rd generation services. The text covers the service creation problem as well as the network technology alternatives to support these services and discusses active and programmable networks in detail. It gives an insight into the practical approach followed in the CONTEXT project, supplying concrete guidelines for building successful context–aware services.
Fast and Efficient Context–Aware Services:
- Provides comprehensive and in–depth information on state–of–the–art CAS technology.
- Proposes a system architecture for CAS creation and delivery, discussing service management and active network layers.
- Describes the service lifecycle functional architecture, covering service authoring, customization, invocation, and assurance.
- Explains system design considerations and details, system evaluation criteria, test–bed requirements, and evaluation results.
Fast and Efficient Context–Aware Services is an invaluable resource for telecommunications developers, researchers in academia and industry, advanced students in Computer Science and Electrical Engineering, telecoms operators, as well as telecommunication management and operator personnel.
1.1. Context–Aware Services.
1.2. The Context Project.
1.3. Structure of the Book.
2. Context Awareness and Modeling: Background.
2.1. Some Context Definitions.
2.2. Context–Aware Service.
2.3. Context–Awareness System Research.
2.3.1. Context–Aware Ubiquitous Computing Applications.
2.3.2. Context–Aware Frameworks.
2.3.3. Context–Aware Application Life Cycle.
2.3.4. Context in GRID Computing.
2.3.5. Context–Aware Sensors Computing.
2.3.6. Context–Aware Ontologies.
2.3.7. Context in Mobile Systems and Devices.
2.3.8. Context Aware Communications.
2.3.9. Context–Aware Flows.
3. The Service Life Cycle Functional Architecture.
3.2. Service Life Cycle Model for Context–Aware Services.
3.3. Service Creation.
3.3.1. CAS Authoring.
3.3.2. Service Customization.
3.3.3. Code and Policies Generation Engine.
3.4. Service Management.
3.4.1. Code Distributor.
3.4.2. Code Execution Controller.
3.4.3. Invocation Service Listener.
3.4.4. Service Assurance.
4. Context–Aware Services and the Network Layer.
4.1. Network Layer Requirements for Context–Aware Services.
4.2. Current State of Service–Aware Networks and Open Network Interfaces.
4.3. Requirements for Network Context Information Collection and Dissemination.
4.3.1. Access to Local Network Level Information.
4.3.2. Gathering and Disseminating Global Network Information.
4.4. Requirements for Network Level Control.
4.5. Security Considerations.
4.5.1. Implementation Aspects.
5. Baseline Technology Review.
5.2. Open Signaling Approach.
5.3. IFTF ForCES Approach.
5.4. DARPA Active Networks Approach.
5.5. Programmable Networks Components.
5.5.1. Node OS: Node Operating Systems.
5.5.2. EE: Execution Environments.
5.5.3. Programmable Management Services.
6. CAS Creation and Management System Architecture and Design Considerations.
6.2. Service Layer Overview.
6.2.1. Policy Management Components.
6.2.2. Service Execution Components.
6.2.3. Interfaces Between Service Layer Components.
6.3. Service Layer Implementation Considerations.
6.3.1. Why Policies?
6.3.2. Objectives of the Policy–Based Service Management System.
6.4. Context Policy–Based Service Management System.
6.4.1. On System Components.
6.4.2. Domain–Specific Policies.
6.4.3. Service Assurance.
7. The Service Execution Environment and Context Delivery.
7.1. A Bird s–Eye View.
7.2. The Active Platform.
7.2.1. The Session Broker.
7.2.2. Execution Environment.
7.2.3. Management of Active Nodes.
7.2.4. DINA Active Packets.
7.2.6. The IP–Related Brokers.
7.2.7. VoIP Support: the SIP Broker.
7.2.8. Wireless Support: The WLAN Broker.
7.3. Context Delivery System.
7.3.1. Functional Overview.
7.3.2. Functional Decomposition.
7.3.3. Context Broker Interfaces.
8. System Evaluation.
8.1. The Scenarios.
8.1.1. Work From Anywhere (WFA).
8.1.2. Crisis–Aware Telecommunications Services.
8.1.3. Moving Campus Services.
8.1.4. Testbed and Service Layer Set Up.
8.2. Performance Evaluation.
8.2.1. CPU Load.
8.2.2. Info–Broker Load.
9.1. Context–Aware Services.
9.2. Autonomic Communications Vision.
Arto Juhola has been with Technical Research Centre of Finland since 2001. He manages the EU IST CONTEXT project formed by Alex Galis. Arto has written largely red tape and project proposal aspects, and has contributed to one conference paper within the EU IST project.
Alex Galis is a Visiting Professor in the Telecommunications Systems Research Group of the Department of Electronic and Electrical Engineering, University College London. He is the author and co–author of more that 125 papers and technical reports and 4 books in the areas of programmable networks and services, selfware and autonomic management, context sensitive communications, programmable GRIDs and ambient networks.
Joan Serrat–Fernandez has worked at Universitat Politecnica de Catalunya since 1977. Recently, he has participated in the IST–FAIN, IST–WINMAN and IST–CONTEXT, three EU projects dealing with management of active networks, IP/WDM and context aware services respectively. Prof. Serrat is a contributor in technical, scientific fora and magazines. He is also co–author/co–editor of four technical books.