Research Catalog

Title

Understanding LTE and its performance / Tara Ali-Yahiya ; foreword by Khaldoun Al Agha.

Author

Ali-Yahiya, Tara.

Publication

New York : Springer, ©2011.

Items in the Library & Off-site

Details

Description

xxv, 250 pages : illustrations; 24 cm

Subject

• Long-Term Evolution (Telecommunications)
• Wireless communication systems
• Systèmes de communication sans fil

Bibliography (note)

• Includes bibliographical references and index.

Contents

• Part I. Understanding LTE : -- 1. Introduction to Mobile Broadband Wireless -- 2. Network Architecture and Protocols -- 2. Interface in User and Control Planes -- 1. Interface in User and Control Planes -- 3. LTE Radio Layer Design -- 2. Design -- 4. LTE Phyiscal Layer -- Part II. LTE Key Features : -- 5. Quality of Service -- 6. Interworking Design for LTE Convergence -- 7. Mobility -- 4. and IPv -- 1. Interface -- 1. Interface (Without Changing S-GW) -- 8. LTE and Femtocell -- Part III. LTE Performance : -- 9. Downlink Radio Resource Allocation Strategies in LTE Networks -- 10. Performance Study of Opportunistic Scheduling in LTE Networks -- 11. Cross-Layer Multiservice Scheduling for LTE Networks -- 12. Fractional Frequency Reuse in LTE Networks -- 13. Performance Study of Mobile Wi MAX and LTE Interworking -- 14. LTE Femtocell Integration with Wireless Sensor/Actuator Networks and RFID Technologies --
• Part I. Understanding LTE : -- 1. Introduction to Mobile Broadband Wireless -- 1.1. Mobile Generation Networks -- 1.1.1. First-Generation Mobile 1G -- 1.1.2. Second-Generation Mobile 2G -- 1.1.3. Third-Generation Mobile 3G -- 1.1.4. The Path Toward 4G -- 1.2. LTE and Other Broadband Wireless Technologies -- 1.2.1. Mobile Wi MAX -- 1.2.2. Wi Fi -- 1.3. Overview of LTE -- 1.3.1. Relevant Features of LTE -- 1.3.2. Relevant Features of LTE-Advanced -- 1.4. Summary and Conclusion -- 2. Network Architecture and Protocols -- 2.1. Architecture Model and Concepts -- 2.2. Architecture Reference Model -- 2.2.1. Functional Description of LTE Network -- 2.2.2. Reference Points -- 2.3. Control and User Planes -- 2.3.1. User Plane -- 2.3.2. Control Plane -- 2.3.3. X -- 2. Interface in User and Control Planes -- 2.3.4. S -- 1. Interface in User and Control Planes -- 2.4. Multimedia Broadcast and Multicast Service (MBSM) -- 2.4.1. MBMS Service Architecture -- 2.4.2. MBMS Service Deployment -- 2.5. Stream Control Transmission Protocol -- 2.6. Network Discovery and Selection -- 2.7. Radio Resource Management -- 2.7.1. Radio Bearer Control (RBC) -- 2.7.2. Connection Mobility Control (CMC) -- 2.7.3. Dynamic Resource Allocation (DRA) -- Packet Scheduling (PS) -- 2.7.4. Inter-cell Interference Coordination (ICIC) -- 2.7.5. Load Balancing (LB) -- 2.7.6. Inter-RAT Radio Resource Management -- 2.7.7. Subscriber Profile ID for RAT/Frequency Priority -- 2.8. Authentication and Authorization -- 2.8.1. User Authentication, Key Agreement, and Key Generation -- 2.8.2. Signaling and User-Plane Security -- 2.9. Summary and Conclusions -- 3. LTE Radio Layer Design -- 3.1. Layer -- 2. Design -- 3.2. MAC Sublayer -- 3.2.1. Logical Channels -- 3.2.2. Transport Channels -- 3.2.3. Mapping of Transport Channels to Logical Channels -- 3.2.4. MAC Transport Block Structure -- 3.2.5. HARQ -- 3.2.6. Buffer Status Reporting -- 3.2.7. Random Access Procedure -- 3.2.8. Scheduling Request -- 3.3. PDCP Sublayer -- 3.3.1. Header Compression and Decompression -- 3.3.2. Ciphering and Deciphering -- 3.3.3. Integrity Protection and Verification -- 3.4. RLC Sublayer -- 3.5. Summary and Conclusion -- 4. LTE Phyiscal Layer -- 4.1. LTE Fundamental Concepts of PHY Layer -- 4.1.1. Single-Carrier Modulation and Channel Equalization -- 4.1.2. Frequency Division Multiplexing -- 4.1.3. OFDM -- 4.1.4. Link Adaptation -- 4.1.5. Generic Radio Frame Structure -- 4.1.6. Downlink Reference Signals -- 4.1.7. Uplink Reference Signals -- 4.1.8. Downlink Control Channel -- 4.1.9. Uplink Control Channel -- 4.2. MIMO and LTE -- 4.3. MIMO and MRC -- 4.4. Summary and Conclusions -- Part II. LTE Key Features : -- 5. Quality of Service -- 5.1. Qo S Mechanisms -- 5.2. Qo S Control at Bearer Level -- 5.2.1. Qo S Parameters -- 5.2.2. Network Initiation Qo S -- 5.3. Qo S Control at Service Data Flow Level -- 5.3.1. Policy and Charging Control Rule -- 5.4. Multimedia Session Management -- 5.4.1. Session Initiation Protocol -- 5.4.2. Registration and IMS -- 5.4.3. Qo S Provisioning and IMS -- 5.5. Summary and Conclusions -- 6. Interworking Design for LTE Convergence -- 6.1. General Design Principles of the Interworking Architecture -- 6.2. Interworking Scenario -- 6.3. LTE Interworking with IEEE -- 6.3.1. Mobile Wi MAX and LTE Interworking Architecture -- 6.3.2. WLAN and LTE Interworking -- 6.3.3. Network Discovery and Selection -- 6.4. LTE Interworking with 3GPP -- 6.4.1. E-UTRAN and HRPD -- 6.5. IEEE -- 802. .21 -- 6.6. Summary and Conclusions -- 7. Mobility -- 7.1. Mobility Management -- 7.1.1. Location Management -- 7.1.2. Handover Management -- 7.2. Mobile IP -- 7.2.1. Registering the Care-of Address -- 7.2.2. Automatic Home Agent discovery -- 7.2.3. Tunneling to the Care-of Address -- 7.2.4. Proxy and Gratuitous Address Resolution Protocol (ARP) -- 7.3. Differences Between IPv -- 4. and IPv -- 7.3.1. Reverse Tunnels -- 7.3.2. Use of Route Optimization -- 7.4. Proxy Mobile IP -- 7.4.1. Idle Mode Mobility -- 7.4.2. Active Mode Mobility -- 7.4.3. Handover Using the S -- 1. Interface -- 7.4.4. Inter-MME Handover Using the S -- 1. Interface (Without Changing S-GW) -- 7.5. Inter-RAT Handover: E-UTRAN to UTRAN Iu Mode -- 7.6. Summary and Conclusions -- 8. LTE and Femtocell -- 8.1. Behind Femtocell Emergence -- 8.2. Femtocell Technology -- 8.3. Femtocell Benefits -- 8.3.1. User Benefits -- 8.3.2. Operator Benefits -- 8.4. LTE Femtocell Design Issues -- 8.4.1. LTE Femtocell Architecture -- 8.5. LTE Femtocell Deployment Scenarios -- 8.5.1. Scenario -- 8.5.2. Scenario -- 8.5.3. Scenario -- 8.6. Femtocell Access Control Strategy -- 8.6.1. CSG Concept -- 8.6.2. Physical Cell Identity -- 8.7. LTE Femtocell Challenges and Technical Issues -- 8.7.1. Interference -- 8.7.2. Spectrum Allocation -- 8.7.3. Access Mode Impact -- 8.7.4. Security and Privacy Challenges -- 8.7.5. Synchronization -- 8.7.6. Mobility -- 8.8. Summary and Conclusion -- Part III. LTE Performance : -- 9. Downlink Radio Resource Allocation Strategies in LTE Networks -- 9.1. An Overview of Resource Allocation Techniques in OFDMA Systems -- 9.2. System Model -- 9.3. OFDMA Key Principles -- Analysis and Performance Characterizations -- 9.3.1. OFDMA Slot Structure in LTE Generic Frame -- 9.3.2. Adaptive Modulation and Coding -- 9.3.3. Multiuser Diversity -- 9.3.4. Capacity Analysis -- Time and Frequency Domain -- 9.4. Proposed Radio Resource Allocation Strategies -- 9.4.1. Problem Formulation -- 9.4.2. Adaptive Slot Allocation (ASA) Algorithm -- 9.4.3. Reservation-Based Slot Allocation (RSA) Algorithm -- 9.5. Performance Evaluation -- 9.5.1. Simulation Parameters -- 9.5.2. Simulation Results -- 9.6. Summary and Conclusions -- 10. Performance Study of Opportunistic Scheduling in LTE Networks -- 10.1. Introduction -- 10.2. Downlink System Model -- 10.3. Opportunistic Packet Scheduling Algorithms -- 10.3.1. Proportional Fairness (PF) -- 10.3.2. Maximum Largest Weighted Delay First (M-LWDF) -- 10.3.3. Exponential Proportional Fairness (EXP/PF) -- 10.4. Simulation Environment -- 10.5. Traffic Model -- 10.6. Simulation Results -- 10.6.1. Packet Loss Ratio -- 10.6.2. Delay -- 10.6.3. Throughput -- 10.6.4. Fairness Index -- 10.6.5. Cell Spectral Efficiency -- 10.7. Conclusion -- 11. Cross-Layer Multiservice Scheduling for LTE Networks -- 11.1. Channel-Based Scheduling Solutions -- 11.1.1. Modified Largest Weighted Delay First (M-LWDF) Algorithm -- 11.1.2. Exponential (EXP) Algorithm -- 11.1.3. Delay-Based Utility Optimization Algorithm -- 11.1.4. Maximum Fairness (MF) Algorithm -- 11.2. Channel-Aware Class-Based Queue (CACBQ) -- The Proposed Solution -- 11.2.1. System Model -- 11.2.2. Channel-Aware Class-Based Queue (CACBQ) Framework -- 11.3. CACBQ Performance Evaluation -- 11.3.1. Simulation Environment -- 11.3.2. Traffic Model -- 11.3.3. Simulation Results -- 11.3.4. Fairness and Efficiency -- 11.4. Summary and Conclusions -- 12. Fractional Frequency Reuse in LTE Networks -- 12.1. Introduction -- 12.2. Proposed Design for LTE Network Architecture -- 12.2.1. Radio Resource Allocation Model -- 12.2.2. Link Model -- 12.2.3. Problem Formulation -- 12.3. Hierarchical Resource Allocation Approach (HRAA) -- 12.3.1. Resource Allocation at RRC -- 12.3.2. Resource Allocation at the e Node B -- 12.4. Numerical Results -- 12.4.1. Simulation Environment -- 12.4.2. Simulation Results -- 12.5. Summary and Conclusions -- 13. Performance Study of Mobile Wi MAX and LTE Interworking -- 13.1. Introduction -- 13.2. Handover Overview -- 13.3. Mobile Wi MAX and LTE Interworking Architecture -- 13.4. Handover Decision-Based Neyman-Pearson Lemma -- 13.5. Handover Execution Based on FMIPv -- 13.6. Performance Evaluation -- 13.6.1. Scenario -- 13.6.2. Scenario -- 13.6.3. Scenario -- 13.7. Simulation Results -- 13.8. Summary and Conclusions -- 14. LTE Femtocell Integration with Wireless Sensor/Actuator Networks and RFID Technologies -- 14.1. Introduction -- 14.1.1. Handover Management -- 14.2. Motivation and Proposal Overview -- 14.3. Scheme A: RFID-Assisted Network Movement Detection -- 14.3.1. System Architecture Design -- 14.3.2. Mechanism -- 14.4. Scheme B: Deploying RFID and WSAN for Improving Handover at Link and Network Layer -- 14.4.1. System Architecture Design -- 14.4.2. Mechanism -- 14.5. Theoretical Analysis -- 14.5.1. Time Response -- 14.6. Performance Analysis -- 14.6.1. Simulation Setup -- 14.6.2. Accuracy Analysis -- 14.6.3. Time Latency -- 14.7. Summary and Conclusions.

ISBN

• 1441964568
• 9781441964564

LCCN

• 2011929037
• 99946224429

OCLC

• ocn728082825
• 728082825
• SCSB-9300823

Owning Institutions

Princeton University Library