1.

Record Nr.

UNINA9910139496803321

Titolo

End-to-end quality of service engineering in next generation heterogeneous networks [[electronic resource] /] / edited by Abdelhamid Mellouk

Pubbl/distr/stampa

London, : ISTE

Hoboken, NJ, : Wiley, 2009

ISBN

1-282-16528-3

9786612165283

0-470-61147-2

0-470-39411-0

Descrizione fisica

1 online resource (474 p.)

Collana

ISTE ; ; v.63

Altri autori (Persone)

MelloukAbdelhamid

Disciplina

004.6

621.3821

Soggetti

Computer networks - Quality control

Internetworking (Telecommunication)

Electronic books.

Lingua di pubblicazione

Inglese

Formato

Materiale a stampa

Livello bibliografico

Monografia

Note generali

Description based upon print version of record.

Nota di bibliografia

Includes bibliographical references and index.

Nota di contenuto

End-to-End Quality of Service Engineering in Next Generation Heterogenous Networks; Table of Contents; Chapter 1. Challenges for End-to-End Quality of Service over Heterogenous Networks; 1.1. Introduction; 1.2. Research challenges in end-to-end QoS; 1.3. Contents; 1.3.1. Chapter 2: principles and mechanisms for Quality of Service in networks; 1.3.2. Chapter 3: different approaches to guarantee Quality of Service; 1.3.3. Chapter 4: Quality of Service-based adaptive routing approaches; 1.3.4. Chapter 5: optical networks: new challenges and paradigms for Quality of Service

1.3.5. Chapter 6: pushing Quality of Service across interdomain boundaries1.3.6. Chapter 7: Internet-based collaborative teleoperation: towards tailorable groupware for teleoperation; 1.3.7. Chapter 8: survivability-oriented Quality of Service in optical networks; 1.3.8. Chapter 9: MAC protocols for Quality of Service provisioning in mobile ad hoc networks; 1.3.9. Chapter 10: Quality of Service-based



scheduling mechanisms in mobile networks; 1.3.10. Chapter 11: Quality of Service in wireless ad hoc and sensor networks; 1.3.11. Chapter 12: Quality of Service challenges in WiMAX networks

1.3.12. Chapter 13: Quality of Service support for MPLS-based wired-wireless domains1.3.13. Chapter 14: Quality of Service control in VoIP applications; 1.3.14. Chapter 15: towards collaborative teleoperation based on human scale networked mixed reality environments; 1.3.15. Chapter 16: Quality of Service driven context awareness using semantic sensors infrastructure; 1.3.16. Chapter 17: effect of transmission delay on haptic perception in shared virtual environments; 1.4. Conclusion; Chapter 2. Principles and Mechanisms for Quality of Service in Networks; 2.1. Introduction

2.2. Concepts and definitions2.2.1. Definitions of QoS in a networking context; 2.2.2. End-to-end QoS; 2.2.3. Classes (levels) of service; 2.2.4. Differentiated classes of service; 2.3. QoS parameters and application classification; 2.3.1. QoS parameter types; 2.3.2. Application classification; 2.3.3. QoS parameter specification; 2.3.4. Traffic models; 2.3.5. Service level agreements; 2.4. Mechanisms and functions for QoS provisioning; 2.4.1. General issues; 2.4.2. QoS establishment; 2.4.3. Admission control; 2.4.4. QoS negotiation and renegotiation; 2.4.5. Resource management

2.4.6. QoS signaling protocols2.4.7. Routing; 2.4.8. Traffic control mechanisms; 2.4.9. QoS control, maintenance, monitoring; 2.4.10. QoS policy; 2.4.11. QoS mapping and translation; 2.5. Overview of IntServ, DiffServ and MPLS; 2.5.1. Integrated services architecture; 2.5.2. DiffServ architecture; 2.5.3. MPLS; 2.6. Conclusion; 2.7. References; Chapter 3. Different Approaches to Guarantee Quality of Service; 3.1. Introduction to QoS; 3.1.1. Different QoS requirements; 3.1.2. Organization of chapter; 3.2. Means of managing an end-to-end time constraint

3.2.1. Components of an end-to-end response time

Sommario/riassunto

A modern communication network?can be described as?a large, complex, distributed system composed by higher interoperating, smaller sub-systems. Today, the proliferation and convergence of different types of wired, wireless, and mobile networks are crucial for the success of the next generation networking.?However, these networks can hardly meet the requirements of future integrated-service networks, and are expected to carry multimedia traffic with various Quality of Experience (QoE) and Quality of Service (QoS) requirements. Providing all relevant QoS/QoE issues in these heterogeneous network