anytime 134 -- 8.1.6 METS and VRA 134 -- 8.1.7 MPEG-21 135 -- 8.1.8 XMP, IPTC in XMP 135 -- 8.1.9 EXIF 136 -- 8.1.10 DIG35 137 -- 8.1.11 ID3/MP3 137 -- 8.1.12 NewsML G2 and rNews 138 -- 8.1.13 W3C Ontology for Media Resources 138 -- 8.1.14 EBUCore 139 -- 8.2 Comparison 140 -- 8.3 Conclusion 143 -- 9 The Core Ontology for Multimedia 145 / Thomas Franz, Raphaël Troncy and Miroslav Vacura -- 9.1 Introduction 145 -- 9.2 A Multimedia Presentation for Granddad 146 -- 9.3 Related Work 149 -- 9.4 Requirements for Designing a Multimedia Ontology 150 -- 9.5 A Formal Representation for MPEG-7 150 -- 9.5.1 DOLCE as Modeling Basis 151 -- 9.5.2 Multimedia Patterns 151 -- 9.5.3 Basic Patterns 155 -- 9.5.4 Comparison with Requirements 157 -- 9.6 Granddad's Presentation Explained by COMM 157 -- 9.7 Lessons Learned 159 -- 9.8 Conclusion 160 -- 10 Knowledge-Driven Segmentation and Classification 163 / Thanos Athanasiadis, Phivos Mylonas, Georgios Th. Papadopoulos, Vasileios Mezaris, Yannis Avrithis, Ioannis Kompatsiaris and Michael G. Strintzis -- 10.1 Related Work 164 -- 10.2 Semantic Image Segmentation 165 -- 10.2.1 Graph Representation of an Image 165 -- 10.2.2 Image Graph Initialization 165 -- 10.2.3 Semantic Region Growing 167 -- 10.3 Using Contextual Knowledge to Aid Visual Analysis 170 -- 10.3.1 Contextual Knowledge Formulation 170 -- 10.3.2 Contextual Relevance 173 -- 10.4 Spatial Context and Optimization 177 -- 10.4.1 Introduction 177 -- 10.4.2 Low-Level Visual Information Processing 177 -- 10.4.3 Initial Region-Concept Association 178 -- 10.4.4 Final Region-Concept Association 179 -- 10.5 Conclusions 181 -- 11 Reasoning for Multimedia Analysis 183 / Nikolaos Simou, Giorgos Stoilos, Carsten Saathoff, Jan Nemrava, VojtÆech Svátek, Petr Berka and Vassilis Tzouvaras -- 11.1 Fuzzy DL Reasoning 184 -- 11.1.1 The Fuzzy DL f-SHIN 184 -- 11.1.2 The Tableaux Algorithm 185 -- 11.1.3 The FiRE Fuzzy Reasoning Engine 187. 11.2 Spatial Features for Image Region Labeling 192 -- 11.2.1 Fuzzy Constraint Satisfaction Problems 192 -- 11.2.2 Exploiting Spatial Features Using Fuzzy -- Constraint Reasoning 193 -- 11.3 Fuzzy Rule Based Reasoning Engine 196 -- 11.4 Reasoning over Resources Complementary to Audiovisual Streams 201 -- 12 Multi-Modal Analysis for Content Structuring and Event Detection 205 / Noel E. O'Connor, David A. Sadlier, Bart Lehane, Andrew Salway, Jan Nemrava and Paul Buitelaar -- 12.1 Moving Beyond Shots for Extracting Semantics 206 -- 12.2 A Multi-Modal Approach 207 -- 12.3 Case Studies 207 -- 12.4 Case Study 1: Field Sports 208 -- 12.4.1 Content Structuring 208 -- 12.4.2 Concept Detection Leveraging Complementary Text Sources 213 -- 12.5 Case Study 2: Fictional Content 214 -- 12.5.1 Content Structuring 215 -- 12.5.2 Concept Detection Leveraging Audio Description 219 -- 12.6 Conclusions and Future Work 221 -- 13 Multimedia Annotation Tools 223 / Carsten Saathoff, Krishna Chandramouli, Werner Bailer, Peter Schallauer and Raphaël Troncy -- 13.1 State of the Art 224 -- 13.2 SVAT: Professional Video Annotation 225 -- 13.2.1 User Interface 225 -- 13.2.2 Semantic Annotation 228 -- 13.3 KAT: Semi-automatic, Semantic Annotation of Multimedia Content 229 -- 13.3.1 History 231 -- 13.3.2 Architecture 232 -- 13.3.3 Default Plugins 234 -- 13.3.4 Using COMM as an Underlying Model: Issues and Solutions 234 -- 13.3.5 Semi-automatic Annotation: An Example 237 -- 13.4 Conclusions 239 -- 14 Information Organization Issues in Multimedia Retrieval Using Low-Level Features 241 / Frank Hopfgartner, Reede Ren, Thierry Urruty and Joemon M. Jose -- 14.1 Efficient Multimedia Indexing Structures 242 -- 14.1.1 An Efficient Access Structure for Multimedia Data 243 -- 14.1.2 Experimental Results 245 -- 14.1.3 Conclusion 249 -- 14.2 Feature Term Based Index 249 -- 14.2.1 Feature Terms 250 -- 14.2.2 Feature Term Distribution 251 -- 14.2.3 Feature Term Extraction 252 -- 14.2.4 Feature Dimension Selection 253. 14.2.5 Collection Representation and Retrieval System 254 -- 14.2.6 Experiment 256 -- 14.2.7 Conclusion 258 -- 14.3 Conclusion and Future Trends 259 -- Acknowledgement 259 -- 15 The Role of Explicit Semantics in Search and Browsing 261 / Michiel Hildebrand, Jacco van Ossenbruggen and Lynda Hardman -- 15.1 Basic Search Terminology 261 -- 15.2 Analysis of Semantic Search 262 -- 15.2.1 Query Construction 263 -- 15.2.2 Search Algorithm 265 -- 15.2.3 Presentation of Results 267 -- 15.2.4 Survey Summary 269 -- 15.3 Use Case A: Keyword Search in ClioPatria 270 -- 15.3.1 Query Construction 270 -- 15.3.2 Search Algorithm 270 -- 15.3.3 Result Visualization and Organization 273 -- 15.4 Use Case B: Faceted Browsing in ClioPatria 274 -- 15.4.1 Query Construction 274 -- 15.4.2 Search Algorithm 276 -- 15.4.3 Result Visualization and Organization 276 -- 15.5 Conclusions 277 -- 16 Conclusion 279 / Raphaël Troncy, Benoit Huet and Simon Schenk -- References 281 -- Author Index 301 -- Subject Index 303. |
| Record Nr. | UNINA-9910139612903321 |
Troncy Raphael
|
||
| Chichester, West Sussex, U.K. : , : Wiley, , 2011 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Multimedia semantics : metadata, analysis, and interaction / / Raphael Troncy, Benoit Huet, Simon Schenk
| Multimedia semantics : metadata, analysis, and interaction / / Raphael Troncy, Benoit Huet, Simon Schenk |
| Autore | Troncy Raphael |
| Edizione | [1st ed.] |
| Pubbl/distr/stampa | Chichester, West Sussex, U.K. ; ; Hoboken, N.J., : Wiley, c2011 |
| Descrizione fisica | 1 online resource (329 p.) |
| Disciplina | 006.7 |
| Altri autori (Persone) |
HuetBenoit
SchenkSimon |
| Soggetto topico |
Multimedia systems
Semantic computing Information retrieval Database searching Metadata |
| ISBN |
9786613204394
9781283204392 1283204398 9781119970620 1119970628 9781119970231 1119970237 9781119970224 1119970229 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Foreword xi -- List of Figures xiii -- List of Tables xvii -- List of Contributors xix -- 1 Introduction 1 / Raphaël Troncy, Benoit Huet and Simon Schenk -- 2 Use Case Scenarios 7 / Werner Bailer, Susanne Boll, Oscar Celma, Michael Hausenblas and Yves Raimond -- 2.1 Photo Use Case 8 -- 2.1.1 Motivating Examples 8 -- 2.1.2 Semantic Description of Photos Today 9 -- 2.1.3 Services We Need for Photo Collections 10 -- 2.2 Music Use Case 10 -- 2.2.1 Semantic Description of Music Assets 11 -- 2.2.2 Music Recommendation and Discovery 12 -- 2.2.3 Management of Personal Music Collections 13 -- 2.3 Annotation in Professional Media Production and Archiving 14 -- 2.3.1 Motivating Examples 15 -- 2.3.2 Requirements for Content Annotation 17 -- 2.4 Discussion 18 -- Acknowledgements 19 -- 3 Canonical Processes of Semantically Annotated Media Production 21 / Lynda Hardman, ZÆêljko Obrenovic ́and Frank Nack -- 3.1 Canonical Processes 22 -- 3.1.1 Premeditate 23 -- 3.1.2 Create Media Asset 23 -- 3.1.3 Annotate 23 -- 3.1.4 Package 24 -- 3.1.5 Query 24 -- 3.1.6 Construct Message 25 -- 3.1.7 Organize 25 -- 3.1.8 Publish 26 -- 3.1.9 Distribute 26 -- 3.2 Example Systems 27 -- 3.2.1 CeWe Color Photo Book 27 -- 3.2.2 SenseCam 29 -- 3.3 Conclusion and Future Work 33 -- 4 Feature Extraction for Multimedia Analysis 35 / Rachid Benmokhtar, Benoit Huet, Gaël Richard and Slim Essid -- 4.1 Low-Level Feature Extraction 36 -- 4.1.1 What Are Relevant Low-Level Features? 36 -- 4.1.2 Visual Descriptors 36 -- 4.1.3 Audio Descriptors 45 -- 4.2 Feature Fusion and Multi-modality 54 -- 4.2.1 Feature Normalization 54 -- 4.2.2 Homogeneous Fusion 55 -- 4.2.3 Cross-modal Fusion 56 -- 4.3 Conclusion 58 -- 5 Machine Learning Techniques for Multimedia Analysis 59 / Slim Essid, Marine Campedel, Gaël Richard, Tomas Piatrik, Rachid Benmokhtar and Benoit Huet -- 5.1 Feature Selection 61 -- 5.1.1 Selection Criteria 61 -- 5.1.2 Subset Search 62 -- 5.1.3 Feature Ranking 63 -- 5.1.4 A Supervised Algorithm Example 63 -- 5.2 Classification 65.
5.2.1 Historical Classification Algorithms 65 -- 5.2.2 Kernel Methods 67 -- 5.2.3 Classifying Sequences 71 -- 5.2.4 Biologically Inspired Machine Learning Techniques 73 -- 5.3 Classifier Fusion 75 -- 5.3.1 Introduction 75 -- 5.3.2 Non-trainable Combiners 75 -- 5.3.3 Trainable Combiners 76 -- 5.3.4 Combination of Weak Classifiers 77 -- 5.3.5 Evidence Theory 78 -- 5.3.6 Consensual Clustering 78 -- 5.3.7 Classifier Fusion Properties 80 -- 5.4 Conclusion 80 -- 6 Semantic Web Basics 81 / Eyal Oren and Simon Schenk -- 6.1 The Semantic Web 82 -- 6.2 RDF 83 -- 6.2.1 RDF Graphs 86 -- 6.2.2 Named Graphs 87 -- 6.2.3 RDF Semantics 88 -- 6.3 RDF Schema 90 -- 6.4 Data Models 93 -- 6.5 Linked Data Principles 94 -- 6.5.1 Dereferencing Using Basic Web Look-up 95 -- 6.5.2 Dereferencing Using HTTP 303 Redirects 95 -- 6.6 Development Practicalities 96 -- 6.6.1 Data Stores 97 -- 6.6.2 Toolkits 97 -- 7 Semantic Web Languages 99 / Antoine Isaac, Simon Schenk and Ansgar Scherp -- 7.1 The Need for Ontologies on the Semantic Web 100 -- 7.2 Representing Ontological Knowledge Using OWL 100 -- 7.2.1 OWL Constructs and OWL Syntax 100 -- 7.2.2 The Formal Semantics of OWL and its Different Layers 102 -- 7.2.3 Reasoning Tasks 106 -- 7.2.4 OWL Flavors 107 -- 7.2.5 Beyond OWL 107 -- 7.3 A Language to Represent Simple Conceptual Vocabularies: SKOS 108 -- 7.3.1 Ontologies versus Knowledge Organization Systems 108 -- 7.3.2 Representing Concept Schemes Using SKOS 109 -- 7.3.3 Characterizing Concepts beyond SKOS 111 -- 7.3.4 Using SKOS Concept Schemes on the Semantic Web 112 -- 7.4 Querying on the Semantic Web 113 -- 7.4.1 Syntax 113 -- 7.4.2 Semantics 118 -- 7.4.3 Default Negation in SPARQL 123 -- 7.4.4 Well-Formed Queries 124 -- 7.4.5 Querying for Multimedia Metadata 124 -- 7.4.6 Partitioning Datasets 126 -- 7.4.7 Related Work 127 -- 8 Multimedia Metadata Standards 129 / Peter Schallauer, Werner Bailer, Raphaël Troncy and Florian Kaiser -- 8.1 Selected Standards 130 -- 8.1.1 MPEG-7 130 -- 8.1.2 EBU P_Meta 132. 8.1.3 SMPTE Metadata Standards 133 -- 8.1.4 Dublin Core 133 -- 8.1.5 TV-Anytime 134 -- 8.1.6 METS and VRA 134 -- 8.1.7 MPEG-21 135 -- 8.1.8 XMP, IPTC in XMP 135 -- 8.1.9 EXIF 136 -- 8.1.10 DIG35 137 -- 8.1.11 ID3/MP3 137 -- 8.1.12 NewsML G2 and rNews 138 -- 8.1.13 W3C Ontology for Media Resources 138 -- 8.1.14 EBUCore 139 -- 8.2 Comparison 140 -- 8.3 Conclusion 143 -- 9 The Core Ontology for Multimedia 145 / Thomas Franz, Raphaël Troncy and Miroslav Vacura -- 9.1 Introduction 145 -- 9.2 A Multimedia Presentation for Granddad 146 -- 9.3 Related Work 149 -- 9.4 Requirements for Designing a Multimedia Ontology 150 -- 9.5 A Formal Representation for MPEG-7 150 -- 9.5.1 DOLCE as Modeling Basis 151 -- 9.5.2 Multimedia Patterns 151 -- 9.5.3 Basic Patterns 155 -- 9.5.4 Comparison with Requirements 157 -- 9.6 Granddad's Presentation Explained by COMM 157 -- 9.7 Lessons Learned 159 -- 9.8 Conclusion 160 -- 10 Knowledge-Driven Segmentation and Classification 163 / Thanos Athanasiadis, Phivos Mylonas, Georgios Th. Papadopoulos, Vasileios Mezaris, Yannis Avrithis, Ioannis Kompatsiaris and Michael G. Strintzis -- 10.1 Related Work 164 -- 10.2 Semantic Image Segmentation 165 -- 10.2.1 Graph Representation of an Image 165 -- 10.2.2 Image Graph Initialization 165 -- 10.2.3 Semantic Region Growing 167 -- 10.3 Using Contextual Knowledge to Aid Visual Analysis 170 -- 10.3.1 Contextual Knowledge Formulation 170 -- 10.3.2 Contextual Relevance 173 -- 10.4 Spatial Context and Optimization 177 -- 10.4.1 Introduction 177 -- 10.4.2 Low-Level Visual Information Processing 177 -- 10.4.3 Initial Region-Concept Association 178 -- 10.4.4 Final Region-Concept Association 179 -- 10.5 Conclusions 181 -- 11 Reasoning for Multimedia Analysis 183 / Nikolaos Simou, Giorgos Stoilos, Carsten Saathoff, Jan Nemrava, VojtÆech Svátek, Petr Berka and Vassilis Tzouvaras -- 11.1 Fuzzy DL Reasoning 184 -- 11.1.1 The Fuzzy DL f-SHIN 184 -- 11.1.2 The Tableaux Algorithm 185 -- 11.1.3 The FiRE Fuzzy Reasoning Engine 187. 11.2 Spatial Features for Image Region Labeling 192 -- 11.2.1 Fuzzy Constraint Satisfaction Problems 192 -- 11.2.2 Exploiting Spatial Features Using Fuzzy -- Constraint Reasoning 193 -- 11.3 Fuzzy Rule Based Reasoning Engine 196 -- 11.4 Reasoning over Resources Complementary to Audiovisual Streams 201 -- 12 Multi-Modal Analysis for Content Structuring and Event Detection 205 / Noel E. O'Connor, David A. Sadlier, Bart Lehane, Andrew Salway, Jan Nemrava and Paul Buitelaar -- 12.1 Moving Beyond Shots for Extracting Semantics 206 -- 12.2 A Multi-Modal Approach 207 -- 12.3 Case Studies 207 -- 12.4 Case Study 1: Field Sports 208 -- 12.4.1 Content Structuring 208 -- 12.4.2 Concept Detection Leveraging Complementary Text Sources 213 -- 12.5 Case Study 2: Fictional Content 214 -- 12.5.1 Content Structuring 215 -- 12.5.2 Concept Detection Leveraging Audio Description 219 -- 12.6 Conclusions and Future Work 221 -- 13 Multimedia Annotation Tools 223 / Carsten Saathoff, Krishna Chandramouli, Werner Bailer, Peter Schallauer and Raphaël Troncy -- 13.1 State of the Art 224 -- 13.2 SVAT: Professional Video Annotation 225 -- 13.2.1 User Interface 225 -- 13.2.2 Semantic Annotation 228 -- 13.3 KAT: Semi-automatic, Semantic Annotation of Multimedia Content 229 -- 13.3.1 History 231 -- 13.3.2 Architecture 232 -- 13.3.3 Default Plugins 234 -- 13.3.4 Using COMM as an Underlying Model: Issues and Solutions 234 -- 13.3.5 Semi-automatic Annotation: An Example 237 -- 13.4 Conclusions 239 -- 14 Information Organization Issues in Multimedia Retrieval Using Low-Level Features 241 / Frank Hopfgartner, Reede Ren, Thierry Urruty and Joemon M. Jose -- 14.1 Efficient Multimedia Indexing Structures 242 -- 14.1.1 An Efficient Access Structure for Multimedia Data 243 -- 14.1.2 Experimental Results 245 -- 14.1.3 Conclusion 249 -- 14.2 Feature Term Based Index 249 -- 14.2.1 Feature Terms 250 -- 14.2.2 Feature Term Distribution 251 -- 14.2.3 Feature Term Extraction 252 -- 14.2.4 Feature Dimension Selection 253. 14.2.5 Collection Representation and Retrieval System 254 -- 14.2.6 Experiment 256 -- 14.2.7 Conclusion 258 -- 14.3 Conclusion and Future Trends 259 -- Acknowledgement 259 -- 15 The Role of Explicit Semantics in Search and Browsing 261 / Michiel Hildebrand, Jacco van Ossenbruggen and Lynda Hardman -- 15.1 Basic Search Terminology 261 -- 15.2 Analysis of Semantic Search 262 -- 15.2.1 Query Construction 263 -- 15.2.2 Search Algorithm 265 -- 15.2.3 Presentation of Results 267 -- 15.2.4 Survey Summary 269 -- 15.3 Use Case A: Keyword Search in ClioPatria 270 -- 15.3.1 Query Construction 270 -- 15.3.2 Search Algorithm 270 -- 15.3.3 Result Visualization and Organization 273 -- 15.4 Use Case B: Faceted Browsing in ClioPatria 274 -- 15.4.1 Query Construction 274 -- 15.4.2 Search Algorithm 276 -- 15.4.3 Result Visualization and Organization 276 -- 15.5 Conclusions 277 -- 16 Conclusion 279 / Raphaël Troncy, Benoit Huet and Simon Schenk -- References 281 -- Author Index 301 -- Subject Index 303. |
| Record Nr. | UNINA-9910815594503321 |
|
Troncy Raphael
|
||
| Chichester, West Sussex, U.K. ; ; Hoboken, N.J., : Wiley, c2011 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||